The URL can be used to link to this page

Home My WebLink AboutEdina_2018_CWRMP_July-2018_Final2018 Comprehensive Water Resources Management Plan July 2018 4300 MarketPointe Drive, Suite 200 Minneapolis, MN 55435 952-832-2600 | www.barr.com Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina i P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\2018 Final CWRMP\Edina_2018_CWRMP_July2018_Final.docx City of Edina 2018 Comprehensive Water Resources Management Plan July 2018 Contents 1.0 Executive Summary ........................................................................................................................................................... 1-1 1.1 Problems, Issues, and Potential Solutions ............................................................................................... 1-2 1.1.1 Water Resources Implementation Program ........................................................................ 1-2 1.1.2 Runoff Management and Flood Control ............................................................................... 1-2 1.2 Flood Risk Reduction Strategy ..................................................................................................................... 1-2 1.3 Clean Water Strategy ....................................................................................................................................... 1-4 2.0 Introduction and Physical Setting ............................................................................................................................... 2-1 2.1 Plan Purposes ..................................................................................................................................................... 2-1 2.2 Physical Setting .................................................................................................................................................. 2-2 2.2.1 Drainage Patterns ........................................................................................................................... 2-2 2.2.2 Watershed Management Organizations ............................................................................... 2-3 2.2.2.1 Minnehaha Creek Watershed District ................................................................................. 2-3 2.2.2.2 Nine Mile Creek Watershed District .................................................................................... 2-3 2.2.3 Land Use ............................................................................................................................................ 2-3 2.2.4 Soils ...................................................................................................................................................... 2-4 2.2.5 Topography ...................................................................................................................................... 2-4 2.2.6 Water Quality ................................................................................................................................... 2-4 2.2.6.1 Water Quality Monitoring ....................................................................................................... 2-4 2.2.6.2 Lakes ................................................................................................................................................. 2-4 2.2.6.3 Creeks ............................................................................................................................................... 2-5 2.2.6.4 Impaired Waters and Total Maximum Daily Loads ....................................................... 2-7 2.2.7 Parks, Recreation, and Natural Resources Open Space ............................................... 2-10 2.2.8 Public Utilities ............................................................................................................................... 2-10 2.2.9 Fish and Wildlife Habitat .......................................................................................................... 2-11 2.2.10 Unique Features and Scenic Areas ....................................................................................... 2-13 2.2.11 Pollutant Sources ......................................................................................................................... 2-13 2.2.11.1 Investigation and Cleanup Sites......................................................................................... 2-13 2.2.11.2 Tank Sites and Leak Sites ...................................................................................................... 2-14 City of Edina 2018 Comprehensive Water Resources Management Plan ii 2.2.11.3 Individual Sewage Treatment Systems ........................................................................... 2-14 2.2.12 Groundwater ................................................................................................................................. 2-14 3.0 Policies for Water Resources Management ............................................................................................................ 3-1 3.1 Runoff Management and Flood Protection ............................................................................................ 3-1 3.1.1 Runoff Management and Flood Protection Background ............................................... 3-1 3.1.2 Runoff Management and Flood Protection Policies......................................................... 3-3 3.1.2.1 Minimum Principle Structure Elevations ........................................................................... 3-5 3.1.2.2 Below-Grade Garages and Parking Adjacent to Flood-Prone Areas ..................... 3-6 3.1.2.3 Stormwater Management Design Standards .................................................................. 3-7 3.2 Floodplain Management ................................................................................................................................ 3-8 3.3 Water Quality ................................................................................................................................................... 3-10 3.3.1 Water Quality Background ...................................................................................................... 3-10 3.3.2 Water Quality Management Policies ................................................................................... 3-12 3.3.2.1 Water Quality Management Standards .......................................................................... 3-14 3.4 Erosion and Sediment Control .................................................................................................................. 3-14 3.4.1 Erosion and Sediment Control Policies ............................................................................... 3-14 3.5 Wetlands ............................................................................................................................................................ 3-14 3.5.1 Wetlands Policies ......................................................................................................................... 3-14 3.6 Natural Resources .......................................................................................................................................... 3-15 3.7 Groundwater .................................................................................................................................................... 3-16 3.8 Education Program ........................................................................................................................................ 3-16 3.9 NPDES Considerations ................................................................................................................................. 3-17 4.0 Methodology for Modeling ........................................................................................................................................... 4-1 4.1 Methodology for Hydrologic/Hydraulic Modeling .............................................................................. 4-1 4.1.1 Hydrologic Modeling .................................................................................................................... 4-1 4.1.1.1 Watershed Data ........................................................................................................................... 4-1 4.1.1.2 Rainfall Data .................................................................................................................................. 4-4 4.1.1.3 Infiltration Data ............................................................................................................................ 4-4 4.1.1.4 Depression Storage Data ......................................................................................................... 4-5 4.1.1.5 Overland Flow Roughness ....................................................................................................... 4-5 4.1.2 Hydraulic Modeling ....................................................................................................................... 4-5 4.1.2.1 Storm Sewer Network ............................................................................................................... 4-5 4.1.2.2 Tailwater Effects ........................................................................................................................... 4-6 4.1.2.3 Overland Flow Network ............................................................................................................ 4-7 4.1.3 Stormwater System Analysis ...................................................................................................... 4-7 4.1.3.1 Problem Areas Selection Process ......................................................................................... 4-9 City of Edina 2018 Comprehensive Water Resources Management Plan iii 4.2 Methodology for Water Quality Modeling .......................................................................................... 4-10 4.2.1 Watershed Characteristics ....................................................................................................... 4-10 4.2.1.1 Impervious Fraction ................................................................................................................. 4-11 4.2.1.2 Pervious Curve Number ........................................................................................................ 4-12 4.2.1.3 Other P8 Watershed Input Parameters ........................................................................... 4-12 4.2.2 Treatment Device Characteristics .......................................................................................... 4-12 4.2.2.1 Dead Storage ............................................................................................................................. 4-12 4.2.2.2 Live Storage ................................................................................................................................ 4-13 4.2.2.3 Other P8 Treatment Device Input Characteristics ...................................................... 4-13 4.2.3 Precipitation and Temperature Data ................................................................................... 4-14 4.2.4 Selection of Other P8 Model Parameters .......................................................................... 4-14 4.2.4.1 Time Step, Snowmelt, and Runoff Parameters ............................................................ 4-14 4.2.4.2 Particle File Selection .............................................................................................................. 4-15 4.2.4.3 Passes through the Storm File ............................................................................................ 4-15 4.2.5 Stormwater System Analysis ................................................................................................... 4-15 5.0 Nine Mile Creek—North ................................................................................................................................................. 5-1 5.1 General Description of Drainage Area ...................................................................................................... 5-1 5.1.1 Drainage Patterns ........................................................................................................................... 5-1 5.1.1.1 Mirror Lake ..................................................................................................................................... 5-1 5.1.1.2 Highlands Lake ............................................................................................................................. 5-1 5.1.1.3 Hawkes Lake .................................................................................................................................. 5-2 5.1.1.4 Mud Lake (Bredesen Park) ....................................................................................................... 5-2 5.1.1.5 Nine Mile North ........................................................................................................................... 5-3 5.2 Stormwater System Results ........................................................................................................................... 5-3 5.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................... 5-3 5.2.2 Water Quality Modeling Results ............................................................................................... 5-4 5.3 Implementation Considerations .................................................................................................................. 5-4 5.3.1 Flood Protection Projects ............................................................................................................ 5-4 5.3.1.1 Maloney Avenue and Tyler Court (ML_35 and ML_19) ............................................... 5-5 5.3.1.2 Between Leslee Lane and Kaymar Drive (MD_22) ......................................................... 5-5 5.3.1.3 Parkwood Road and Schaefer Road (MD_28, MD_29, and MD_35) ...................... 5-6 5.3.1.4 Schaefer Road and View Lane (MD_38) ............................................................................. 5-6 5.3.1.5 Nine Mile Village Townhomes (MD_49) ............................................................................ 5-7 5.3.1.6 Hawkes Lake and Upstream Surrounding Area (HL_1, HL_11c, HL_11w, HL_49, and HL_12) ..................................................................................................................................... 5-7 5.3.2 Construction/Upgrade of Water Quality Basins ................................................................. 5-8 City of Edina 2018 Comprehensive Water Resources Management Plan iv 5.3.2.1 MD_15 .............................................................................................................................................. 5-8 5.3.2.2 NMN_27 .......................................................................................................................................... 5-8 5.3.2.3 NMN_24 .......................................................................................................................................... 5-8 5.3.2.4 NMN_49 .......................................................................................................................................... 5-9 5.3.2.5 MD_3 ................................................................................................................................................ 5-9 6.0 Nine Mile Creek—Central ............................................................................................................................................... 6-1 6.1 General Description of Drainage Area ...................................................................................................... 6-1 6.1.1 Drainage Patterns ........................................................................................................................... 6-1 6.1.1.1 Colonial Ponds ............................................................................................................................. 6-1 6.1.1.2 Indian Pond ................................................................................................................................... 6-1 6.1.1.3 Nine Mile Central ........................................................................................................................ 6-2 6.2 Stormwater System Results ........................................................................................................................... 6-2 6.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................... 6-2 6.2.2 Water Quality Modeling Results ............................................................................................... 6-3 6.3 Implementation Considerations .................................................................................................................. 6-3 6.3.1 Flood Protection Projects ............................................................................................................ 6-3 6.3.1.1 Antrim Road and Chapel Drive (NMC_41) ........................................................................ 6-4 6.3.1.2 Ridgeview Drive (NMC_106 and NMC_107) .................................................................... 6-4 6.3.1.3 West 66th Street and Naomi Drive (NMC_71, NMC_74, and NMC_103) .............. 6-4 6.3.2 Construction/Upgrade of Water Quality Basins ................................................................. 6-5 7.0 Lake Cornelia/Lake Edina/Adam’s Hill ....................................................................................................................... 7-1 7.1 General Description of Drainage Area ...................................................................................................... 7-1 7.1.1 Drainage Patterns ........................................................................................................................... 7-1 7.1.1.1 North Cornelia .............................................................................................................................. 7-1 7.1.1.2 South Lake Cornelia ................................................................................................................... 7-2 7.1.1.3 Lake Edina ...................................................................................................................................... 7-2 7.1.1.4 Adam’s Hill Pond ......................................................................................................................... 7-2 7.2 Stormwater System Results ........................................................................................................................... 7-2 7.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................... 7-2 7.2.2 Water Quality Modeling Results ............................................................................................... 7-3 7.3 Implementation Considerations .................................................................................................................. 7-3 7.3.1 Flood Protection Projects ............................................................................................................ 7-4 7.3.1.1 Valley View and Southdale Road Neighborhood (LE_34, LE_36, and LE_43) ..... 7-4 7.3.1.2 Southwest Corner of TH 62 and TH 100 (NC_7, NC_8, NC_13, NC_11, NC_12, NC_14, NC_15, NC_16, and NC_20) ..................................................................................... 7-6 7.3.2 Construction/Upgrade of Water Quality Basins ................................................................. 7-6 City of Edina 2018 Comprehensive Water Resources Management Plan v 7.3.2.1 LE_38 ................................................................................................................................................. 7-7 7.3.2.2 NC_88 ............................................................................................................................................... 7-7 8.0 Nine Mile Creek South ..................................................................................................................................................... 8-1 8.1 General Description of Drainage Area ...................................................................................................... 8-1 8.1.1 Drainage Patterns ........................................................................................................................... 8-1 8.1.1.1 Centennial Lakes .......................................................................................................................... 8-1 8.1.1.2 South Pond (Border Basin) ...................................................................................................... 8-1 8.1.1.3 Nine Mile South ........................................................................................................................... 8-2 8.2 Stormwater System Results ........................................................................................................................... 8-2 8.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................... 8-2 8.2.2 Water Quality Modeling Results ............................................................................................... 8-3 8.3 Implementation Considerations .................................................................................................................. 8-3 8.3.1 Flood Protection Projects ............................................................................................................ 8-3 8.3.1.1 West 70th Street and West Shore Drive (NMS_38 and NMS_50) ............................ 8-4 8.3.1.2 Centennial Lakes (CL_1) ............................................................................................................ 8-4 8.3.2 Construction/Upgrade of Water Quality Basins ................................................................. 8-5 8.3.2.1 West 77th Street and TH 100 .................................................................................................. 8-5 8.3.2.2 NMS_76 ........................................................................................................................................... 8-6 8.3.2.3 NMS_104 ......................................................................................................................................... 8-6 8.3.2.4 NMS_72 and NMS_74 ................................................................................................................ 8-6 8.3.2.5 SP_1 (South Pond/Border Basin) ........................................................................................... 8-6 9.0 Nine Mile South Fork ....................................................................................................................................................... 9-1 9.1 General Description of Drainage Area ...................................................................................................... 9-1 9.1.1 Drainage Patterns ........................................................................................................................... 9-1 9.1.1.1 Arrowhead Lake ........................................................................................................................... 9-1 9.1.1.2 Indianhead Lake ........................................................................................................................... 9-1 9.1.1.3 Pawnee Pond ................................................................................................................................ 9-2 9.1.1.4 Eden Prairie .................................................................................................................................... 9-2 9.1.1.5 Braemar Arena/Public Works ................................................................................................. 9-2 9.1.1.6 Nine Mile South Fork ................................................................................................................. 9-2 9.2 Stormwater System Results ........................................................................................................................... 9-3 9.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................... 9-3 9.2.2 Water Quality Modeling Results ............................................................................................... 9-3 9.3 Implementation Considerations .................................................................................................................. 9-4 9.3.1 Flood Protection Projects ............................................................................................................ 9-4 9.3.1.1 McCauley Trail West (AH_6).................................................................................................... 9-4 City of Edina 2018 Comprehensive Water Resources Management Plan vi 9.3.1.2 Sally Lane and Valley View Road (NMSB_52, NMSB_69, and NMSB_77) ............. 9-5 9.3.2 Construction/Upgrade of Water Quality Basins ................................................................. 9-5 9.3.2.1 NMSB_3 and NMSB_2 ............................................................................................................... 9-6 9.3.2.2 NMSB_12 ........................................................................................................................................ 9-6 9.3.2.3 NMSB_86 ........................................................................................................................................ 9-6 9.3.2.4 NMSB_7 ........................................................................................................................................... 9-7 9.3.2.5 NMSB_85 ........................................................................................................................................ 9-7 10.0 Southwest Ponds (Dewey Hill Road Area) ............................................................................................................ 10-1 10.1 General Description of Drainage Area ................................................................................................... 10-1 10.1.1 Drainage Patterns ........................................................................................................................ 10-1 10.1.1.1 Southwest Ponds ...................................................................................................................... 10-1 10.1.1.2 Nine Mile I-494 ......................................................................................................................... 10-1 10.2 Stormwater System Results ........................................................................................................................ 10-2 10.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................ 10-2 10.2.2 Water Quality Modeling Results ............................................................................................ 10-2 10.3 Implementation Considerations ............................................................................................................... 10-3 10.3.1 Flood Protection Projects ......................................................................................................... 10-3 10.3.1.1 Gleason Road and Bonnie Brae Drive (SWP_24) ......................................................... 10-3 10.3.2 Construction/Upgrade of Water Quality Basins .............................................................. 10-4 11.0 TH 169 North .................................................................................................................................................................... 11-1 11.1 General Description of Drainage Area ................................................................................................... 11-1 11.1.1 Drainage Patterns ........................................................................................................................ 11-1 11.2 Stormwater System Results ........................................................................................................................ 11-1 11.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................ 11-1 11.2.2 Water Quality Modeling Results ............................................................................................ 11-2 11.3 Implementation Considerations ............................................................................................................... 11-2 11.3.1 Flood Protection Projects ......................................................................................................... 11-2 11.3.2 Construction/Upgrade of Water Quality Basins .............................................................. 11-3 12.0 Northeast Minnehaha Creek ...................................................................................................................................... 12-1 12.1 General Description of Drainage Area ................................................................................................... 12-1 12.1.1 Drainage Patterns ........................................................................................................................ 12-1 12.1.1.1 Morningside ............................................................................................................................... 12-1 12.1.1.2 Minnehaha Creek North ........................................................................................................ 12-1 12.1.1.3 Edina Country Club .................................................................................................................. 12-2 12.2 Stormwater System Results ........................................................................................................................ 12-2 12.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................ 12-2 City of Edina 2018 Comprehensive Water Resources Management Plan vii 12.2.2 Water Quality Modeling Results ............................................................................................ 12-3 12.3 Implementation Considerations ............................................................................................................... 12-3 12.3.1 Flood Protection Projects ......................................................................................................... 12-3 12.3.1.1 Indianola Avenue South of West 50th Street (MHN_72) .......................................... 12-4 12.3.1.2 Halifax Avenue South (MHN_84, MHN_3, MHN_4, MHN_56, MHN_89, MHN_55, MHN_61, MHN_62, MHN_87, MHN_90, and MHN_2) .............................................. 12-4 12.3.1.3 Morningside/Weber Park (MS_26, MS_25, MS_41, MS_32, MS_44, MS_24, MS_15, MS_52, MS_53, MS_2, MS_38, MS_40, MS_54, MS_31, MS_33, MS_39a, and MS_39b) .............................................................................................................................. 12-6 12.3.1.4 Edinbrook Lane and Westbrook Lane (MHN_79) ....................................................... 12-7 12.3.1.5 North of Morningside Road between Lynn Avenue and Crocker Avenue (MS_22) ......................................................................................................................................... 12-8 12.3.1.6 Branson Street between West 44th Street and Morningside Road (MS_3, MS_48, and MS_7) .................................................................................................................................... 12-8 12.3.2 Construction/Upgrade of Water Quality Basins .............................................................. 12-9 13.0 Southeast Minnehaha Creek ...................................................................................................................................... 13-1 13.1 General Description of Drainage Area ................................................................................................... 13-1 13.1.1 Drainage Patterns ........................................................................................................................ 13-1 13.1.1.1 Lake Pamela ................................................................................................................................ 13-1 13.1.1.2 Minnehaha Creek South ........................................................................................................ 13-1 13.1.1.3 Melody Lake ............................................................................................................................... 13-2 13.2 Stormwater System Results ........................................................................................................................ 13-2 13.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................ 13-2 13.2.2 Water Quality Modeling Results ............................................................................................ 13-3 13.3 Implementation Considerations ............................................................................................................... 13-3 13.3.1 Flood Protection Projects ......................................................................................................... 13-3 13.3.1.1 East Golf Terrace Heights Neighborhood ...................................................................... 13-4 13.3.1.2 Concord and West 58th Street (MHS_59, MHS_26, MHS_58, MHS_42, MHS_53, and MHS_17) .............................................................................................................................. 13-5 13.3.2 Construction/Upgrade of Water Quality Basins .............................................................. 13-6 13.3.3 Stream Improvement Projects ................................................................................................ 13-7 13.3.3.1 Minnehaha Creek Reach 14 Stream Restoration ........................................................ 13-7 14.0 Northwest Minnehaha Creek ..................................................................................................................................... 14-1 14.1 General Description of Drainage Area ................................................................................................... 14-1 14.1.1 Drainage Patterns ........................................................................................................................ 14-1 14.1.1.1 TH 100 ........................................................................................................................................... 14-1 14.1.1.2 Hopkins ........................................................................................................................................ 14-1 14.1.1.3 Interlachen .................................................................................................................................. 14-1 City of Edina 2018 Comprehensive Water Resources Management Plan viii 14.2 Stormwater System Results ........................................................................................................................ 14-2 14.2.1 Hydrologic/Hydraulic Modeling Results ............................................................................ 14-2 14.2.2 Water Quality Modeling Results ............................................................................................ 14-3 14.3 Implementation Considerations ............................................................................................................... 14-3 14.3.1 Flood Protection Projects ......................................................................................................... 14-3 14.3.1.1 Blake Road South and Spruce Road (HO_4) ................................................................. 14-4 14.3.2 Construction/Upgrade of Water Quality Basins .............................................................. 14-4 15.0 Issues and Implementation Program ...................................................................................................................... 15-1 15.1 Flood Protection and Runoff Management ......................................................................................... 15-1 15.1.1 Flood protection and runoff management infrastructure ........................................... 15-2 15.1.2 Flood protection and runoff management programs .................................................. 15-3 15.1.2.1 Assessing Risk ............................................................................................................................ 15-3 15.1.2.2 Communicating Risk ............................................................................................................... 15-3 15.1.2.3 Land Use Controls .................................................................................................................... 15-3 15.1.2.4 Technical Assistance ............................................................................................................... 15-4 15.1.3 Flood Risk Reduction Strategy ............................................................................................... 15-4 15.1.3.1 Implementation Approaches ............................................................................................... 15-4 15.1.3.2 Opportunity Identification/Prioritization........................................................................ 15-5 15.2 Clean Water .................................................................................................................................................... 15-20 15.2.1 Clean Water Infrastructure ..................................................................................................... 15-20 15.2.2 Clean Water Programs ............................................................................................................ 15-20 15.2.2.1 Community Engagement .................................................................................................... 15-21 15.2.2.2 Pollution Prevention ............................................................................................................. 15-21 15.2.2.3 Pollution Source Controls ................................................................................................... 15-22 15.2.2.4 Lake and Pond Management ............................................................................................ 15-23 15.2.3 Clean Water Strategy ............................................................................................................... 15-27 15.2.3.1 Implementation Approach ................................................................................................. 15-28 15.2.3.2 Opportunity Identification and Prioritization ............................................................. 15-28 15.3 Stormwater Infrastructure ......................................................................................................................... 15-30 15.3.1 Operation and Maintenance of Stormwater Systems ................................................. 15-31 15.3.1.1 Private Stormwater Facilities ............................................................................................. 15-31 15.3.1.2 Publicly Owned Stormwater Facilities ........................................................................... 15-31 15.3.1.3 Maintenance of Storm Sewer and Culvert Inlets ...................................................... 15-31 15.3.1.4 Maintenance of Ponding Facilities .................................................................................. 15-32 15.3.1.5 Riprap and Filter Areas......................................................................................................... 15-32 15.3.1.6 Adequacy of the Maintenance Program ...................................................................... 15-32 City of Edina 2018 Comprehensive Water Resources Management Plan ix 15.4 Management Approach............................................................................................................................. 15-32 15.4.1 Coordination with Watershed Districts ............................................................................. 15-34 15.4.1.1 Regulation ................................................................................................................................. 15-34 15.4.1.2 Data and Information ........................................................................................................... 15-34 15.4.1.3 Land Use Planning Opportunities ................................................................................... 15-35 15.4.1.4 Implementation Partnership Opportunities ................................................................ 15-36 15.4.2 Development Review Process and Land Use Planning .............................................. 15-37 15.4.3 Prioritization ................................................................................................................................ 15-38 15.4.4 Resources ...................................................................................................................................... 15-39 15.4.5 Financial Considerations ......................................................................................................... 15-39 15.4.6 Utility funding ............................................................................................................................. 15-40 15.4.7 Policy Issues ................................................................................................................................. 15-41 15.5 Plan Update and Amendment Procedure .......................................................................................... 15-42 16.0 Wetlands ............................................................................................................................................................................ 16-1 16.1 City of Edina Wetlands Inventory—1999 .............................................................................................. 16-1 16.1.1 Delineation ..................................................................................................................................... 16-1 16.1.2 Dominant Vegetation ................................................................................................................ 16-2 16.1.3 Wetland Functional Assessment............................................................................................ 16-2 16.1.3.1 Hydrology .................................................................................................................................... 16-2 16.1.3.2 Vegetative Diversity ................................................................................................................ 16-2 16.1.3.3 Wildlife Habitat ......................................................................................................................... 16-3 16.1.3.4 Fishery Habitat .......................................................................................................................... 16-3 16.1.3.5 Flood/Stormwater Attenuation .......................................................................................... 16-3 16.1.3.6 Water Quality Protection ...................................................................................................... 16-3 16.1.3.7 Shoreline Protection ............................................................................................................... 16-3 16.1.3.8 Aesthetics/Recreation/Education and Science ............................................................ 16-4 16.1.4 Wetland Sensitivity to Stormwater Input ........................................................................... 16-4 16.2 MCWD FAW—2003 ....................................................................................................................................... 16-7 16.2.1 Delineation and Inventory ....................................................................................................... 16-7 16.2.2 Critical Wetland Resources ...................................................................................................... 16-7 16.2.3 Wetland Susceptibility to Stormwater ................................................................................ 16-8 16.2.4 Wetland Management Classification ................................................................................... 16-8 16.3 Circular 39 Wetland Classification ........................................................................................................... 16-8 16.3.1 Type 1: Seasonally Flooded Basin, Floodplain Forest ................................................... 16-8 16.3.2 Type 2: Wet Meadow, Fresh Wet Meadow, Wet to Wet-Mesic Prairie, Sedge Meadow, and Calcareous Fen ................................................................................................ 16-9 City of Edina 2018 Comprehensive Water Resources Management Plan x 16.3.3 Type 3: Shallow Marsh ............................................................................................................... 16-9 16.3.4 Type 4: Deep Marsh .................................................................................................................... 16-9 16.3.5 Type 5: Shallow Open Water................................................................................................... 16-9 16.3.6 Type 6: Shrub Swamp; Shrub Carr, Alder Thicket ........................................................... 16-9 16.3.7 Type 7: Wooded Swamps; Hardwood Swamp, Coniferous Swamp ........................ 16-9 16.4 Cowardin Wetland Classification ........................................................................................................... 16-10 16.4.1 System............................................................................................................................................ 16-10 16.4.2 Subsystem .................................................................................................................................... 16-11 16.4.3 Class, Subclass ............................................................................................................................ 16-11 16.4.4 Water Regime ............................................................................................................................. 16-12 16.4.5 Special Modifiers ....................................................................................................................... 16-13 16.5 Public Waters ................................................................................................................................................. 16-13 17.0 References ......................................................................................................................................................................... 17-1 City of Edina 2018 Comprehensive Water Resources Management Plan xi List of Tables Table 1.1 Strategies and Potential Actions for Addressing Local and Regional Flood Issues .............................. 1-3 Table 2.1 Summer (June-September) Average Total Phosphorus Concentrations for Edina Lakes................... 2-6 Table 2.2 City of Edina waterbodies on MPCA's 303(d) Impaired Waters List ........................................................... 2-8 Table 2.3 Fishery and Aquatic Invasive Species Information .......................................................................................... 2-12 Table 3.1 Source of the Best Available 1-Percent-Annual Chance Flood Elevations throughout the City of Edina ................................................................................................................................................................................ 3-3 Table 3.2 Strategies and Potential Actions for Addressing Local and Regional Flood Issues ........................... 3-10 Table 4.1 Land Use Impervious Fraction Assumptions for Hydrologic Modeling ..................................................... 4-3 Table 4.2 Horton Infiltration Parameters ................................................................................................................................... 4-5 Table 4.3 Roughness Coefficient Assumptions ....................................................................................................................... 4-6 Table 4.4 Land Use Impervious Fraction Assumptions for Water Quality Modeling ............................................ 4-11 Table 4.5 Infiltration Assumptions for Water Quality Modeling ................................................................................... 4-13 Table 5.1 Major Watersheds within the Nine Mile Creek—North Drainage Basin ................................................... 5-1 Table 5.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek—North Drainage Basin .................................................................................................................................................................................. 5-10 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek— North Drainage Basin.................................................................................................................................................. 5-15 Table 6.1 Major Watersheds within the Nine Mile Creek—Central Drainage Basin ................................................. 6-1 Table 6.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek—Central Drainage Basin ..................................................................................................................................................................................... 6-6 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek— Central Drainage Basin .................................................................................................................................................. 6-9 Table 7.1 Major Watersheds within the Lake Cornelia/Lake Edina/Adam’s Hill Drainage Basin ......................... 7-1 Table 7.2 Watershed Modeling Results for Subwatersheds in the Lake Cornelia/Lake Edina/Adam’s Hill Drainage Area ................................................................................................................................................................... 7-8 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam’s Hill Drainage Area ........................................................................................................................... 7-12 Table 8.1 Major Watersheds within the Nine Mile Creek—South Drainage Basin ................................................... 8-1 Table 8.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek—South Drainage Basin ..................................................................................................................................................................................... 8-7 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek— South Drainage Basin.................................................................................................................................................. 8-10 Table 9.1 Major Watersheds within the Nine Mile South Fork Drainage Basin ......................................................... 9-1 Table 9.2 Watershed Modeling Results for Subwatersheds in the Nine Mile South Fork Drainage Basin...... 9-8 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin ..................................................................................................................................................... 9-11 Table 10.1 Major Watersheds within the Southwest Ponds Drainage Basin .............................................................. 10-1 Table 10.2 Watershed Modeling Results for Subwatersheds in the Southwest Ponds Drainage Basin .......... 10-5 City of Edina 2018 Comprehensive Water Resources Management Plan xii Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin ............................................................................................................................................................... 10-7 Table 11.1 Major Watershed within the TH 169 North Drainage Area ......................................................................... 11-1 Table 11.2 Watershed Modeling Results for Subwatersheds in the TH 169 North Drainage Basin .................. 11-4 Table 11.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the TH 169 North Drainage Basin ............................................................................................................................................................... 11-5 Table 12.1 Major Watersheds within the Northeast Minnehaha Creek Drainage Basin ........................................ 12-1 Table 12.2 Watershed Modeling Results For Subwatersheds n the Northeast Minnehaha Creek Drainage Basin ................................................................................................................................................................................ 12-10 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin ........................................................................................................................ 12-13 Table 13.1 Major Watersheds within the Southeast Minnehaha Creek Drainage Basin ........................................ 13-1 Table 13.2 Watershed Modeling Results For Subwatersheds n the Southeast Minnehaha Creek Drainage Basin .................................................................................................................................................................................. 13-8 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin ........................................................................................................................ 13-11 Table 14.1 Major Watersheds within the Northwest Minnehaha Creek Drainage Basin ....................................... 14-1 Table 14.2 Watershed Modeling Results For Subwatersheds n the Northwest Minnehaha Creek Drainage Basin .................................................................................................................................................................................. 14-5 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin .......................................................................................................................... 14-7 Table 15.1 Water Resources Implementation Program ...................................................................................................... 15-6 Table 15.2 Potential Implementation Activities (including Capital Improvements) ............................................... 15-12 Table 15.3 Level of Potential Lake Management Activity by Service Level ............................................................... 15-26 Table 15.4 City staff support activities and alternative methods related to Table 15.3 ....................................... 15-26 Table 15.5 Potential Funding Sources for Plan Implementation ................................................................................... 15-40 Table 16.1 Susceptibility of Wetlands to Degradation by Stormwater Impacts ........................................................ 16-5 Table 16.2 Management Recommendations for Each Wetland Sensitivity Classification ..................................... 16-6 Table 16.3 MnDNR Public Waters within Edina .................................................................................................................... 16-14 City of Edina 2018 Comprehensive Water Resources Management Plan xiii List of Figures Figure 2.1 Major Drainage Areas ................................................................................................................................................. 2-15 Figure 2.2 Land Use Classification ............................................................................................................................................... 2-16 Figure 2.3 Edina Soils Classification ............................................................................................................................................ 2-17 Figure 2.4 Water Quality Monitoring Stations ....................................................................................................................... 2-18 Figure 2.5 Edina Parks and Recreational Areas ...................................................................................................................... 2-19 Figure 2.6 Threatened and Endangered Species ................................................................................................................... 2-20 Figure 5.1 Nine Mile Creek—North Drainage Basin ............................................................................................................ 5-31 Figure 5.2 Nine Mile Creek—North Major Watersheds...................................................................................................... 5-32 Figure 5.3 Nine Mile Creek—North Hydraulic Model Results ......................................................................................... 5-33 Figure 5.4 Nine Mile Creek—North Water Quality Modeling Results .......................................................................... 5-34 Figure 6.1 Nine Mile Creek—Central Drainage Basin .......................................................................................................... 6-19 Figure 6.2 Nine Mile Creek—Central Major Watersheds ................................................................................................... 6-20 Figure 6.3 Nine Mile Creek—Central Hydraulic Model Results ....................................................................................... 6-21 Figure 6.4 Nine Mile Creek—Central Water Quality Modeling Results........................................................................ 6-22 Figure 7.1 Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin .................................................................................. 7-30 Figure 7.2 Lake Cornelia/Lake Edina/Adam's Hill Major Watersheds ........................................................................... 7-31 Figure 7.3 Lake Cornelia/Lake Edina/Adam's Hill Hydraulic Model Results ............................................................... 7-32 Figure 7.4 Lake Cornelia/Lake Edina/Adam's Hill Water Quality Modeling Results ................................................ 7-33 Figure 8.1 Nine Mile Creek—South Drainage Basin ............................................................................................................ 8-22 Figure 8.2 Nine Mile Creek—South Major Watersheds ..................................................................................................... 8-23 Figure 8.3 Nine Mile Creek—South Hydraulic Model Results ......................................................................................... 8-24 Figure 8.4 Nine Mile Creek—South Water Quality Modeling Results .......................................................................... 8-25 Figure 9.1 Nine Mile South Fork Drainage Basin .................................................................................................................. 9-22 Figure 9.2 Nine Mile South Fork Major Watersheds ............................................................................................................ 9-23 Figure 9.3 Nine Mile South Fork Hydraulic Model Results ............................................................................................... 9-24 Figure 9.4 Nine Mile South Fork Water Quality Modeling Results ................................................................................ 9-25 Figure 10.1 Southwest Ponds Drainage Basin ........................................................................................................................ 10-13 Figure 10.2 Southwest Ponds Major Watersheds .................................................................................................................. 10-14 Figure 10.3 Southwest Ponds Hydraulic Model Results ..................................................................................................... 10-15 Figure 10.4 Southwest Ponds Water Quality Modeling Results ...................................................................................... 10-16 Figure 11.1 TH 169 North Drainage Basin .................................................................................................................................. 11-7 Figure 11.2 TH 169 North Major Watersheds ........................................................................................................................... 11-8 Figure 11.3 TH 169 North Hydraulic Model Results ............................................................................................................... 11-9 Figure 11.4 TH 169 North Water Quality Modeling Results.............................................................................................. 11-10 Figure 12.1 Northeast Minnehaha Creek Drainage Basin .................................................................................................. 12-26 Figure 12.2 Northeast Minnehaha Creek Major Watersheds ........................................................................................... 12-27 Figure 12.3 Northeast Minnehaha Creek Hydraulic Model Results ............................................................................... 12-28 City of Edina 2018 Comprehensive Water Resources Management Plan xiv Figure 12.4 Northeast Minnehaha Creek Water Quality Modeling Results ................................................................ 12-29 Figure 13.1 Southeast Minnehaha Creek Drainage Basin .................................................................................................. 13-22 Figure 13.2 Southeast Minnehaha Creek Major Watersheds ........................................................................................... 13-23 Figure 13.3 Southeast Minnehaha Creek Hydraulic Model Results ............................................................................... 13-24 Figure 13.4 Southeast Minnehaha Creek Water Quality Modeling Results ................................................................ 13-25 Figure 14.1 Northwest Minnehaha Creek Drainage Basin ................................................................................................. 14-14 Figure 14.2 Northwest Minnehaha Creek Major Watersheds .......................................................................................... 14-15 Figure 14.3 Northwest Minnehaha Creek Hydraulic Model Results .............................................................................. 14-16 Figure 14.4 Northwest Minnehaha Creek Water Quality Modeling Results ............................................................... 14-17 Figure 15.1 City-Owned Property ................................................................................................................................................ 15-43 Figure 16.1 Wetlands within the City of Edina ........................................................................................................................ 16-16 Figure 16.2 Wetlands Classification ............................................................................................................................................ 16-17 List of Appendices, Attachments, or Exhibits Appendix A City of Edina Imperviousness Assumptions for Stormwater Modeling Appendix B Summary of Nine Mile Creek and Minnehaha Creek Modeling Approach Appendix C Legacy Flood Protection Projects Appendix D List of Pond Improvement Recommendations Appendix E Aquatic Vegetation Prioritization List Appendix F Modified Minnesota Routine Assessment Method for Evaluating Wetland Functions (MnRAM) Version 2.0 Appendix G GIS Wetlands Inventory Database City of Edina 2018 Comprehensive Water Resources Management Plan xv Certifications I hereby certify that this report was prepared by me or under my direct supervision and that I am a duly License Professional Engineer under the laws of the State of Minnesota. 5/24/2018 Janna M. Kieffer PE #: 43571 Date City of Edina 2018 Comprehensive Water Resources Management Plan xvi Acronyms Acronym Description BMPs Best Management Practices CAMP Citizen Assisted Monitoring Program CFS Cubic Feet per Second CIP Capital Improvement Program CWA Clean Water Act CWRMP Comprehensive Water Resources Management Plan EPA United States Environmental Protection Agency FAW Functional Assessment of Wetlands (MCWD) FEMA Federal Emergency Management Agency GIS Geographic Information Systems IBI Index of Biotic Integrity ISTS Individual Sewage Treatment Systems LGU Local Government Unit MCWD Minnehaha Creek Watershed District MnRAM Minnesota Routine Assessment Method MnDNR Minnesota Department of Natural Resources MnDOT Minnesota Department of Transportation MPCA Minnesota Pollution Control Agency MS4 Municipal Separate Storm Sewer System MUSA Metropolitan Urban Service Area NGVD29 National Geodetic Vertical Datum of 1929 NMCWD Nine Mile Creek Watershed District NOAA National Oceanic and Atmospheric Administration NPDES National Pollutant Discharge Elimination System NURP Nationwide Urban Runoff Program NWI National Wetlands Inventory PWI Public Waters Inventory RCP Reinforced-Concrete Pipe SCS Soil Conservation Service SSURGO Soil Survey Geographic Database SWMM Stormwater Management Model SWPPP Stormwater Pollution Prevent Plan/Program TBD To Be Determined City of Edina 2018 Comprehensive Water Resources Management Plan xvii TH Trunk Highway TMDL Total Maximum Daily Load TSS Total Suspended Solids UAA Use Attainability Analysis USFWS United States Fish and Wildlife Service VIC Voluntary Investigation and Clean-up WCA Wetland Conservation Act WMO Watershed Management Organization City of Edina 2018 Comprehensive Water Resources Management Plan 1-1 1.0 Executive Summary This plan provides the City of Edina with a Comprehensive Water Resource Management Plan (CWRMP). The plan was developed to address current and future stormwater issues, especially those related to future development and redevelopment. The plan addresses stormwater runoff management and flood control, water quality management, and wetlands protection through establishment of stormwater planning policies and recommendations. The City of Edina developed its first CWRMP in 2003. The original CWRMP is referenced throughout this document as the 2003 CWRMP. The CWRMP was then updated in 2011. This CWRMP is composed of Section 1.0: Executive Summary and 16 additional sections, which are described as follows: Section 2.0: Introduction and Physical Setting—presents background information regarding the City, general watershed information, and plan purposes. Section 3.0: Policies for Water Resources Management presents background information, goals, policies and design standards covering runoff management and flood control, water quality management, erosion and sediment control, wetlands, floodplain management, recreation, habitat and shoreland management, groundwater, the City’s education goals, and National Pollutant Discharge Elimination System (NPDES) considerations. Section 4.0: Methodology for Modeling—describes the data, methods and assumptions used for the stormwater analyses. Section 5.0 through Section 14.0: Major Drainage Area Descriptions and Recommendations—describes the general drainage area, drainage patterns within the area, the stormwater system analysis and results, and implementation recommendations for each of the following 10 major drainage areas in the City: Nine Mile Creek- North, Nine Mile Creek- Central, Nine Mile Creek- South, Lake Cornelia/Lake Edina/Adam’s Hill, Nine Mile South Fork, Southwest Ponds, Trunk Highway (TH) 169 North, Northeast Minnehaha, Southeast Minnehaha, and Northwest Minnehaha. Section 15.0: Issues and Implementation Program—describes the programs and activities that support each of the core services (runoff management, flood control, and clean water services) and some of the policy issues around the provision and growth of service. This chapter also discusses resources, financial considerations, and implementation priorities. City of Edina 2018 Comprehensive Water Resources Management Plan 1-2 Section 16.0: Wetlands—Discusses the wetland inventories completed for the City of Edina and the assessment methodologies and results. Section 17.0: References 1.1 Problems, Issues, and Potential Solutions This section summarizes the City’s 2018 - 2028 water resources implementation program, and potential stormwater management improvements identified in Section 5.0 through Section 14.0 of the plan. 1.1.1 Water Resources Implementation Program This plan serves as a master plan for the City’s water resources management and storm drainage system. The City will work with residents to implement structural (capital) improvements and non-structural programs to address existing water resource problems within the City and to prevent future problems from occurring. The implementation program identifies the programs and improvements, and provides cost estimates for budgeting purposes. Table 15.1 presents the City’s water resource-related implementation program, which includes the City’s non-structural (administration) programs and structural (capital) improvement program. Prioritization of the projects listed in the table will occur as part of the forthcoming Clean Water Strategy and Flood Risk Reduction Strategy. 1.1.2 Runoff Management and Flood Control The hydrologic and hydraulic modeling analyses of the current stormwater system identified several areas throughout the City where the desired 1-percent-annual chance level of protection may not be provided. These problem areas and potential solutions are discussed in detail in Section 5.0 through Section 14.0 and are summarized and prioritized in Table 15.2. In addition to evaluating the level of protection provided by the current stormwater system, the level of service provided was also evaluated. From this analysis, it was determined that the storm sewer throughout many areas of the City is not currently providing the desired 10-year level of service. The areas where the storm sewer does not offer sufficient capacity and street flow occurs during a 10-percent-annual-chance event are depicted in figures in Section 5.0 through Section 14.0 .The capacity of these storm sewer systems should be evaluated and upgraded as opportunities arise. 1.2 Flood Risk Reduction Strategy As part of this 10-year plan, the City of Edina will develop a Flood Risk Reduction Strategy that outlines a plan for working toward reducing flood risk, where appropriate, and meeting its stormwater management goals for providing a 1-percent-annual-chance (100-year) level of protection where possible. The strategy will identify and characterize flood problems throughout the city and identify strategies and infrastructure improvements to address flood-prone areas. The strategy will include preparation of planning-level cost estimates to help understand the potential financial investment required to meet the City’s flood protection goals and the anticipated timeframe for implementation. City of Edina 2018 Comprehensive Water Resources Management Plan 1-3 The Flood Risk Reduction Strategy will detail the City’s approach to addressing flood-prone areas based on implementation categories described in Section 15.1.3.1. The Flood Risk Reduction Strategy will focus on identification and prioritization of flood reduction efforts. The City will seek to maximize cost effectiveness and capitalize on coinciding opportunities, such as planned street reconstruction, redevelopment, availability of land, and other planned infrastructure improvement projects. Consideration will also be given to achieving additional “co-benefits”, such as water quality improvements, open space expansion, and wildlife habitat improvement. When completed, the Flood Risk Reduction Strategy will be included as an amendment to this CWRMP. The City recognizes that addressing regional and local flood issues throughout the community will require multiple strategies and many actions implemented over a generational time frame. The City will employ the strategies and associated actions summarized in Table 1.1 for addressing flood issues. Table 1.1 Strategies and Potential Actions for Addressing Local and Regional Flood Issues Strategies Potential Actions Modify the flood Plan, preserve and reclaim flood storage (new public and private stormwater plans, deeds, easements, open space) Maintain and increase green space Maintain and increase storage (ponds, underground chambers, streets, depressions) Protect flow paths and emergency overflows Manipulate timing of peak flow Divert water Control rate of peak flow Detain and slowly release flow Reuse water for beneficial purposes Employ Green Infrastructure (GI) and Low Impact Development (LID) standards Modify susceptibility Elevate structures Reduce impacts Floodproof structures Enforce substantial improvement limits Elevate utilities Encourage flood insurance Encourage preparedness planning Encourage resilient landscaping Provide risk audits Limit infiltration and inflow to the sanitary system Maintaining existing floodplain infrastructure City of Edina 2018 Comprehensive Water Resources Management Plan 1-4 1.3 Clean Water Strategy As part of this 10-year plan, the City of Edina will develop a clean water implementation strategy that outlines a plan for working toward meeting its clean water goals. The strategy will address the City’s approach to meeting the pollutant reduction targets identified through the TMDL and WRAPS process. The strategy will also determine pollutant load reduction targets for nondegradation of water bodies that are not impaired and identify an approach for achieving these stormwater management targets. The clean water implementation strategy will be a 5-year strategy that identifies regular “good housekeeping” stormwater practices and clean water capital improvement projects (CIP) to achieve the goals, including quantification of pollutant removals and preparation of planning-level cost estimates. This information will be used for planning, as well as assessment of cost-benefit for project prioritization. The implementation strategy will be developed in coordination with street reconstruction projects, redevelopment, and other opportunities. Annual or biennial reporting will be included in the strategy to quantify movement toward the City’s goals and track activities for the City’s annual SWPPP and MS4 reporting. The Clean Water Strategy will define clean water goals, the cost and pace of achievement, and plan implementation opportunities based on implementation categories described in Section 15.2.3.1. When completed, the Clean Water Strategy will be included as an amendment to this CWRMP. Each of the clean water improvement opportunity categories identified above have opportunities for partnership with other entities, such as private land owners, watershed districts, non-profit organizations, or other local governmental entities. City of Edina 2018 Comprehensive Water Resources Management Plan 2-1 2.0 Introduction and Physical Setting 2.1 Plan Purposes This plan provides the City of Edina with a Comprehensive Water Resource Management Plan (CWRMP). The plan was developed to address current and future stormwater issues, especially those related to future development and redevelopment. The plan addresses stormwater runoff management and flood control, water quality management, and wetlands protection through establishment of stormwater planning policies and recommendations. The first goal of this CWRMP is to provide stormwater runoff management and flood control. Design criteria have been adopted to ensure that a proper level of service for stormwater management and level of protection from flooding, per the 1969 Floodplain Management Act, is provided to residents of the City. The established design criteria are discussed in Section 3.1. The current storm sewer system throughout the City has been analyzed using computer models and recommendations to improve runoff management and flood control have been made. Discussion on the stormwater analyses and the resulting implementation recommendations is included in Section 4.0 through Section 14.0. The second goal of the CWRMP is to provide water quality management for the water bodies throughout the City. Water quality management policies and design standards have been established to protect the water quality of the waterbodies within the City. These policies and design criteria are discussed in Section 3.3. A water quality model was used to simulate the generation and transport of pollutants through the waterbodies within the City. The model results were used to make recommendations for upgrades to water quality basins throughout the City to maintain and improve the pollutant removal efficiency from these basins. This analysis and the resulting implementation recommendations are discussed in Section 4.0 through Section 14.0. The third goal of the CWRMP is to provide wetland protection throughout the City. The City of Edina’s goal is to achieve no net loss of wetlands, including acreage, functions, and values. To achieve this goal, policies have been established to protect the wetlands within the City. These policies are included in Section 3.5. To provide a basis for wetland protection efforts, an inventory and assessment of all the wetlands within the City was completed. The wetland inventory and assessment identified wetland location, size, type, wetland classification, dominant wetland vegetation, function, and value for each wetland. General management recommendations are included based on the wetland sensitivity to stormwater degradation. The inventory and assessment is discussed in Section 16.0. This plan will assist the City of Edina in defining and implementing a comprehensive and environmentally sound system of surface water management. It is intended to be used as a tool to: 1. Plan for projects and other water management activities so as to correct existing problems and prevent foreseeable future problems from occurring. City of Edina 2018 Comprehensive Water Resources Management Plan 2-2 2. Assist the City in considering water resource impacts resulting from variances to the City’s long- range land use plan. 3. Enable the City to grow/redevelop in a systematic and orderly manner while protecting its vital water resources. In order to accomplish these objectives, the plan considers a specific array of land uses within the City limits. If and when land uses change, this plan provides the means to (1) address the proposed changes; (2) determine the impact of the changes on the City’s infrastructure, flooding, and natural resources; and (3) determine the actions needed within the proposed areas of land use change to prevent undesirable impacts. 2.2 Physical Setting 2.2.1 Drainage Patterns The City of Edina covers an area of approximately 16 square miles. There are two stream systems that flow through the City: Nine Mile Creek and Minnehaha Creek. The northeast corner of the City drains to Minnehaha Creek, which enters the City limits northwest of West 44th Street and Trunk Highway (TH) 100 and flows in a southeasterly direction through the City, exiting near West 54th Street and York Avenue. The southwest corner of the City drains to the South Fork of Nine Mile Creek through a series of storm sewer networks, ditches, and stormwater detention basins. The remainder of the City drains to the North Fork of Nine Mile Creek, which enters the Edina City limits in the northwest corner of the City near the intersection of TH 169 and Londonderry Road and meanders in a southeasterly direction through the City and exits the City limits near the intersection of TH 100 and Interstate 494 (I-494). For the purposes of this study, the City was divided into several major drainage areas based on drainage patterns. These drainage areas are depicted in Figure 2.1 and listed below: • Nine Mile Creek- North • Nine Mile Creek- Central • Lake Cornelia/Lake Edina/Adam’s Hill Pond • Nine Mile Creek- South • Nine Mile South Fork • Southwest Ponds • TH 169 North • Northeast Minnehaha Creek • Southeast Minnehaha Creek • Northwest Minnehaha Creek Various maps related to the City of Edina can be found online at the City’s “Maps” page: https://www.edinamn.gov/894/Maps City of Edina 2018 Comprehensive Water Resources Management Plan 2-3 Section 5.0 through Section 14.0 discuss the drainage patterns within each of these drainage areas and describe the recommended stormwater system improvements for each area. In some cases, the drainage areas may include portions of adjoining cities, including Hopkins, Minnetonka, Eden Prairie, Bloomington, Richfield, and Minneapolis. The 10 drainage basins listed above were subdivided into major watersheds and subwatersheds. Watershed divides were originally determined as part of the 2003 CWRMP using air- flown 2-foot topographic data. For this plan update, watershed divides were reviewed and, in some cases, were updated using newer data topographic data (2011 MnDNR LiDAR elevation data). 2.2.2 Watershed Management Organizations Edina lies within two major watersheds: the Minnehaha Creek watershed and Nine Mile Creek watershed. As a result, two watershed management organizations cover Edina, each with its own governing body. Additional information on the Minnehaha Creek Watershed District and Nine Mile Creek Watershed District is provided below. 2.2.2.1 Minnehaha Creek Watershed District The Minnehaha Creek Watershed District (MCWD) spans approximately 180 square miles and consists of 27 cities and three townships on the western edge of the Twin Cities area. The watershed includes eight major creeks, including Minnehaha Creek which meanders through the northeastern part of Edina. The MCWD also includes 129 lakes, including Lake Harvey and Melody Lake, and thousands of wetlands. The MCWD adopted their most recent watershed management plan (Minnehaha Creek Watershed District Watershed Management Plan) on January 11, 2018. More information is available at the MCWD website: www.minnehahacreek.org. 2.2.2.2 Nine Mile Creek Watershed District The Nine Mile Creek Watershed District (NMCWD) is approximately 50 square miles and encompasses the land area draining to Nine Mile Creek, including portions of Bloomington, Eden Prairie, Edina, Hopkins, Minnetonka, and Richfield. Portions of the North Fork and South Fork of Nine Mile Creek flow through Edina. The NMCWD also includes over 20 lakes, including Lake Edina, Lake Cornelia, Arrowhead Lake, Indianhead Lake, Hawkes Lake, Highlands Lake, and Mirror Lake, and many wetlands. The NMCWD adopted their most recent watershed management plan (Nine Mile Creek Watershed District Water Management Plan) on October 18, 2017. More information is available at the NMCWD’s website: http://www.ninemilecreek.org/ 2.2.3 Land Use The city of Edina is fully urbanized. Less than 1 percent of the developable area within the city, not including wetland, floodplain, or park land uses, remains available for development. Figure 2.2 shows the land use classifications for the city. The 2009 Edina Comprehensive Plan provides additional information about the existing and projected (2020) land uses in the city. An updated projected land use map (2030) will be prepared as part of the City’s upcoming comprehensive plan effort. The projected 2030 land use map will be provided online via the City’s “Maps” page, when available. City of Edina 2018 Comprehensive Water Resources Management Plan 2-4 2.2.4 Soils The infiltration capacity of soils affects the amount of direct runoff resulting from rainfall. Soils with a higher infiltration rate have a lower runoff potential. Conversely, soils with low infiltration rates produce high runoff volumes and high peak runoff rates. According to the Hennepin County soil survey, the underlying soils in the City of Edina are predominantly classified as hydrologic soil group B, with moderate infiltration rates. The underlying soils in the southern portions of the City are classified as hydrologic soil group A, characterized by high infiltration rates. The underlying soils surrounding the floodplain of Nine Mile Creek and Minnehaha Creek and around many of the natural wetlands within the City are classified as hydrologic soil group D, with very slow infiltration rates. Figure 2.3 depicts the hydrologic soils group classification for soils within the City of Edina. 2.2.5 Topography The topography of the City varies from relatively flat land along portions of Nine Mile Creek and Minnehaha Creek to very hilly land in the southwest portion of the City. Generally the topography throughout the City consists of moderately rolling hills. The elevations generally vary from 980 to 880 feet (National Geodetic Vertical Datum of 1929 or NGVD 29) at the divide between the Minnehaha Creek and Nine Mile Creek watersheds to elevations between 812 and 850 feet where each creek exits the City. The City of Edina has older 2-foot contour data (Markhurd, 2000) coverage for the entire City; this information was used for the 2003 CWRMP and is available from the City Engineering Department. The MnDNR has newer (2011) and higher resolution Light Detection and Ranging (LiDAR) topographic data that was used for this plan update. 2.2.6 Water Quality 2.2.6.1 Water Quality Monitoring 2.2.6.2 Lakes While the City of Edina does not have a water quality monitoring program, several lakes and streams within the city are monitored periodically by watershed districts and volunteer programs. The NMCWD conducts periodic monitoring of several lakes within the city, including Arrowhead Lake, Lake Cornelia, Lake Edina, Indianhead Lake, and Mirror Lake. The NMCWD’s lake monitoring program includes analysis of a range of parameters, including phosphorus, nitrogen, chlorophyll a, chlorides, clarity/transparency, temperature, pH, specific conductivity and dissolved oxygen. In addition, the NMCWD typically completes phytoplankton (algae) and zooplankton monitoring and conducts early-summer and late-summer aquatic plant (macrophyte) surveys. In addition to the lake monitoring data collected by the NMCWD, water quality data has also been collected for several lakes by citizen monitoring volunteers as part of the Metropolitan Council’s Citizen- Assisted Monitoring Program (CAMP). The lakes within the city that have been monitored as part of CAMP include Pamela, Cornelia, Edina, Harvey, and Hawkes lakes. The locations of these lakes are shown in Figure 2.4. Volunteer monitoring through the CAMP program has historically been funded by the watershed districts. City of Edina 2018 Comprehensive Water Resources Management Plan 2-5 A summary of the historic summer average total phosphorus concentrations for the monitored lakes in Edina is provided in Table 2.1. The summary reflects the data collected by both the NMCWD and the Metropolitan Council CAMP over the most recent ten years when data was collected. As can be seen in the table, the available data is limited for many of the Edina lakes. It should be noted that lakes and ponds are dynamic, so that relatively infrequent sampling cannot provide a complete picture of the status of the water body in question. The situation is further complicated by the impossibility of inferring statistically significant trends from relatively few water quality sampling results. A minimum of about 10 (summer average) data points is thought to be required to reliably identify a water quality trend. 2.2.6.3 Creeks The NMCWD has two continuous flow monitoring stations within or near Edina; one along the North Fork of Nine Mile Creek at the Metro Boulevard crossing, and another along the South Fork of Nine Mile Creek at the 78th Street crossing, just south of the city boundary with Bloomington (Figure 2.4). The monitoring stations collect data on stream flow and several water quality parameters, including turbidity, nutrients, and chlorides. The water quality monitoring data is available from the NMCWD upon request. The MCWD has two monitoring stations along Minnehaha Creek; one near the intersection of West 56th Street and Woodland Drive, just west of France Avenue, and another at Mill Pond, upstream of Browndale Dam. The west 56th Street station has consistently been monitored since 2009. MCWD had a third station, just below Browndale Dam, beginning in 1996. This station was discontinued in 2016. Continuous stream level data is collected to determine stream flow at the Mill Pond station. Instantaneous discharge and water quality samples are collected bi-weekly at the West 56th Street station. Samples are analyzed bi-weekly for total phosphorus and total suspended solids (TSS), and monthly for chloride during the months of March-October. E. coli is collected weekly during the months of April – October. Samples are analyzed monthly during the winter (November-February). City of Edina 2018 Comprehensive Water Resources Management Plan 2-6 Table 2.1 Summer (June-September) Average Total Phosphorus Concentrations for Edina Lakes Lake Year Summer Average Total Phosphorus Concentration (µg/L) Data Collection Entity 1,2 North Lake Cornelia 2007 211 MCES CAMP 2008 153 NMCWD and MCES CAMP 2009 111 MCES CAMP 2013 165 NMCWD and MCES CAMP 2014 84 MCES CAMP 2015 139 NMCWD and MCES CAMP 2016 114 NMCWD Average 144 South Lake Cornelia 2008 150 NMCWD 2013 114 NMCWD 2015 122 NMCWD 2016 149 NMCWD Average 134 Mirror Lake 2004 119 NMCWD 2012 104 NMCWD Average 112 Arrowhead Lake 2011 52 NMCWD 2014 65 NMCWD Average 58 Indianhead Lake 2011 53 NMCWD 2014 61 NMCWD Average 57 Harvey Lake 2011 53 CAMP Average 53 Pamela Lake 2004 78 CAMP 2005 73 CAMP Average 76 Lake Edina 2008 120 NMCWD 2012 146 NMCWD 2015 85 NMCWD Average 117 1 Metropolitan Council Environmental Services (MCES) Citizen Assisted Monitoring Program (CAMP) for Lakes 2 Nine Mile Creek Watershed District (NMCWD) lake monitoring program City of Edina 2018 Comprehensive Water Resources Management Plan 2-7 2.2.6.4 Impaired Waters and Total Maximum Daily Loads The federal Clean Water Act (CWA) requires states to adopt water quality standards to protect the nation’s waters. Water quality standards designate beneficial uses for each waterbody and establish criteria that must be met within the waterbody to maintain the water quality necessary to support its designated use(s). Section 303(d) of the CWA requires each state to identify and establish priority rankings for waters that do not meet the water quality standards. The list of impaired waters, or 303(d) list, is updated by the state every two years. For impaired waterbodies, the CWA requires the development of a total maximum daily load (TMDL). A TMDL is a threshold calculation of the amount of a pollutant that a waterbody can receive and still meet water quality standards. A TMDL establishes the pollutant loading capacity within a waterbody and develops an allocation scheme amongst the various contributors, which include point sources, non-point sources and natural background, as well as a margin of safety. As a part of the allocation scheme a waste load allocation is developed to determine allowable pollutant loadings from individual point sources (including loads from storm sewer networks), and a load allocation also establishes allowable pollutant loadings from non-point sources and natural background levels in a waterbody. Impaired waters located within the City of Edina, as identified by the MPCA’s 2016 Proposed Impaired Waters List, include: Lake Cornelia (North Basin), Lake Edina, Nine Mile Creek and Minnehaha Creek. The Draft 2018 Impaired Waters list also includes Lake Cornelia (South Basin) and the portion of Nine Mile Creek between Metro Boulevard and an unnamed wetland. These waterbodies are listed in Table 2.2 along with the affected MPCA designated use, the pollutant or stressor that is not meeting the MPCA water quality criteria, and the MPCA target for starting and completing the TMDL process. The MPCA is using a systematic watershed approach to address impaired waters and TMDLs, whereas intensive water quality monitoring and assessments are being conducted in each of the states 80 major watersheds during a 10-year cycle. The MPCA developed a process termed Watershed Restoration and Protection Strategy (WRAPS) to identify and address water quality threats in each major watershed. The four primary steps of the WRAPS process include 1) monitoring water quality and collecting data, 2) assessing the data, 3) developing strategies to restore and protect water bodies within the watershed, and 4) conducting restoration and protection projects. TMDLs are conducted for impaired water bodies as part of the WRAPS process. The MPCA initiated a WRAPS process in the Nine Mile Creek watershed in 2016, with completion anticipated in 2017. The City of Edina is participating in the process as a stakeholder. An anticipated outcome of the process is an approved TMDL for Lake Cornelia (North and South basins), Lake Edina, and Nine Mile Creek. The MPCA will likely conduct a WRAPS process (and TMDL) in the Minnehaha Creek watershed during 2020-2024, based on the schedule identified in the 2016 Proposed Impaired Waters list. Following TMDL completion, the TMDL requirements will be incorporated into the City’s NPDES Phase II MS4 permit. It may also be necessary to amend the City’s CWRMP to incorporate future TMDL requirements. City of Edina 2018 Comprehensive Water Resources Management Plan 2-8 Table 2.2 City of Edina waterbodies on MPCA's 303(d) Impaired Waters List Reach/Waterbody Description Affected Use Pollutant or Stressor Target Dates for Starting/Completing TMDL Lake Cornelia (North Basin) 1 Aquatic Recreation Nutrient/Eutrophicat ion Biological Indicators 2014/2019 Lake Cornelia (South Basin)2 Aquatic Recreation Nutrient/Eutrophicat ion Biological Indicators 2014/2019 Lake Edina1 Aquatic Recreation Nutrient/Eutrophicat ion Biological Indicators 2014/2019 Nine Mile Creek1 Headwaters to Minnesota River Aquatic Life Fish Bioassessments 2014/2019 Nine Mile Creek2 Metro Boulevard to end of unnamed wetland Aquatic Life Aquatic macroinvertebrate bioassessments 2024/2029 Nine Mile Creek2 Metro Boulevard to end of unnamed wetland Aquatic Life Fish Bioassessments 2024/2029 Minnehaha Creek1 Lake Minnetonka to Mississippi River Aquatic Life Aquatic Macroinvertebrate Bioassessments 2020/2024 Minnehaha Creek1 Headwaters to Minnesota River Aquatic Life Fish Bioassessments 2020/2024 Minnehaha Creek1 Lake Minnetonka to Mississippi River Aquatic Recreation Fecal Coliform 2007/2012 Minnehaha Creek1 Lake Minnetonka to Mississippi River Aquatic Life Chloride 2007/2012 Minnehaha Creek1 Lake Minnetonka to Mississippi River Aquatic Life Dissolved Oxygen 2020/2024 1 Information based on the 2016 proposed impaired waters list, sent to USEPA for approval on January 4, 2017. 2 Information based on the draft 2018 impaired waters list, submitted for EPA approval on April 4, 2018. Nine Mile Creek Nine Mile Creek is currently on the 303(d) Impaired Waters List for an aquatic life impairment due to a fish biota impairment. In 2009, the MPCA and NMCWD began development of a TMDL to address the biotic impairment. The City of Edina participated as a stakeholder in the TMDL process. The TMDL included a biological stressor identification study to determine the causes of the Nine Mile Creek biological impairment for fish (MPCA, 2010). The study concluded: City of Edina 2018 Comprehensive Water Resources Management Plan 2-9 • The probable cause of impairment on the South Fork of Nine Mile Creek is inadequate dissolved oxygen. Although the impairment can be caused by numerous stressors, the data suggests that inadequate dissolved oxygen is the most prominent of the stressors, followed by excess sediment and inadequate base flow. • The probable causes of impairment on the North Fork of Nine Mile Creek are inadequate dissolved oxygen and excess sediment. In 2004, the MPCA determined that Nine Mile Creek did not meet the chloride standard for streams and listed Nine Mile Creek as impaired. A TMDL was completed in 2010 to identify management measures to reduce chloride levels in Nine Mile Creek. The study determined that a 63% reduction in the existing watershed chloride load estimated for Nine Mile Creek would be required, to be achieved through management of road salt inputs from both road authorities and commercial and private applicators. Minnehaha Creek Minnehaha Creek is currently on the 303(d) list for several impairments, including an aquatic life impairment due to fish biota, aquatic macroinvertebrates, chloride, and dissolved oxygen and an aquatic recreation impairment due to fecal coliform. Lake Hiawatha, located on Minnehaha Creek downstream of the City of Edina, is also on the impaired waters list for excess nutrients and eutrophication biological indicators. The MPCA and MCWD initiated the TMDL development process in 2009 to address an E. coli bacteria impairment (originally listed as fecal coliform) in Minnehaha Creek and a nutrient impairment in downstream Lake Hiawatha. The City of Edina participated in the stakeholder process. The TMDL, approved in 2014, includes a categorical E. coli wasteload allocation for all MS4s within the watershed and a 50% total phosphorus load reduction target to Minnehaha Creek (MPCA, 2013). The chloride impairment for Minnehaha Creek is being addressed as part of the Twin Cities Metropolitan Area Chloride Total Maximum Daily Load Study (MPCA, 2016). The MPCA’s 2016 proposed 303(d) list also includes an aquatic life impairment for Minnehaha Creek due to low dissolved oxygen levels. Lake Cornelia In 2004–2005, the NMCWD completed a draft use attainability analysis (UAA) for Lake Cornelia, which is a scientific assessment of a water body’s physical, chemical, and biological condition (Barr Engineering, 2006). The study included a water quality assessment and prescription of protective and/or remedial measures for the lake and its tributary watershed. In 2010, the NMCWD updated the study based on additional lake water quality data, to verify the conclusions of the draft UAA and evaluate several additional remedial measures to improve lake water quality. Lake Cornelia (North Basin) is included on the MPCA’s 2016 Proposed Impaired Waters list for excess nutrients and eutrophication biological indicators; Lake Cornelia (South Basin) is also included on the City of Edina 2018 Comprehensive Water Resources Management Plan 2-10 MPCA’s Draft 2018 Impaired Waters list. The Lake Cornelia impairments are to be addressed as part of the WRAPS process being led by the MPCA and NMCWD, with a targeted TMDL completion date of 2019. The City of Edina will partner with the NMCWD in implementing potential remedial measures for the lake(s) and its watershed recommended as part of the NMCWD UAA and MPCA WRAPS to improve the quality of Lake Cornelia. Lake Edina Lake Edina is included on the MPCA’s Impaired Waters list for excess nutrients and eutrophication biological indicators. The Lake Edina impairment is to be addressed as part of the WRAPS process being led by the MPCA and NMCWD, with a targeted TMDL completion date of 2019. The City of Edina will partner with the NMCWD in identifying and implementing potential remedial measures for the lake and its watershed recommended following the MPCA WRAPS process to improve the quality of Lake Edina. Other Downstream Waterbodies There are also impaired lakes and streams outside the City that receive stormwater from Edina and will be the subject of TMDL studies, including Lake Hiawatha, the Mississippi and Minnesota Rivers, and Lake Pepin. The City has been assigned a wasteload allocation to address the Lake Hiawatha TMDL. The City may need to amend the CWRMP to implement future requirements related to any downstream body. 2.2.7 Parks, Recreation, and Natural Resources Open Space The City of Edina has numerous community parks, neighborhood parks, and other public open space recreational areas. Figure 2.5 shows the numerous parks and recreational areas within the City of Edina. Lakes, ponds, and creeks are often key attractions in public parks; examples within Edina include Arden Park, Bredesen Park, Pamela Park, Rosland Park, Utley Park, Centennial Lakes Park, and Weber Woods Park. The City of Edina currently owns and maintains approximately 350 acres of natural resource open space areas, which includes 148 acres along the Nine Mile Creek right-of-way and 23 acres along the Minnehaha Creek right-of-way. The city is basically fully developed, and is therefore no longer actively acquiring additional property to develop as park land or open space. However, the City plans to retain all of the current publicly owned park land and consider any additional property that may be offered in the future as potential additional park property. The City will also seek to acquire additional park and open space land as more private land becomes available for public acquisition. 2.2.8 Public Utilities Edina is completely within the Metropolitan Council’s designated Metropolitan Urban Service Area (MUSA). The MUSA is the area in the seven county metro area in which the Metropolitan Council ensures that regional services and facilities are provided or planned. The City of Edina provides sanitary sewer and water service throughout the City. City of Edina 2018 Comprehensive Water Resources Management Plan 2-11 2.2.9 Fish and Wildlife Habitat The water bodies and open spaces interspersed throughout the City provide habitat for numerous fish and wildlife species, including birds, mammals, and reptiles. Ducks and geese are present in large numbers at lakes, wetlands, and open water areas. Vegetative cover in the undeveloped open areas support many mammalian species such as deer, raccoon, squirrels, fox, chipmunks, and rabbits. The wetlands in Edina provide habitat for a variety of aquatic species including snakes, turtles, and frogs. The Minnesota Department of Natural Resources (MnDNR) has completed fishery surveys of four lakes within the City of Edina. The most recent surveys were of Lake Cornelia in 2010 and Centennial Lake in 2011. Both of these lakes are part of the MnDNR’s Fishing in the Neighborhood program. Lake Cornelia, Centennial Lake, and Indianhead Lake have been stocked by the MnDNR in recent years. Arrowhead Lake was observed to be infested with the invasive aquatic plant Eurasian Watermilfoil; Minnehaha Creek was observed to be infested with invasive Eurasian Watermilfoil, Flowering Rush, and Zebra Mussels. Table 2.3 summarizes the available fishery survey, stocking, and aquatic invasive species information available for the water bodies within the City of Edina. City of Edina 2018 Comprehensive Water Resources Management Plan 2-12 Table 2.3 Fishery and Aquatic Invasive Species Information Water Resource Survey Year Fishery 1 Stocking 2 Dominant Fish Species Invasive Species 3 and Year Species Was First Confirmed Lakes Lake Cornelia 2005 Bluegill: 2001-2005 Bluegill, Black Crappie, Carp N/A 2010 Bluegill: 2007-2012, 2014-2016 Black Crappie: 2014 Hybrid Sunfish: 2014 Pumpkinseed Sunfish: 2014 Black Bullhead N/A Arrowhead Lake 1995 Bluegill: 1994 Largemouth Bass: date unknown Black Bullhead, Green Sunfish Eurasian Watermilfoil (1995) Centennial Lake 2006 Bluegill: 2001-2006, Largemouth Bass: 2002-2006 Black Bullhead, Green Sunfish N/A 2011 Bluegill: 2007-2012, 2014-16 Black Crappie: 2017 Largemouth Bass: 2007-2009, 2014 Northern Pike: 2007-2010, 2013-2014 Pumpkinseed Sunfish: 2016 Black Bullhead, Hybrid Sunfish N/A Indianhead Lake N/A Bass: 2008 Black Crappie: 2008 Bluegill: 2008-2009 Walleye: 2008 N/A N/A Streams Minnehaha Creek N/A N/A N/A Eurasian Watermilfoil (1989), Flowering Rush (2009), Zebra Mussels (2010) Meadowbrook (connected to Minnehaha Creek) N/A N/A N/A Zebra Mussels (2010) Edina Mill Pond (connected to Minnehaha Creek) N/A N/A N/A Zebra Mussels (2010) 1 – Fisheries information from the MnDNR LakeFinder website (http://www.dnr.state.mn.us/lakefind/) 2 – Stocking reports available for 1998-2016 from the MnDNR LakeFinder website (http://www.dnr.state.mn.us/lakefind/) 3 – Invasive species information from MnDNR Infested Waters List website (http://www.eddmaps.org/midwest/tools/infestedwaters/) City of Edina 2018 Comprehensive Water Resources Management Plan 2-13 2.2.10 Unique Features and Scenic Areas The MnDNR Natural Heritage Program and Nongame Wildlife Program maintain a database of rare plant or animal species and significant natural features. This database includes only one record of a rare or threatened species observance in Edina; a Blanding’s Turtle (Emydoidea Blandingii) was observed in 1989 in the southeast portion of the City (see Figure 2.6). The Blanding’s Turtle was classified as a threatened species in Minnesota in 1984. Other information was reviewed to determine whether other unique features area present in Edina. Based on this review, no Outstanding Resource Value Waters (Minnesota Rules 7050.0180), Designated Scientific and Natural Areas (Minn. Stat. 86A.05), State Wildlife Management Areas (Minn. Stat. 86A.05), or State Aquatic Management Areas (Minn. Stat 86A.05) are located within the City of Edina. 2.2.11 Pollutant Sources The MPCA’s “What’s in My Neighborhood” online application provides a variety of environmental information for communities. The interactive web map provides information about environmental permits issues by the MPCA, registrations and notifications required by the MPCA, and investigations of potentially contaminated properties undertaken by the MPCA or its partners. The map shows the approximate locations of registered storage tanks, leak sites, hazardous waste generators, dump sites, Superfund sites, and Minnesota Pollution Control Agency (MPCA) Voluntary Investigation and Cleanup (VIC) sites, as obtained from the Hennepin County Department of Environmental Services. The Hennepin County Department of Environmental Services should be contacted for details about specific sites, since many of the sites have been cleaned up or are in the clean-up process. 2.2.11.1 Investigation and Cleanup Sites Dump sites include both unpermitted and permitted dump sites. Unpermitted dump sites are historic landfills that never held a valid permit from the MPCA. Generally, these dump sites existed prior to the MPCA’s permitting program, which was initiated in 1967. Unpermitted dump sites were often old farm or municipal disposal sites that accepted household waste. The MPCA VIC Program is a non-petroleum brownfield program that provides technical assistance and administrative or legal assurances for individuals or businesses seeking to investigate or clean-up contaminated property and to bring contaminated land back into productive use. There is currently one MPCA Superfund Site within the City of Edina. This site is the Edina Well Field. Additional information on this site can be obtained from the MPCA. In the early 2000s, the City of Edina detected elevated levels of vinyl chloride in Municipal Well Number 7. Preliminary investigations found several volatile organic compounds in nearby groundwater resulting in the City discontinuing use of Well Number 7 in October 2003. Well Number 7 came online again after a high-capacity treatment plant (Water Treatment Facility No. 6) was built at the Danen’s Building (5116 Brookside Avenue) in 2012. The plant is equipped with an aeration system specially designed to filter out vinyl chloride. The City regularly tests for vinyl chloride and Edina’s water meets the criteria set forth by the Environmental Protection Agency. City of Edina 2018 Comprehensive Water Resources Management Plan 2-14 2.2.11.2 Tank Sites and Leak Sites Tank sites include registered petroleum tank facilities, both underground and above ground. Leak sites are locations where a release of petroleum products has occurred from a tank system. Leak sites can occur from aboveground or underground tank systems, or from spills at tank facilities. A leak can result from an accident or from activities that occurred over a long period of time. Many of the known leak sites are related to releases from underground fuel oil tanks. 2.2.11.3 Individual Sewage Treatment Systems If properly functioning, individual sewage treatment systems (ISTS) typically do not impact the water quality of surface or ground water resources. However, improperly functioning systems can negatively impact water resources and are a source of ground and surface water contamination. City records indicate that there are five known ISTS throughout the City. 2.2.12 Groundwater The City of Edina operates two separate water systems: the Morningside water system and the Edina water system. The Morningside system is supplied with treated surface water from the City of Minneapolis; the City of Edina does not appropriate any surface water for its municipal water supply. The water supply for the Edina system is groundwater, obtained from 18 groundwater wells, ranging in depth from 450 to 1,100 feet. The City’s current groundwater appropriation permit limits the City’s groundwater pumping to 17,500 gallons per minute or 3,000,000,000 gallons per year. Wellhead protection programs are intended to help prevent contamination of public drinking water supplies. The City’s Wellhead Protection Plan is available online. Part II of the Wellhead Protection plan includes results of the City’s Potential Contaminant Source Inventory (PCSI). Wellhead Protection information can also be found on the City’s Interactive Water Resources Map. Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Min n e h a h a Cr e ek Nine Mile Creek - North Nine MileCreek - Central Nine MileCreek - South SoutheastMinnehaha Creek SouthwestPonds NorthwestMinnehaha Creek Nine Mile -South Fork Lake Cornelia/Lake Edina/Adam's Hill NortheastMinnehaha Creek TH 169North £¤169 100 62 100 456717 456731 4567158 456731NorthBranchN i ne Mile C reek SouthBranc h N ine Mile C r eekMinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-09-20 17:37 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_2_1_Major_Drainage_Areas.mxd User: EMAMAJOR DRAINAGE AREASComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 2.1 0 3,000 Feet !;N Streets and Highways Creek/Stream Lake/Pond City of Edina Boundary Imagery Source: MnGeo 2016 Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Min n e h a h a Cr e ek £¤169 100 62 100 456717 456731 4567158 456731 NorthBranchNineMileCreek SouthBranc h N ine Mile C r eekMinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-09-21 08:39 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_2_2_Edina_Soils_Classification.mxd User: EMALAND USE CLASSIFICATIONComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 2.2 0 3,000 Feet !;N Land Use Classification Agricultural Natural/Park/Open Developed Parkland Golf Course Very Low Density Residential Low Density Residential Medium Density Residential High Density Residential Institutional Institutional - High Imperv. Airport Highway Roads Commercial Industrial/Office Other Open Water Wetland Graded Pit Streets and Highways Creek/Stream City of Edina Boundary Imagery Source: MnGeo, 2016 1Data Source: City of Edina, 2000 1 Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Min n e h a h a Cr e ek £¤169 100 62 100 456717 456731 4567158 456731 NorthBranchNineMileCreek SouthBranc h N ine Mile C r eekMinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-09-21 08:39 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_2_2_Edina_Soils_Classification.mxd User: EMAEDINA SOILS CLASSIFICATIONComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 2.3 0 3,000 Feet !;N Hydrologic Soil Groups A - High infiltration rates. Low runoff Potential. B - Moderate infiltration rates. Low to medium runoff potential. C - Slow infiltration rates.Medium to high runoff potential. D - Very slow infiltration rates. High runoff potential. Water Streets and Highways Creek/Stream City of Edina Boundary Imagery Source: MnGeo, 2016 ^_ ^_ ^_ ^_ ^_ ^_ ^_ ^_ ¸# ¸# ¸# Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Min n e h a h a Cr e ek £¤169 100 62 100 456717 456731 4567158 456731 Nine Mile CreekWatershed District Minnehaha CreekWatershed District NorthBranchNineMileCreek SouthBranc h N ine Mile C r eekMinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-09-25 15:47 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_2_4_Water_Quality_Monitoring_Stations.mxd User: EMAWATER QUALITYMONITORING STATIONSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 2.4 0 3,000 Feet !;N ¸#MCWD StreamMonitoring Station1 ¸#NMCWD Stream Monitoring Stations1 ^_Lake Water Quality Sampling Locations1 Watershed District Boundary Streets and Highways Creek/Stream Lake/Pond City of Edina Boundary Imagery Source: MnGeo, 2016 1Monitoring is conducted periodicallyby NMCWD, MCWD, and CAMP Volunteers. Watershed district monitoring is on a rotating basis based on each district plan. Volunteer monitoring sites are subject to change. North B ranchNineMileCreek SouthBranc h Nine Mile C r eekMud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes M in ne h a h a C r ee k£¤169 100 62 100 456717 456731 4567158 456731 Braemar Park (Courtney Fields) Bredesen Park Rosland Park Pamela Park Lewis Park Highlands Park Walnut Ridge Park T. Lea Todd Park Open Space 1 Heights Park Garden Park Heights Park Lincoln Drive Floodplain Van Valkenburg Park Fred Richards Golf Course Arden Park Krahl Hill Creek Valley School Park Lake Edina Park Normandale Park Weber Field Park Arneson Acres Park Countryside Park Weber Woods Centennial Lakes Park Open Space 2 Open Space 3 Centennial Lakes Park Alden Park Utley Park Open Space 2 Moore Property Pamela Park York Park Yorktown Park Centennial Lakes Park Cornelia School Park Wooddale Park Strachauer Park Garden Park Open Space 5 Fox Meadow Park Kojetin Park Edinborough Park Arden Park Garden Park McGuire Park Fox Meadow Park Birchcrest Park Sherwood Park Garden Park Addition Melody Lake Park Chowen Park Open Space 2 Centennial Lakes Park St. John's Park Tingdale Park York Park Browndale Park York Park Frank Tupa Park Grandview Square Open Space 6 MinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-09-21 08:47 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_2_4_Edina_Parks_and_Recreation_Areas.mxd User: EMAPARKS ANDRECREATIONAL AREASComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 2.5 0 3,000 Feet !;N Park/Recreational Area Streets and Highways Creek/Stream Lake/Pond City of Edina Boundary Imagery Source: MnGeo, 2016 Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Min n e h a h a Cr e e k £¤169 100 62 100 456717 456731 4567158 456731 NorthBranchNineMileCreek SouthBranc h N ine Mile C r eekMinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-10-03 09:45 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_2_6_Threatened_and_Endangered_Species.mxd User: EMATHREATENED ANDENDANGERED SPECIESComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 2.6 0 3,000 Feet !;N NHIS Rare Natural Features Vertebrate Animal Community Vascular Plant Animal Assemblage Streets and Highways Creek/Stream Lake/Pond City of Edina Boundary Imagery Source: MnGeo, 2016 Data Source:Natural Heritage Information System Rare Features DataCopyright 2017 State of Minnesota,Department of Natural Resources City of Edina 2018 Comprehensive Water Resources Management Plan 3-1 3.0 Policies for Water Resources Management 3.1 Runoff Management and Flood Protection 3.1.1 Runoff Management and Flood Protection Background Just as watershed models are used to define problem areas within the drainage system, design criteria (standards for design) are used to define solutions to the problems. Municipal drainage systems provide service (removal of runoff water) and protection (control of flood levels). It is useful to have criteria for both the level of service and the level of protection to be provided by the drainage system. In addition, at ponds and low-lying areas it is common to add a factor of safety in the form of added elevation above the projected flood level (freeboard) or extra volume. It is important to understand the difference between flood control level of service and level of protection when designing and analyzing stormwater systems. Level of service is defined as the capacity provided by a municipal drainage system to remove runoff and prevent significant interference with normal daily transportation, commerce, or access that might result from a rainstorm. For example, gutters might run full, but when the runoff arrives at a catch basin it would enter the catch basin and be carried away by the storm sewer. Intersections would not be inundated to an extent that adversely impacts driving conditions, right-of-way would be undamaged, and public infrastructure would operate normally. The modern standard of practice is usually that systems be designed for the “10-year” (10-percent-annual chance) storm event, which means that there is roughly a 10 percent probability in any year that the system will be overtaxed and unable to meet these criteria. In many communities, older systems were designed for smaller storm events such as a “2-year” event or a “5-year” event. Intersection flooding is common in these areas. Level of protection is defined as the capacity provided by a municipal drainage system to prevent property damage and assure a reasonable degree of public safety following a rainstorm. For example, runoff might bypass a catch basin and collect in low-lying areas such as intersections, but would not cause flood damage to structures. Accumulated water might temporarily interfere with traffic or access, but right-of-way should be undamaged and public infrastructure should operate normally. Safety should not be significantly threatened, assuming persons use common sense and don’t drive into the standing water or try to walk or swim in fast-flowing water. The stormwater system must have the capacity (in terms of pipe capacity, overland overflow capacity, or detention volume) to limit the flood elevation to acceptable levels for an event representing the protection criteria. Flood frequency data is often also described in terms of a percentage of risk, or annual exceedance probability. For example, the 100-year frequency flood inundation area represents an area that has a 1- percent chance of flooding for any given year (1-percent-annual-chance flood). Structures located within the 1-percent-annual-chance flood inundation area have a 26 percent chance of flooding during the life Plan and policy supporting documentation can be found online through the “Edina Docs” Water Resources Library: http://edinadocs.edinamn.gov/ City of Edina 2018 Comprehensive Water Resources Management Plan 3-2 of a standard 30-year mortgage. Federal and state programs use criteria based on the 1-percent-annual- chance flood event to define the floodplain along rivers and streams, and cities and other drainage authorities commonly extend this standard to other areas. A 1-percent-annual-chance event is also a common standard for design of detention basins. A 1-percent-annual-chance design for a ponding area means the pond has adequate volume to hold the 1-percent probable runoff and infers that adjacent structures will be above the level of the ponded water. However, the criterion for level of protection has broader application. In addition to ponding areas, lakes, and streams, this criterion should be applied to all locations served by the drainage system where there are depressed intersections or other areas subject to temporary, unplanned flooding. In 2013, the National Oceanic and Atmospheric Administration’s (NOAA’s) National Weather Service (NWS) published new precipitation frequency estimates (“Atlas 14”) for the state of Minnesota and other Midwestern states (NOAA, 2013). The Atlas 14 precipitation frequency estimates, which are the estimated rainfall depths for various rainfall durations and exceedance probabilities, replace the precipitation estimates published in Technical Paper No. 40 Rainfall Frequency Atlas of the United States (“TP 40”) (U.S. Department of Commerce, 1961). The Atlas 14 rainfall frequency estimates indicate a significant increase in the depth of the 50-year and 100-year frequency rainfall events (i.e., rainfall events with exceedance probabilities of 2% and 1%, respectively) across Minnesota and neighboring states, as compared with TP 40 estimates. For the Minneapolis/St. Paul area, the increases in 24-hour duration precipitation depths over TP 40 are as high 25%. These precipitation depth increases are of concern, as they can have serious implications for how stormwater systems are designed and managed. Since the 2013 release of Atlas 14, the Nine Mile Creek Watershed District has updated their hydrologic and hydraulic models to reflect the updated precipitation frequency estimates and has adopted revised flood management elevations. The City of Edina has also updated their hydrologic and hydraulic models to reflect Atlas 14 precipitation. However, FEMA’s effective Flood Insurance Rate Map (FIRM) and Flood Insurance Study (FIS) within the city of Edina are still based on TP-40 rainfall depths. Table 3.1 identifies the source of the best available 1-percent-annual-chance flood elevations for various portions of the City at the time of this plan development. City of Edina 2018 Comprehensive Water Resources Management Plan 3-3 Table 3.1 Source of the Best Available 1-Percent-Annual Chance Flood Elevations throughout the City of Edina Area Best Available Flood Elevation Information/Modeling Source of Precipitation Frequency Estimates Owner Nine Mile Creek corridor NMCWD Atlas 14 Flood Management Elevations and associated XP-SWMM Model(s) Atlas 14 NMCWD Minnehaha Creek corridor FEMA Effective Flood Insurance Rate Map (FIRM) and Flood Insurance Study (FIS) TP-40 MCWD City of Edina, with exception of Nine Mile Creek and Minnehaha Creek corridor areas City of Edina 2017 CWRMP or subsequent XP- SWMM model updates Atlas 14 City of Edina 3.1.2 Runoff Management and Flood Protection Policies The following sections present the City of Edina’s policies and design standards that address runoff management and flood control. In addition to the policies discussed below, the City has entered into water resource management related agreements with watershed districts and adjacent cities. • City of Bloomington: for the area of the Border Basin • City of Eden Prairie: for the area along Washington Avenue • City of Richfield: for the outlet from Adam’s Hill Pond • City of Hopkins: for the area east of Blake Road and along TH 169 • City of St Louis Park: for Meadowbrook Golf Course and Morningside area • Minnehaha Creek Watershed District: for Arden Park, Pamela Park Water Quality Improvements, and the 2014 Memorandum of Understanding outlining spheres of collaboration • Nine Mile Creek Watershed District: for the Edina Streambank Stabilization project and Pentagon Park assessment and planning (in cooperation with the City of Bloomington). The City adopts the following general runoff management and flood protection policies (Sections 3.1.2.1 through 3.1.2.3 provide specific policies and standards): 1. No flow rate increases in already overtaxed stormwater systems. 2. The City will place a high priority on providing 1-percent-annual-chance level of protection for the City’s stormwater detention and conveyance systems, where detention is provided (e.g., low point intersections, ponds, planned flood area, etc.). The City will require new stormwater systems Water resource management- related agreements that the City has entered with other public and private organizations can be found online through the “Edina Docs” Water Resources Library: http://edinadocs.edinamn.gov/ City of Edina 2018 Comprehensive Water Resources Management Plan 3-4 to provide 1-percent-annual-chance level of protection. Existing systems (conveyance and detention) that currently do not provide 1-percent-annual-chance level of protection will be modified to provide 1-percent-annual-chance level of protection when feasible. Potential additions and modifications to the stormwater system are discussed in Section 5.0 through Section 14.0 and summarized in Table 15.2. 3. The City will require new stormwater conveyance systems to provide a 10-percent-annual-chance (10-year) level of service. Existing stormwater conveyance systems that currently do not provide a 10-percent-annual-chance level of service will be modified, as opportunities arise and as feasible. 4. For new development and redevelopment, peak flow rates will be limited in accordance with the applicable rules of the Nine Mile Creek Watershed District and Minnehaha Creek Watershed District. 5. It is the City’s standard practice to provide a 10-percent-annual-chance level of service and 1- percent-annual-chance level of protection for the City’s stormwater conveyance systems, where feasible. However, some existing stormwater conveyance systems have capacity limitations and cannot be guaranteed to provide the discharge capacity where private storm sewer systems tie into the trunk system. 6. The City will determine the applicable 1-percent- annual-chance flood elevation(s) by using the best information available at the time. For regional flood areas, the applicable 1-percent-annual-chance flood elevation will be based on FEMA’s effective Flood Insurance Rate Map (FIRM) and Flood Insurance Study (FIS), flood management elevations adopted by the respective watershed district, or hydrologic and hydraulic model(s) developed by the respective watershed district, whichever is higher. For local flood areas, the applicable 1-percent-annual-chance flood elevation will be based on the City’s 2018 CWRMP or subsequent XP-SWMM model updates. The applicable 1-percent-annual-chance flood elevations are subject to change due to periodic model updates that incorporate additional or more accurate information and may differ from the flood elevations identified in this plan. For a regional flood area, the applicable 1-percent-annual chance flood elevation (also called the Special Flood Hazard Area) is based on the higher of FEMA’s effective Flood Insurance Rate Map (FIRM) and Flood Insurance Study (FIS), flood management elevations adopted by the respective watershed district, or hydrologic and hydraulic model(s) developed by the respective watershed district. A local flood area is the area below the modeled 1-percent-annual chance flood elevation for areas outside of the regional flood area. These areas are described in detail in Sections 5-14 of this plan. Generally, regional flood conditions tend to persist longer than local flood conditions. City of Edina 2018 Comprehensive Water Resources Management Plan 3-5 7. The applicable 1-percent-annual-chance flood elevation will be based on a 24-hour duration precipitation event, unless an event of another duration is determined to result in a higher flood elevation. 8. The City will allow outlets from landlocked basins only when such outlets are at or above the 1- percent-annual-chance floodplain, are consistent with state and federal regulations, and the downstream, riparian, and habitat impacts of such outlets have been analyzed and no detrimental impacts result. An exception to this policy is the City will allow an outlet below the 1-percent- annual-chance floodplain elevation in situations where public safety is threatened and/or inundation of principle structures would be likely if the outlet is at a higher elevation. 3.1.2.1 Minimum Principle Structure Elevations To prevent flooding of principle (non-detached) structures, the City will implement the following standards in addition to the Floodplain Overlay Districts ordinance (City Code Chapter 36, Article 10). 1. New principle structures, additions, and other permanent fixtures including heating and air conditioning ventilation systems must have a lowest floor elevation at least two feet above the applicable 1-percent-annual-chance flood elevation if one or more of the following conditions exist: a. The structure is within or adjacent to a regional flood area; b. The structure is within a local flood area subject to regional tailwater effects; c. The structure is within a local flood area that is land-locked; d. The City Engineer determines the structure to be at significant risk due to seepage. 2. New principle structures that are not subject to 3.1.2.1 (1) and are adjacent to a ponding basin must have a lowest floor elevation at least two feet above the ponding basin outlet elevation. New principle structures that require a watershed district permit must conform to their minimum elevation standards. Ponding basin describes an area used for long term or extended flood storage, for example detention basins/ponds, retention basins/ponds, infiltration basins, natural waterbodies, or other areas that provide flood storage either by design or naturally. Temporary storage area describes an area used for short term, temporary flood storage, for example backyard depression areas, streets, parking lots, or other areas that provide temporary short term flood storage either by design or naturally. Lowest floor elevation is the floor elevation of the lowest enclosed area (including basement). Lowest entry elevation is the lowest opening of a structure, for example windows, window well sill elevations, or walkout elevations. City of Edina 2018 Comprehensive Water Resources Management Plan 3-6 3.New principle structures, additions, and other permanent fixtures including heating and air conditioning ventilation systems must have a lowest entry elevation at least two feet above the applicable 1 percent-annual-chance flood elevation if one or more of the following conditions exist: a.The structure is within or adjacent to a local flood area; b.The structure is within or adjacent to a temporary storage area, emergency overflow, or stormwater conveyance; the 1-percent-annual-chance flood elevation of the temporary storage area, emergency overflow, or stormwater conveyance at the point where the temporary storage area, emergency overflow, or stormwater conveyance is closest to the structure applies. 4.New principle structures, additions, and other permanent fixtures including heating and air conditioning ventilation systems that are within or adjacent to a surface conveyance must have a lowest entry elevation at least two feet above the modeled 1 percent-annual-chance flood elevation at the point where the surface conveyance is closest to the structure applies. 5.New principle structures, additions, and other permanent fixtures including heating and air conditioning that are within or adjacent to a landlocked basin must have a lowest floor elevation that is at least two feet above the water level resulting from two concurrent 1-percent-annual chance, 24-hour rainfall events or two feet above the 1-percent-annual chance 10-day snowmelt, whichever is higher. In either case, the starting elevation of the basin/waterbody prior to the runoff event should be established by one of the following: i.Existing Ordinary High Water level established by the MnDNR; ii.Annual water balance calculation approved by the City; iii.Local observation well records, as approved by the City; or iv.Mottled soil. Note: The landlocked basin 1-percent-annual-chance flood elevation may be lowered by creating new storage, excavating an overflow swale or installing an outlet pipe at an overflow point. 3.1.2.2 Below-Grade Garages and Parking Adjacent to Flood-Prone Areas To prevent flooding of below-grade garages and parking facilities, the City will implement the following design standards: 1.Construction of below-grade parking garages in residential structures in local flood and regional flood areas is prohibited. City of Edina 2018 Comprehensive Water Resources Management Plan 3-7 For further guidance including requirements and certification of below-grade parking garages, review the following; •FEMA’s Technical Bulletin 6- 93, “Below-Grade Parking Requirements for Buildings Located in Special Flood Hazard Areas” •FEMA’s Technical Bulletin 3- 93, “Non-Residential Floodproofing – Requirements and Certification”. 2.Construction of below-grade parking garages in mixed-use and non-residential structures in local flood and regional flood areas is permitted, provided the structure (including the parking garage) is flood proofed to two feet above the applicable 1-percent-annual-chance flood elevation in accordance with the following design standards: a.Together with associated utility and sanitary facilities, the structure must be designed so that below two feet above the 1-percent-annual-chance flood elevation the structure is watertight with walls substantially impermeable to the passage of water and with structural components having the capability of resisting hydrostatic and hydrodynamic loads and effects of buoyancy. b.A Floodproofing Certificate and Inspection and Maintenance Plan must be provided by a registered professional engineer or architect. c.A floodproofing design that entails human intervention, such as the installation of flood gates or flood shields, will require a Flood Emergency Operation Plan. 3.1.2.3 Stormwater Management Design Standards The City adopts the following design standards for all new stormwater management systems (i.e., basins, storm sewers, etc.): 1.All ponding basins, temporary storage areas, and basin outlet pipes should be designed to collectively detain and convey the flows from the critical 1-percent-annual-chance storm (1- percent-annual-chance level of protection). The critical storm represents a storm of a given runoff duration that produces the greatest discharge or detention storage volume, as appropriate. Ponding basins should be designed to contain the flows from the 1-percent-annual-chance storm without overtopping. 2.All lateral storm sewer systems, including catch basin grates, should be designed to convey flows from the 10-percent- annual-chance storm (10-year level of service). 3.Where practical and physically possible, regional ponding basins and temporary storage areas, as opposed to individual onsite ponding basins and temporary storage areas, are preferred to reduce flooding, to control discharge rates, and to provide necessary storage volumes. The City has begun development of an inventory of public and private stormwater management facilities which can be found online via the City’s interactive water resources map: https://www.barr.com/maps/edi na/index.html#/ City of Edina 2018 Comprehensive Water Resources Management Plan 3-8 4. Stormwater retention (volume control) is required by both the Nine Mile Creek Watershed District and Minnehaha Creek Watershed District. Applicable design criteria are available from each respective watershed district. 5. All new constructed slopes within the 1-percent-annual-chance storage volume of a stormwater management system should be designed in accordance with current design standards. 6. All ponding basins and temporary storage areas should have a protected and stable emergency overflow conveyance or structure to prevent undesired flooding resulting from extreme storms or plugged outlet conditions. The emergency overflow conveyance should be protected with permanent, non-degrading erosion control materials (i.e., riprap or geosynthetics), where feasible. 7. Each ponding basin and temporary storage area should have an access for maintenance purposes. 3.2 Floodplain Management The floodplain of a stream can be defined as that area adjacent to a stream which is inundated during times of flood. More specifically, the Minnesota Floodplain Management Act of 1969 defines the floodplain as that area adjoining a watercourse which is subject to inundation by a flood of 1-percent- annual chance. Under the provisions of this act, local governmental units are required to adopt floodplain management ordinances which will include “the delineation of floodplains and floodways, the preservation of the capacity of the floodplain to carry and discharge regional floods, minimization of flood hazards, and the regulation of the use of land in the floodplain.” Under the provisions of the required ordinances, no major alteration to existing structures, no new fill and no floodplain use which would unreasonably constrict flood flows will be allowed in the floodplain unless further provisions are made to fully compensate any detrimental effects. The following policies regarding floodplain regulation with the City of Edina have been adopted: 1. The City will work to maintain no net loss of floodplain storage and will manage local and regional floodplains to maintain critical 100-year flood storage volumes. 2. The City will reduce the risk and consequence of flooding through the enforcement of engineering standards and the Floodplain Districts Overlay ordinance. a. The City defines the regional flood as the 1-percent-annual-chance floodplain as shown in FEMA’s Flood Insurance Rate Maps and Flood Insurance Study, consistent with Edina City Code floodplain districts overlay ordinance Chapter 36, Article X. b. The City defines local flooding as flood-prone areas that are outside of the regional flood area, and applies to all land within the City of Edina. Note: A description of the model inputs for regional and local flood elevations is provided in Section 4.0. City of Edina 2018 Comprehensive Water Resources Management Plan 3-9 3. The floodplain of Nine Mile Creek is defined as that area lying below the 100-year NMCWD Management Elevations as identified in the Nine Mile Creek Water Management Plan, October 2017, available on their website at www.ninemilecreek.org. The floodplain of Minnehaha Creek is defined as that area lying below the 1-percent-annual-chance flood elevations as shown in the Federal Emergency Management Agency (FEMA) Flood Insurance Study for Hennepin County, Minnesota All Jurisdictions, November 2016. 4. The floodplain requirements of the Nine Mile Creek Watershed District and the Minnehaha Creek Watershed District are applicable. 5. The City will communicate local and regional flood risk to stakeholders. 6. The City recognizes that addressing regional and local flood issues throughout the community will require multiple strategies and many actions implemented over a generational time frame. The City will employ the strategies and associated actions summarized in Table 3.2 for addressing flood issues. City of Edina 2018 Comprehensive Water Resources Management Plan 3-10 Table 3.2 Strategies and Potential Actions for Addressing Local and Regional Flood Issues Strategies Potential Actions Modify the flood Plan, preserve and reclaim flood storage (new public and private stormwater plans, deeds, easements, open space) Maintain and increase green space Maintain and increase storage (ponds, underground chambers, streets, depressions) Protect flow paths and emergency overflows Manipulate timing of peak flow Divert water Control rate of peak flow Detain and slowly release flow Reuse water for beneficial purposes Employ Green Infrastructure (GI) and Low Impact Development (LID) standards Modify susceptibility Elevate structures Reduce impacts Floodproof structures Enforce substantial improvement limits Elevate utilities Encourage flood insurance Encourage preparedness planning Encourage resilient landscaping Provide risk audits Limit infiltration and inflow to the sanitary system Maintaining existing floodplain infrastructure 3.3 Water Quality The streams, ponds, lakes, and wetlands in the City of Edina are an important community asset. These resources supply aesthetic and recreational benefits, in addition to providing wildlife habitat and refuge. The City recognizes the need to assure adequate water quality in the water bodies within the city and will take steps to protect and improve these resources. The City of Edina will manage the City’s water resources so that the beneficial uses of lakes, streams, ponds, and wetlands remain available to the community. Such beneficial uses may include aesthetic appreciation, wildlife habitat protection, nature observation, and recreational activities. 3.3.1 Water Quality Background Within the City of Edina, there are over two hundred water bodies, ranging in size from lakes to small stormwater detention basins. Historically, as the city developed, these lakes and ponds have been used for stormwater runoff detention in association with flood protection efforts. Unfortunately, the urbanization City of Edina 2018 Comprehensive Water Resources Management Plan 3-11 of a watershed often accelerates the degradation of water bodies through a natural process known as eutrophication. Nonpoint pollution associated with stormwater runoff creates adverse impacts; the degree of impact dependent upon the water body’s natural ability to remove, absorb, or process the pollutants through chemical, physical, or biological processes. Poor water quality usually indicates a situation where the resource receives more nutrients, or other pollutants, than can be processed naturally. Urban stormwater runoff carries a variety of pollutants that affect water quality. These contaminants are generated through the activities in different residential, commercial, and industrial land developments within a watershed. During storm or snowmelt events, these pollutants quickly wash off and are carried to downstream waters. As development increases and activities change and intensify, the concentrations and types of contaminants increase accordingly. Phosphorus and suspended sediments are recognized as being particularly detrimental to the health of lakes and streams in Minnesota. As a result, the City’s watershed management and land development policies are directed mainly at controlling the amount of phosphorus and sediment that reaches the water bodies within the city. Many other pollutants are transported by the same processes that convey phosphorus. Therefore, phosphorus reduction measures for stormwater runoff may also reduce the flow of other pollutants to water resources within the city. Suspended sediment in runoff is a major source of phosphorus because dissolved phosphorus frequently adsorbs to small particles in the suspended sediment. Because much of the phosphorus reaching water bodies from runoff is transported with the suspended sediment load, efforts to control sediment also help to reduce phosphorus loading. Suspended sediment carried by stormwater runoff typically consists of fine particles of soil, dust, dirt, organic material, and undissolved fertilizer. Suspended sediment loads can also carry heavy metals, oils, and other pollutants. High volumes of suspended sediment reaching water bodies can be the result of: • Runoff from city streets, buildings, parking lots, and other impervious areas, which washes accumulated sediment from those areas. • Runoff from urban areas with higher flows and higher velocities, which in turn causes channel and swale erosion. • Runoff from construction sites with poor erosion and sediment control or with poorly maintained sediment control facilities. Chloride is another pollutant in stormwater runoff that can be detrimental to the health of lakes and streams in Minnesota. Chloride is a salt found in most waters; however, elevated levels of chloride in surface water can harm aquatic organisms. High chloride levels in lakes and streams usually occur in relation to winter snowmelt due to the wide-spread application of road salt during winter-weather conditions. Nine Mile Creek and Minnehaha Creek have both been identified by the Minnesota Pollution Control Agency (MPCA) as impaired due to excessive chloride levels (see Section 2.2.6 for more details). City of Edina 2018 Comprehensive Water Resources Management Plan 3-12 Stormwater can also convey harmful bacteria, often called pathogens, into local lakes and streams. Ingestion of pathogens by humans can lead to gastrointestinal illnesses such as severe diarrhea or nausea, as well as headaches and fatigue. Two bacterial groups often used as “indicator organisms” for detection of pathogenic organisms are fecal coliform and E. coli bacteria. Fecal coliform and E. coli bacteria found in lakes and streams can originate from human, pet, livestock, or wildlife waste. Minnehaha Creek has been identified by the MPCA as impaired due to excess levels of bacteria (see Section 2.2.6 for more details). Lakes and streams are often monitored for the presence of specific pollutants, such as phosphorus, suspended sediment, or dissolved oxygen, to assess the quality of the waterbody. Another means to assess the health of a waterbody is through biological monitoring, which tracks the health of plant, insect, small organism, and fish communities. Several measures of a biological community related to the diversity and types of species present are assessed to develop an Index of Biological Integrity (IBI). For fish, for example, these measures may include feeding, reproduction, tolerance to human disturbance, abundance, and condition. An IBI score can then be used to assess the health and integrity of the waterbody. Nine Mile Creek and Minnehaha Creek have both been identified by the Minnesota Pollution Control Agency (MPCA) as biologically impaired (see Section 2.2.6 for more details). Algae (phytoplankton) are small aquatic plants that derive energy from sunlight and dissolved nutrients found in lake water. While algae are generally considered beneficial for lakes in that they form the base of a lake’s food web, over-abundance of algae can hinder lake health and cause poor water clarity. Typical algal blooms are comprised of green algae, which although can be a nuisance, are generally not harmful. Blue-green algal blooms, on the other hand, can be harmful. Blue-green algae, often described as looking like pea soup or spilled green paint, are not actually algae but types of bacteria called cyanobacteria. These bacteria can produce algal toxins that can pose a health threat for pets and people when concentrations become high enough. Blue green algae thrive in warm, shallow, nutrient-rich lakes. 3.3.2 Water Quality Management Policies The City adopts the following general water quality management policies: 1. The City will review, permit, and enforce standards for construction activities to prevent pollution and make progress toward water quality goals. 2. The City will work to heighten community awareness of water quality management through education and training to reduce pollution sources including, but not limited to, chloride. 3. The City will engage the community in decision-making and encourage active participation in solving water resources problems. 4. The City will manage its water resources so that the beneficial uses of streams, wetlands, ponds, and lakes remain available to the community. City of Edina 2018 Comprehensive Water Resources Management Plan 3-13 5. The City will conduct targeted street sweeping and encourage other forms of upstream pollutant reduction in areas closer to the source of such pollutants. 6. The City will encourage use of regional detention areas as opposed to individual on-site detention to reduce flooding, control discharge rates, and provide for water quality management. 7. As required by the Nine Mile Creek Watershed District and Minnehaha Creek Watershed Districts, stormwater retention is required. The rules of the Nine Mile Creek Watershed District and Minnehaha Creek Watershed District are adopted by reference and can be found on the appropriate watershed district website. 8. As required by the Nine Mile Creek Watershed District, stormwater runoff must be treated to achieve at least 60 percent annual removal efficiency for phosphorus and at least 90 percent annual removal efficiency for total suspended solids. 9. The City will implement stormwater management requirements for single and double dwelling units as described in City Code, chapter 10 and for site plans associated with commercial, multifamily, and multiuse as described in City Code, chapter 36. 10. The City will work with the MPCA, Nine Mile Creek Watershed District, and Minnehaha Creek Watershed District to implement the recommendations and/or requirements of existing or future WRAPS and TMDL(s) throughout the city. 11. The City will work with Nine Mile Creek Watershed District, Minnehaha Creek Watershed District, and lake associations to study the health of waterbodies and plan activities for protecting and improving waterbodies. 12. The City will target improvements to address pollutant loading from watershed sources, and partner with watershed districts and lake associations to address internal phosphorus loads. 13. The City will promote and protect a diverse, native population of aquatic vegetation that contributes to a balanced ecosystem through partnerships with watershed districts and lake associations. 14. The City will conduct management of invasive aquatic species where the management strategy has a measurable clean water benefit. 15. The City will encourage the use of low-impact site design for development and redevelopment within the city. 16. The City will, where feasible, apply low-impact site design principles for City-sponsored improvement projects. City of Edina 2018 Comprehensive Water Resources Management Plan 3-14 3.3.2.1 Water Quality Management Standards Stormwater Retention/Detention System Standards Stormwater retention/detention facilities must be designed according to the most current technology as reflected in the Minnesota Stormwater Manual (MPCA, 2005) or the applicable Nine Mile Creek Watershed District or Minnehaha Creek Watershed District rules, whichever applies to the site. Construction Site Standards The requirements of the National Pollutant Discharge Elimination System (NPDES) Municipal Separate Storm Sewer Systems (MS4) General Permit and the City’s Stormwater Pollution Prevention Program (SWPPP) are applicable (see Section 15.2.2 for more details). 3.4 Erosion and Sediment Control The City’s goals regarding erosion and sediment control are to protect the capacity of the City’s stormwater management system, prevent flooding, maintain water quality by preventing erosion and sedimentation from occurring, and correct existing erosion and sedimentation problems. 3.4.1 Erosion and Sediment Control Policies The following policies are adopted by the City of Edina: 1. The City requires erosion and sediment controls and submittal of erosion and sediment control plans for proposed construction activities. 2. Erosion and sediment controls shall conform to the requirements of the Nine Mile Creek Watershed District or Minnehaha Creek Watershed District, depending on project location. 3. The City will direct that entities proposing construction projects that disturb more than 1 acre of land will need to apply for coverage under the MPCA’s General NPDES Construction Stormwater Permit. 3.5 Wetlands The City of Edina’s goal is to achieve no net loss of wetlands, including acreage, functions, and values. Due to the developed nature of the city, all of the wetlands within the city are used for clean water and flood protection purposes. Where practical, opportunities to improve the functions, values, biological diversity, and acreage of existing wetlands should be sought. 3.5.1 Wetlands Policies The City adopts the following policies relating to wetlands within the city: 1. The City discourages wetland alteration. Unavoidable wetland alterations must be mitigated in conformance with the Wetland Conservation Act (WCA) requirements and the requirements of the Nine Mile Creek Watershed District or Minnehaha Creek Watershed District, and must be City of Edina 2018 Comprehensive Water Resources Management Plan 3-15 guided by the following principles, in descending order: avoid the impact, minimize the impact, rectify the impact, reduce or eliminate the impact over time, and compensate for the impact. 2. The Nine Mile Creek Watershed District and the Minnehaha Creek Watershed District are the local government units (LGU) responsible for administering the Wetland Conservation Act in the City of Edina. The City will work in conjunction with the Nine Mile Creek Watershed District and the Minnehaha Creek Watershed District on issues pertaining to wetland alterations within the city boundary. 3. The City will support watershed districts and other agencies in their efforts to maintain and periodically update the wetland inventory data and the wetland management classifications provided in this plan. 4. The City will partner with watershed districts to restore previously existing wetlands and enhance existing wetlands. 5. The City will involve the appropriate regulatory agencies (MPCA, U.S. Army Corps of Engineers, and the MnDNR) in the planning of any proposed water quality or flood control facilities identified in this plan that may be located within a wetland. 6. The City will provide buffer zones of native vegetation, where feasible, around ponds and wetlands to provide habitat. The City will work with the Nine Mile Creek Watershed District and Minnehaha Creek Watershed District to educate the public regarding wetland protection and the importance of creating and maintaining vegetative buffers. Land use and property ownership may limit the ability to provide buffer zones. 7. The City encourages the minimization of water level fluctuations (bounce), where feasible, in wetlands or detention basins to prevent adverse habitat changes. 3.6 Natural Resources The City’s goals are to protect and enhance fish and wildlife habitat, soils and native landscapes. To accomplish this objective, the City adopts the following policies: 1. Cooperate with other units of government to complete habitat and recreation corridor connections (trails and greenways). 2. Maintain, enhance, or provide new habitat as part of wetland modification, stormwater facility construction, Parks redevelopment, or other appropriate projects. 3. Encourage alternative landscape designs that increase beneficial habitat, wildlife and clean water ; promote infiltration and vegetative water use, decrease detrimental wildlife uses (such as beaver dams, goose overabundance), protect water control facilities, stabilize soils with deep roots near City of Edina 2018 Comprehensive Water Resources Management Plan 3-16 the shoreline, stabilize soils for water quality or recreational opportunity ,and minimize irrigation demand and chemical control. 3.7 Groundwater The City’s goal is to protect the quality and quantity of groundwater resources. The City adopts the following groundwater policies: 1. The City will encourage groundwater recharge and protect recharge areas from potential sources of contamination. The City will provide increased greenspace, native vegetation, and pond “dead” storage wherever possible and appropriate to allow for the infiltration of stormwater runoff and promote groundwater recharge. 2. The City will encourage use of grassed waterways to maximize infiltration where not detrimental to groundwater supplies. 3. The City will implement groundwater quality and quantity protection measures outlined in the City’s Wellhead Protection Plan, Part II (2013). 4. The City will address unused unsealed private wells through the permitting process. 5. The City will review and adopt as necessary a water sustainability ordinance that is protective of groundwater quality and quantity. 6. The City will investigate, and implement where feasible, water reuse projects. 7. The City will promote awareness of groundwater resource issues through public education and information programs. 3.8 Education Program The City of Edina believes public education is an important and effective method to control non-point source pollution since it emanates from broad reaches of the landscape. A public education program raises citizen awareness regarding pollutant sources in everyday life from all types of property. The City will educate its residents, businesses, industries and staff concerning pollutant reduction, best management practices, the link between daily housekeeping activities and the condition of the City of Edina’s water resources, and awareness of natural resources in general. The City will also seek to inform its residents, businesses, industries and staff of initiatives, projects, etc. completed by the community that address the City’s education goals. City of Edina 2018 Comprehensive Water Resources Management Plan 3-17 Education and housekeeping practices are especially important in urban settings since there is limited land available to provide water quality treatment facilities. The City of Edina will develop and distribute educational materials to the general public and targeted groups regarding: • Natural resources within and adjacent to the city • Importance of pollutant reduction in stormwater runoff • City ordinances, policies and programs pertaining to water resources • Reducing fertilizer/herbicide use • Reducing chloride use for snow and ice management • Lawn care practices that prevent organic debris from reaching storm sewer systems • Household and automobile hazardous waste disposal • Problems with pet waste and proper disposal • Litter control • Recycling and trash disposal • Composting, leaf collection, and grass clippings • Residential stormwater drainage • Native vegetation • Public area maintenance • Alternative landscaping methods • Plantings in buffer zones along wetlands, lakes, and streams • Car washing • Reporting illicit discharges • Water conservation • Sealing unused private wells Information will be distributed via the City’s newsletter, the City Extra email notification service, local newspapers, cable television, social media, workshops, and any other appropriate media. 3.9 NPDES Considerations Under the federal 1987 Clean Water Act revision, discharges of pollutants into waters of the United States are prohibited without a permit under the National Pollutant Discharge Elimination System (NPDES) program. Traditionally, this program concentrated on discharges from industries and publicly owned treatment plants. In 1990, the EPA promulgated rules establishing Phase I of the NPDES Stormwater Program in an effort to reduce the water quality impact of stormwater drainage systems on receiving City of Edina 2018 Comprehensive Water Resources Management Plan 3-18 water bodies. Phase I of the program regulates stormwater runoff from municipal separate storm sewer systems (MS4s) generally serving populations of 100,000 or greater, construction activities disturbing five acres of land or greater, and various industrial activities. In 1999, the Phase II Rule of the NPDES Stormwater Program extended the coverage of the NPDES program to operation of “small” MS4s in urbanized areas and operation of small construction sites. Through the use of NPDES permits, these operations are required to implement programs and practices to control polluted stormwater runoff. Because the City of Edina is located in an “urbanized area”, as defined by the Bureau of the Census, it is covered under the Phase II NPDES Stormwater Program. Operators of Phase II small MS4s in Minnesota were required to apply for coverage under the Small Municipal Separate Storm Sewer Systems (MS4s) General Permit by March 10, 2003. Under this permit, MS4s are required to develop and implement a Storm Water Pollution Prevention Program (SWPPP), which must contain the following six control measures, at a minimum: 1. Public education and outreach on stormwater impacts. 2. Public involvement and public participation. 3. Illicit discharge detection and elimination. 4. Construction site stormwater runoff control. 5. Post-construction stormwater runoff control in new development and redevelopment. 6. Pollution prevention and good housekeeping for municipal operations. The SWPPP must include Best Management Practices (BMPs) and measurable goals for each of the six control measures. An annual report detailing the implementation of the control measures for the previous calendar year must be submitted to the MPCA by June 30 of each year. Water resource management activities undertaken by the City of Edina through the implementation of this plan exceed the minimum standards required by the MS4 general permit. Additional information on how the City’s activities align with the NPDES Phase II MS4 General Permit and SWPPP is provided in Section 15.2.2. A stormwater conveyance map that meets the standards of the MS4 permit can be found online via the City’s interactive water resources map. Additional metadata associated with the stormwater conveyance system is available from the City upon request. A map showing an inventory of facilities and operations is provided in the City’s SWPPP. City of Edina 2018 Comprehensive Water Resources Management Plan 4-1 4.0 Methodology for Modeling 4.1 Methodology for Hydrologic/Hydraulic Modeling The U.S. EPA’s Stormwater Management Model (SWMM), with a computerized graphical interface provided by XP Software (XP-SWMM), was chosen as the computer modeling package for this study. XP-SWMM uses rainfall and watershed characteristics to generate local runoff, which is routed through pipe and overland flow networks. The model can account for detention in ponding areas, backflow in pipes, surcharging of manholes, as well as tailwater conditions that may exist and affect upstream storage or pipe flows. The 5000 node version of XP-SWMM 2014, was used to model the storm sewer, ponding and overland flow systems within the City of Edina. The City storm sewer system was split into two XP- SWMM models: one model that reflects the parts of Edina that drain to Minnehaha Creek and one that reflects the parts of Edina that drain to Nine Mile Creek, with overflow connections between the two where necessary. 4.1.1 Hydrologic Modeling Three major types of information are required by XP-SWMM for hydrologic modeling: (1) watershed data, (2) rainfall data, and (3) infiltration data. This data is used by XP-SWMM to generate inflow hydrographs at various points into the storm sewer, ponding, and overland flow networks. The following sections describe each of these data. 4.1.1.1 Watershed Data The amount of runoff from a watershed depends on numerous factors, including the total watershed area, the soil types within the watershed, the percent of impervious area, the runoff path through the watershed, and the slope of the land within the watershed. ESRI’s ArcMap geographic information systems (GIS) software was used extensively in assessing the above mentioned characteristics of each watershed within the City. The software also allowed mapping of the drainage network for the area. Watershed Area The watershed delineation was based on watersheds delineated for the 2003 CWRMP that were then modified using newer data including the MnDNR LiDAR elevation data collected in 2011, the updated City storm sewer GIS data (provided by the City in 2016), and newer aerial imagery. In certain cases, the watershed divides were field verified. A total of 1,474 separate watersheds were delineated for this CWRMP update. Land Use Data The percent of impervious area within each watershed was estimated using land use data provided by the City of Edina (Figure 2.2). An electronic land use coverage was provided by the City for the 2003/2011 CWRMPs. For areas outside of the Edina City limits that were included in the model, such as small portions of Eden Prairie, Bloomington, Hopkins, St. Louis Park, Minneapolis, and Richfield, land use data based on City of Edina 2018 Comprehensive Water Resources Management Plan 4-2 the 2010 Metropolitan Council aerial photographs was used. Land use within the study area was divided into the designations shown in Table 4.1. The land use information provided by the City categorized residential land use as single-family residential or multiple-family residential. For modeling purposes, these residential categories were further broken down based on the density of housing units within the area. The City’s electronic land use coverage and aerial imagery was used in ArcMap to determine the density of the residential areas. The single-family residential areas were further categorized as very low density residential (<1 unit/acre) or low density residential (1-4 units/acre). The areas categorized as multiple-family residential by the City were broken down into the following categories: low density residential (1-4 units/acre), medium density residential (4-8 units/acre), and high density residential (>8 units/acre). The land use type “Other” is new to the analysis for this CWRMP update. The “Other” land use type essentially reflects railroad corridors and is about 20% impervious. The land use categories were used to estimate the total and “directly-connected” impervious fractions for each subwatershed within the study area. The total impervious fraction of a watershed represents the portion of the watershed that is covered by an impervious surface. The “directly-connected” impervious fraction represents the impervious surfaces that are hydraulically connected to a stormwater conveyance system. For example, if a rooftop drains onto an adjacent pervious area such as a yard, it is not a “directly- connected” impervious area. However, if a rooftop drains onto a driveway, which drains to the street and then to a stormwater catch basin, the rooftop would be a “directly-connected” impervious area. A separate study estimating the total impervious fraction and the “directly-connected” impervious fraction for each land use type was completed in October 2016 (City of Edina Imperviousness Assumptions for Stormwater Modeling, Barr Engineering, 2016; also attached in Appendix A) using the land use layer from the City, and a 2011 gridded impervious layer of the City from the University of Minnesota. Resulting imperviousness for each land use type throughout the City are listed in Table 4.1. The “directly- connected” imperviousness for each watershed was calculated as an area-weighted average of the different land use types existing within the watershed. City of Edina 2018 Comprehensive Water Resources Management Plan 4-3 Table 4.1 Land Use Impervious Fraction Assumptions for Hydrologic Modeling Land Use Designation Total Impervious % Directly-Connected Impervious % Commercial 85% 80% Developed Park 30% 20% Golf Course 5% 2% High Density Residential 65% 50% Highway 65% 65% Industrial/Office 75% 75% Institutional 60% 30% Institutional - High Imperviousness 80% 70% Low Density Residential 40% 25% Medium Density Residential 50% 40% Natural/Park/Open 2% 0% Open Water 100% 100% Other 20% 20% Very Low Density Residential 25% 15% Wetland 100% 100% Watershed Width and Slope The SWMM Runoff Non-linear Reservoir Method was used as the hydrograph generation technique for this project. This method computes outflow as the product of velocity, depth and a watershed width factor. The watershed “width” in XP-SWMM is defined as twice the length of the main drainage channel, with adjustments made for watersheds that are skewed (i.e., the areas on both sides of the main drainage channel are not equal). This factor is a key parameter in determining the shape of the hydrograph for each watershed and is often used as a calibration parameter. To determine the width parameter, the main drainage channel for each watershed was digitized in ArcMap and a customized ArcMap script was used to calculate the width based on the skew of the drainage path within the subwatershed. For this CWRMP update, the widths of unchanged or slightly modified watersheds were left the same. Only in watersheds where the boundary was significantly modified or the watershed was subdivided were the widths recalculated using the method described above. The average slope (feet/feet) for each watershed was calculated in ArcMap using the electronic gridded topographic LiDAR data. The slope was then determined for each grid cell by calculating the steepest slope in any direction. The average of all of the gridded slope values within each watershed was then used as the representative slope of the watershed. City of Edina 2018 Comprehensive Water Resources Management Plan 4-4 4.1.1.2 Rainfall Data Storm events for several return periods were analyzed in this study: the 1-percent-annual-chance 24-hour storm, the 10-percent-annual-chance ½ hour storm, and the 1-percent-annual-chance 10-day snowmelt event. For the 1-percent-annual-chance return period, a nested distribution was applied to a total rainfall depth of 7.47 inches, based on the National Oceanic and Atmospheric Administration’s Atlas 14 Volume 8 precipitation frequency curves. A nested distribution was selected to be consistent with the XP-SWMM models of Nine Mile Creek and Minnehaha Creek which are incorporated in the City’s model as tailwater conditions. For the snowmelt event, a longer 10-day distribution that has historically been used was applied to a total of 7.2 inches with no losses (generating 7.2 inches of runoff). A precipitation depth of 1.65 inches was used for the 10-percent-annual-chance ½ hour storm, 4.1.1.3 Infiltration Data Soils Soils data for the City of Edina was obtained through two sources: the 2012 Natural Resources Conservation Service Soil Survey Geographic (SSURGO) Database and the soils layer used for the modeling effort associated with the 2003 CWRMP. The hydrologic soil group (HSG) designation classifies soils into groups (A, B, C, and D) based on the infiltration capacity of the soil (well drained, sandy soils are classified as “A” soils; poorly drained, clayey soils are classified as “D” soils). When a HSG designation was not included in the new SSURGO soils database, the 2003 CWRMP HSGs were used. For the 2003 modeling effort, when a HSG designation was not included in the soils database, the soil description was used to estimate the HSG. If a soil description was unavailable, the most dominant soil group in the vicinity was assumed. Although all soil types are represented in the City (Figure 2.2), the predominant soil type in the City is Type B (sandy loam). Horton Infiltration Infiltration was simulated in the XP-SWMM models using the Horton Infiltration equation. This equation is used to represent the exponential decay of infiltration capacity of the soil that occurs during heavy storm events. The soil infiltration capacity is a function of the following variables: Fc (minimum or ultimate value of infiltration capacity), Fo (maximum or initial value of infiltration capacity), k (decay coefficient), and time. The actual values of Fc, Fo, and k are dependent upon soil, vegetation, and initial moisture conditions prior to a rainfall event. Because it was not feasible to obtain this detailed information for each subwatershed through field samples, it was necessary to make assumptions based on the various soil types throughout the City. Table 4.2 summarizes the Horton infiltration values used for each Hydrologic Soil Group to calculate composite infiltration parameters for each subwatershed. The values shown in the table are based on suggested values in the Stormwater Management Model, Version 4: User’s Manual, U.S. EPA, 1988. Composite Fc and Fo values were calculated for each subwatershed based on the fraction of each soil type within the subwatershed. Global databases containing the infiltration parameters for each subwatershed were developed and imported into the XP-SWMM models. City of Edina 2018 Comprehensive Water Resources Management Plan 4-5 Table 4.2 Horton Infiltration Parameters Hydrologic Soil Group Fo (in/hr) Fc (in/hr) k (1/sec) A 5 0.38 0.00115 B 3 0.23 0.00115 C 2 0.1 0.00115 D 1 0.03 0.00115 4.1.1.4 Depression Storage Data Depression storage represents the volume (in inches) that must be filled with rainfall prior to the occurrence of runoff in XP-SWMM. It characterizes the loss or "initial abstraction" caused by such phenomena as surface ponding, surface wetting, interception and evaporation. Separate depression storage input values are required in XP-SWMM for pervious and impervious areas. The depression storage assumptions used for the models were based on the values used in the XP-SWMM model developed for the Nine Mile Creek Watershed District Bloomington Use Attainability Analysis, Barr Engineering, 2001. For this model, the depression storage was estimated by plotting total precipitation for several measured rainfall events at a Bloomington continuous recording precipitation gage versus runoff from several Bloomington monitoring sites. A regression of the data yielded a y- intercept that was assumed to be the depression storage (in inches). Based on this analysis, the assumed impervious depression storage was 0.06 inches and the pervious depression storage was 0.17 inches. XP-SWMM also uses a “Zero Detention Storage” parameter to account for areas that generate immediate runoff (i.e., water surface areas). This parameter was estimated for each subwatershed by dividing the water surface area by the directly connected impervious surface area. 4.1.1.5 Overland Flow Roughness The SWMM Runoff Non-linear Reservoir Method requires an estimate of the roughness of both pervious and impervious areas in the watershed. These values were calibrated in the Nine Mile Creek Watershed District Bloomington Use Attainability Analysis (Barr Engineering, 2001) and were used in previous CWRMPs as well as this CWRMP. The values for impervious area and for pervious area are 0.200 and 0.355, respectively. 4.1.2 Hydraulic Modeling 4.1.2.1 Storm Sewer Network Data detailing the storm sewer network within the City of Edina was provided by the City. An electronic GIS feature dataset provided detailed information on the storm sewer system, including the type of pipe (material of construction), invert elevations, pipe sizes, pipe lengths, and manhole rim elevations. Where this data was incomplete, additional information was obtained from other sources such as construction plans, field surveys, or previous modeling efforts. All elevations entered into the model reflect the National Geodetic Vertical Datum of 1929 (NGVD29). City of Edina 2018 Comprehensive Water Resources Management Plan 4-6 Assumptions A variety of pipe types are used throughout the City. The assumptions used for the roughness coefficient (Manning’s “n”) for each pipe type are listed in Table 4.3. Table 4.3 Roughness Coefficient Assumptions Pipe Type Abbreviation Assumed Roughness Coefficient Corrugated Metal Pipe CMP 0.024 Clay - 0.015 Steel - 0.015 Ductile Iron Pipe DIP 0.014 Reinforced-Concrete Pipe RCP 0.013 Poly Vinyl Chloride PVC 0.01 High Density Polyethylene HDPE 0.008 Outlets from ponding areas that may be inlet controlled were modeled in XP-SWMM assuming a groove end projecting concrete pipe inlet condition. This allowed XP-SWMM to determine the controlling flow condition in the outlet pipe (i.e., is the flow in the pipe controlled by the inlet size, barrel capacity, or tailwater conditions) and accurately estimate the pond’s water surface elevation. Surface inundation, or flooding, occurs when the runoff from the watershed exceeds the capacity of the storm sewer system to convey the stormwater downstream. Capacity of the storm sewer system can be limited by either the capacity of the storm sewer pipes or the inlet capacity (i.e., flow through catch basins and other minor roadway inlets into storm sewer pipes). For most of the city, the XP-SWMM model does not include inlet capacity, due to the high-level of detail required. Therefore, model results reflect the capacity of the storm sewer system and may not fully characterize the existing flood risk where inlet capacity is restrictive. Inlet capacity was modeled for certain areas of the city were additional detailed analysis was performed. Tables *.3 in Sections 5.0 through 14.0 identify where inlet capacity was modeled. 4.1.2.2 Tailwater Effects For the portion of the City that drains to Nine Mile Creek, the City XP-SWMM model incorporated the relevant portions of the Nine Mile Creek XP-SWMM model to more accurately account for tailwater impacts from the creek. For the portion of the City that drains to Minnehaha Creek, the City XP-SWMM model uses the tailwater elevations (stage hydrographs) along the creek system as boundary conditions for each corresponding storm event (i.e., the Minnehaha Creek model provided by Wenck Associates is not integrated into the City model, but the creek model is used to establish boundary conditions). A more detailed description of City of Edina 2018 Comprehensive Water Resources Management Plan 4-7 the Nine Mile Creek and Minnehaha Creek model development, as well as a description of how the tailwater conditions were incorporated into the City of Edina models is provided in Appendix B. 4.1.2.3 Overland Flow Network Overland flow networks were entered into the XP-SWMM models because preliminary modeling results indicated that water was being routed out of the systems and lost (i.e., manholes and ponding areas would surcharge and the model assumed the water disappeared once it exceeded the respective spill crest elevation). An iterative process was used by adding storage and overland flow network data until all of the stormwater had been accounted for by XP-SWMM. Data for the overland flow network were primarily based on MnDNR 2011 LiDAR elevation data (ground surface), and in some cases, site visits or storm sewer data from the City. Storage was also added to XP-SWMM nodes based on the MnDNR 2011 LiDAR elevation. The storage curves were defined as depth-area tables, at depth increments of 0.2 feet. Initially, storage was added only to the XP-SWMM nodes representing ponds or backyard depression areas. After the initial model runs, storage was added to subwatersheds where ponding or surface inundation occurs (e.g., parking lots). Overland flow paths were added with the following characteristics: Overland flow along streets • Trapezoidal channels • Bottom width = 16 feet (approx. ½ street width), or 32 feet if the entire street is flowing • Side slopes = 1H:1V • Manning’s “n” for the surface flow channels was set equal to 0.014 for flow down paved streets • Channel depth = 1 foot Natural overland flow paths • Trapezoidal channels • Bottom width = variable based on topographic information. Typically an estimate of 10 feet was used. • Side slopes = variable based on topographic information. Typically 5H:1V was used. • Manning’s “n” = 0.035 where overland flow was clearly over vegetated areas or onto boulevards. • Channel depth = 1 foot or deeper where necessary. 4.1.3 Stormwater System Analysis Ten- and 1-percent-annual-chance frequency flood analyses were performed for all of the major drainage basins. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain. Tables *.2 present the watershed information and the results for the 10- and 1-percent-annual-chance frequency hydrologic analyses. City of Edina 2018 Comprehensive Water Resources Management Plan 4-8 The results of the 10- and 1-percent-annual-chance frequency hydraulic analyses for each of the major drainage basins is summarized in Tables *.3. The column headings in Tables *.3 are defined as follows: Subwatershed or Node—XP-SWMM node identification label—Each XP-SWMM node represents a manhole, catch basin, pond, or other junction within the stormwater system. Type of Storage—Defines the type of storage at storage node locations. Outlet Elevation—The control elevation of the outlet. Flood Elevation—The maximum water elevation reached in the given pond/manhole for each referenced event. Flood Bounce—The fluctuation of the water level within a given pond for each referenced event. Figures *.3 illustrate the results of the 10- and 1-percent-annual-chance frequency hydraulic analyses. Each figure depicts the drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. One objective of the hydraulic analyses was to evaluate the level of service provided by the current storm sewer system. The level of service was examined by determining the surcharge conditions of the manholes and catch basins within the storm sewer system during the 10- and 1-percent-annual-chance frequency storm events. An XP-SWMM node was considered surcharged if the hydraulic grade line at that node breached the ground surface (rim elevation). Surcharging is typically the result of limited downstream capacity and tailwater impacts. The XP-SWMM nodes depicted on Figures *.3 were color-coded based on the modeled surcharge conditions. The green nodes signify no surcharging occurred during the 10- or 1-percent-annual-chance storm events, the yellow nodes indicate surcharging during the 1-percent- annual-chance event, and the red nodes identify that surcharging is likely to occur during both the 10- and 1-percent-annual-chance frequency storm events. Figures *.3 illustrate that several XP-SWMM nodes within each major drainage basin are predicted to surcharge during both the 10- and 1-percent- annual-chance event. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. Another objective of the hydraulic analyses was to evaluate the level of protection offered by the current stormwater system. Level of protection is defined as the pipe and overland overflow capacity provided by a municipal drainage system to prevent property damage and assure a reasonable degree of public safety following a rainstorm. A 1-percent-annual-chance event is recommended as a standard for the design of stormwater management basins. To evaluate the level of protection of the stormwater system within each major drainage area, the 1-percent-annual-chance frequency flood elevations for the ponding basins and depressed areas were compared to the approximate low elevations of structures surrounding each basin. The approximate low elevations were determined using the 2011 MnDNR LiDAR elevation data in ArcMap. The LiDAR elevation may not be representative of the actual lowest elevation, therefore a field survey City of Edina 2018 Comprehensive Water Resources Management Plan 4-9 would need to be conducted to determine potential impacts. The inundation areas predicted to potentially impact structures during the 1-percent-annual-chance storm event are shown in Figures *.3. Discussion and recommended improvement considerations for these areas are included in Sections 5.0 through 14.0. 4.1.3.1 Problem Areas Selection Process The Atlas 14 XP-SWMM modeling analysis identified many locations throughout the city where the 1-percent-annual-chance flood elevations appears to impact roadways and/or structures. As part of this plan, some of these flood-prone areas were evaluated further (at varying levels of detail) to better understand the problem(s) and identify potential improvement options. The discussion below summarizes the approach taken to identify and categorize the most severe flood-prone areas throughout the city. The criteria summarized below were used to identify and categorize the most severe flood-prone areas throughout the city, based on the potential to impact City infrastructure, buildings, and/or homes. The inundation areas were given a score based on meeting some or all of the following criteria that are based on 1-percent-annual-chance flood event modeling results (except where otherwise noted): • 1 point for each potentially impacted residential home • 1 point for each potentially impacted apartment building • 1 point for each potentially impacted commercial building, as defined by a GIS structure layer provided by the City • 1 point for road flooding for roads identified as an evacuation route, as defined by an evacuation route GIS layer provided by the City • 1 point for each area where the depth of flooding over a road is greater than or equal to 2 feet, and the road is not an evacuation route, with evacuation routes defined by a GIS layer provided by the City • 1 point for each area where a public building (school, church, fire station, daycare) is potentially impacted with public buildings defined by a GIS layer provided by the City • 1 point for each area where the flooding problem is a regional problem (versus flooding in a backyard depression area with no outlet) • 2 points for each area where the flooding from the 10-percent-annual-chance precipitation event is similar to the 1-percent-annual-chance precipitation event, indicating higher probability of impacts • 2 to 14 points based on the duration of flooding during the 1-percent-annual-chance precipitation event. Areas where the lowest structure is potentially impacted for a short time (less than 1 hour) received 2 points, whereas areas where the lowest structure is potentially impacted for a long time (greater than 72 hours) received 14 points. • 3 points for any area that impacts a water facility (treatment, wells, towers, etc.), as identified by a GIS layer provided by the City City of Edina 2018 Comprehensive Water Resources Management Plan 4-10 The top 80 flood-prone areas were identified (“registered”) as most severe, based on the criteria presented above. In general, inundation areas that potentially impacted less than five residential homes with no other criterion did not register within the top approximately 80 identified flood-prone areas. The registered flood-prone areas were reviewed further; five areas were selected to be studied in detail and another 20 areas were selected for a screening-level review. The identification process was objective, data-driven, and was collaborative between City staff and Barr Engineering staff. The resulting 25 flood- prone areas that were identified for further study during this 2018 CWRMP update are discussed in Sections 5.0 through 14.0. Detailed study of the five areas consisted of evaluating the nature of the problem based on modeling results, and identifying and modeling potential improvement options to reduce flood risk, including combinations of the proposed improvement options. For the 20 flood-prone areas selected for a screening level analysis, a desktop review was conducted to assess the nature of the problem and identify potential improvement options (without additional modeling analysis). The remaining registered flood-prone areas that weren’t evaluated in detail or at a screening level are included for future evaluation. Inundation areas that didn’t register in the top 80 areas are not described further in the narrative of this plan; however, they are shown on inundation maps in Sections 5.0 through 14.0 4.2 Methodology for Water Quality Modeling Water quality modeling was not updated for the 2018 CWRMP. The following sections are based on the work completed for the 2003 CWRMP. As described in Section 15.2.3, the City will be developing a Clean Water strategy to target and prioritize pollutant reduction. P8 (Program for Predicting Polluting Particle Passage through Pits, Puddles and Ponds, IEP, Inc., 1990) is a computer model used for predicting the generation and transport of stormwater runoff pollutants in urban watersheds. The P8 model was used in this study to simulate the hydrology and phosphorus loads introduced from the watershed of each pond and the transport of phosphorus throughout the stormwater system. P8 is a useful diagnostic tool for evaluating and designing watershed improvements and BMPs. The model requires user input on watershed characteristics, pond attributes, local precipitation and temperature, and other parameters relating to water quality and pond removal performances. 4.2.1 Watershed Characteristics Examination of the watershed characteristics for each pond being modeled involved assessment of soil type, land use and residential density, and the impervious fraction of the land in the watershed. ArcMap software was used extensively in assessing the watershed characteristics. The software also allowed mapping of the drainage network for the area. In P8, pervious and impervious areas are modeled separately. Runoff volumes from pervious areas are computed using the Soil Conservation Service (SCS) Curve Number method. Runoff from impervious areas begins once the cumulative storm rainfall exceeds the specified depression storage, with the runoff rate equal to the rainfall intensity. City of Edina 2018 Comprehensive Water Resources Management Plan 4-11 4.2.1.1 Impervious Fraction Because P8 calculates runoff separately from pervious and impervious areas, it was necessary to determine the impervious fraction of each watershed. For the P8 model, the impervious fraction included only the directly-connected impervious area, the impervious surfaces that are “connected” directly to a stormwater conveyance system, where stormwater does not cross over pervious areas. The directly- connected impervious fraction was calculated for each watershed based on the land use(s) within the watershed and impervious fraction assumptions for each land use. The assumptions made for the total impervious fraction and directly-connected impervious fraction for each land use for the water quality modeling are listed in Table 4.4. Table 4.4 Land Use Impervious Fraction Assumptions for Water Quality Modeling Land Use Designation Total Impervious % Directly-Connected Impervious % Commercial 90% 80% Golf Course 5% 2% Highway 50% 50% Industrial/Office 90% 80% Institutional 40% 20% Institutional- High Imperviousness 70% 50% Natural/Park/Open 2% 0% Open Water 100% 0% Residential- Very Low Density 12% 8% Residential- Low Density 40% 20% Residential- Medium Density 55% 30% Residential- High Density 70% 40% Wetlands 0% 0% City of Edina 2018 Comprehensive Water Resources Management Plan 4-12 4.2.1.2 Pervious Curve Number Watershed runoff volumes from pervious areas are computed in P8 using the SCS Curve Number method. Thus, it was necessary to determine a pervious curve number for each watershed. The soil type(s) within each watershed were determined and a pervious curve number was selected for the watershed based on the soil type, land use, and hydrologic conditions (e.g., if watershed soils are Type B and pervious areas comprise grassed areas with >75 percent cover, then a curve number of 61 would be selected). The pervious curve number was then weighted with the indirect (i.e., unconnected) impervious area in each subwatershed as follows: ()()[]Area) (PerviousArea Impervious Indirect Number)] Curve (Pervious* Area) [(Pervious +(98)] * Area Impervious Indirect[ = CNwt + 4.2.1.3 Other P8 Watershed Input Parameters Outflow Device Number: The Device Number of the device receiving runoff from the watersheds was selected to match the pond or manhole node ID used for the hydrologic/hydraulic modeling. Swept/Not Swept: An “Unswept” assumption was made for the entire impervious watershed area. A Sweeping Frequency of 0 was selected. Selected parameters were placed in the “Unswept” column since a sweeping frequency of 0 was selected. Depression Storage = 0.03 (P8 default value) Impervious Runoff Coefficient = 0.94 (P8 default value) 4.2.2 Treatment Device Characteristics The treatment devices in P8 provide collection, storage, and/or treatment of watershed discharges. A variety of treatment devices can be modeled in P8, including detention ponds (wet or dry), infiltration basins, swales and buffers, aquifers, and pipe/manholes. For this study, nearly all ponds were modeled as detention basins. The user-defined characteristics of these ponds are described in the following sections. 4.2.2.1 Dead Storage Detailed information pertaining to the permanent pool storage volume (dead storage) was only available for a small number of the ponds that were modeled. Pond depth data for the ponds in the Mirror Lake watershed was available as a result of pond surveys being performed for the Draft Mirror Lake Use Attainability Analysis (Barr Engineering, 2004). Pond depth information for Indianhead Lake was available from the MnDNR. Where detailed information on pond depths was not available, it was necessary to make assumptions. The surface area of each pond was determined from the 2-foot topographic information provided by the City. Where detailed information was not available, pond depths were estimated based on the type of wetland, which was determined in the wetland inventory process. An average depth of City of Edina 2018 Comprehensive Water Resources Management Plan 4-13 4 feet was typically assumed for Type 5 wetlands; 2 feet for Type 3 and Type 4 wetlands; 0.5 feet for Type 1, 2, 6, and 7 wetlands. 4.2.2.2 Live Storage The flood pool storage volume (live storage) for each pond was calculated in ArcMap using the electronic topographic data provided by the City. The live storage represents the storage volume between the normal water elevation and the flood elevation. The overflow elevation from each pond was determined from the 2-foot topographic data. The live storage volume was then calculated in ArcMap based on the slope of the flood pool. 4.2.2.3 Other P8 Treatment Device Input Characteristics Infiltration Rate (in/hr): An infiltration rate was entered only for land-locked detention ponds. The rates applied were dependent upon the type of soil surrounding each pond. The infiltration rates used for each soil type are listed in Table 4.5. Table 4.5 Infiltration Assumptions for Water Quality Modeling Hydrologic Soil Group Infiltration Rate Assumption for Dead Storage Areas [in/hr] Infiltration Rate Assumption for Live Storage Areas [in/hr] A 0.02 0.06 B 0.015 0.05 C 0.015 0.02 D 0.005 0.01 • Orifice Diameter and Weir Length: The orifice diameter or weir length of the pond outlet was determined from storm sewer system data provided by the City of Edina. For landlocked basins, the overflow was represented as a weir, with the weir length estimated using ArcMap and available topographic information. • Particle Removal Scale Factor: 0.3 for ponds less than 2 feet deep and 1.0 for all ponds 3 feet deep or greater. For ponds with normal water depths between 2 and 3 feet, a particle removal factor of 0.6 was selected. These factors were selected based on development of a similar P8 model for the Round Lake Use Attainability Analysis (Barr Engineering, 1999). • Pipe/Manhole— Time of Concentration: The time of concentration for each pipe/manhole device was determined and entered here. Time of concentration was determined in accordance with Kirpich’s method (Schwab et al., 1993). City of Edina 2018 Comprehensive Water Resources Management Plan 4-14 4.2.3 Precipitation and Temperature Data The P8 model requires hourly precipitation and daily temperature data; long-term data can be used so that watersheds and BMPs can be evaluated for varying hydrologic conditions. Hourly precipitation data was obtained from the Minneapolis-St. Paul International Airport for October 1994 through September 1995 (1995 water year, which represents average yearly precipitation). Average daily temperature data was obtained from the National Weather Service site at the Minneapolis-St. Paul International Airport. 4.2.4 Selection of Other P8 Model Parameters 4.2.4.1 Time Step, Snowmelt, and Runoff Parameters • Time Steps per Hour (Integer) = varied. This parameter varied between each P8 model. Selection was based upon the number of time steps required to eliminate continuity errors greater than 2 percent. • Minimum Inter-Event Time (Hours) = 10. The selection of this parameter was based upon an evaluation of storm hydrographs from the summer of 1999 to determine which storms should be combined and which storms should be separated to accurately depict runoff from the lake’s watershed. Precipitation data from 1999 was used for the analysis due to the high frequency of storms during the summer, particularly during July. • Snowmelt Factors—Melt Coef (Inches/Day-Deg-F) = 0.03. The P8 model predicts snowmelt runoff beginning and ending earlier than observed snowmelt. The lowest coefficient of the recommended range was selected to minimize the disparity between observed and predicted snowmelt (i.e., the coefficient minimizes the number of inches of snow melted per day and maximizes the number of snowmelt runoff days). • Snowmelt Factors— Scale Factor for Max Abstraction = 1. This factor controls the quantity of snowmelt runoff (i.e., controls losses due to infiltration). Selection of this factor was based upon other calibrated P8 models developed for lakes within the metropolitan area (Reference Glen Lake, Smetana Lake). • Growing Season AMC-II = .05 and AMC-III = 100. Selection of this factor was based upon calibration efforts for the P8 model developed for the Glen Lake Use Attainability Analysis (Barr Engineering, 1999). In development of this calibrated model, it was observed that the model accurately predicted runoff water volumes from monitored watersheds when the Antecedent Moisture Condition II was selected (i.e., curve numbers selected by the model are based upon antecedent moisture conditions). Modeled water volumes were less than observed volumes when Antecedent Moisture Condition I was selected, and modeled water volumes exceeded observed volumes when Antecedent Moisture Condition III was selected. The selected parameters direct the model to only use Antecedent Moisture Condition I when less than 0.05 inches of rainfall occur during the 5 days prior to a rainfall event and to only use Antecedent Moisture Condition III if more than 100 inches of rainfall occur within 5 days prior to a rainfall event, thus causing the City of Edina 2018 Comprehensive Water Resources Management Plan 4-15 model to simulate Antecedent Moisture Condition II throughout the majority of the simulation period. 4.2.4.2 Particle File Selection The NURP50.PAR file was selected for the P8 models. The NURP 50 particle file represents typical concentrations and the distribution of particle settling velocities for a number of stormwater pollutants. The component concentrations in the NURP 50 file were calibrated to the 50th percentile (median) values compiled in the U.S. EPA’s Nationwide Urban Runoff Program (NURP). 4.2.4.3 Passes through the Storm File The number of passes through the storm file was determined after the model had been set up and a preliminary run completed. The selection of the number of passes through the storm file was based upon the number required to achieve model stability. Multiple passes through the storm file were required because the model assumes that dead storage waters contain no pollutants. Consequently, the first pass through the storm file results in lower pollutant loading than occurs with subsequent passes. Stability occurs when subsequent passes do not result in a change in pollutant concentration in the pond waters. To determine the number of passes to select, the model was run with five passes and 10 passes. A comparison of pollutant predictions for all devices was evaluated to determine whether changes occurred between the two scenarios. If there is no difference between five and 10 passes, five passes is sufficient to achieve model stability. This parameter was determined for all of the P8 model areas and no differences were noted between five and 10 passes. Therefore, it was determined that five passes through the storm file resulted in model stability for these models. 4.2.5 Stormwater System Analysis The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. Since site-specific data on pollutant wash-off rates and sediment characteristics were not available, it was necessary to make assumptions based on national average values. Because of these assumptions and lack of in-lake water quality data for model calibration, the analysis of modeling results was based on the percent of phosphorus removed and not on actual phosphorus concentrations. Figures *.4 depict the results of the water quality modeling for each of the major drainage basins. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. The individual water bodies are colored various shades of blue, indicating the percent of the total annual mass of phosphorus entering the water body that is removed (through settling). It is important to note that the percent of phosphorus removed is based on total phosphorus, including phosphorus in the soluble form. Therefore, the removal rates in downstream ponds will likely decrease due to large soluble fractions of incoming phosphorus that could not settle in upstream ponds. The watersheds are depicted in various shades of gray, indicating the cumulative total City of Edina 2018 Comprehensive Water Resources Management Plan 4-16 phosphorus removal achieved. The cumulative percent removal represents the percent of the total annual mass of phosphorus entering the watershed that is removed by the pond and all upstream ponds. Ponds that had an average annual total phosphorus removal rate of 60 percent or greater under average climatic conditions were considered to be performing well. For ponds with total phosphorus removal below 60 percent, the permanent pool storage volume was analyzed to determine whether additional capacity is necessary. Based on recommendations from the MPCA publication Protecting Water Quality in Urban Areas (March 2000), the permanent pool for detention ponds should be equal to or greater than the runoff from a 2.0-inch rainfall, plus sediment storage for at least 25 years of accumulation. This recommended permanent pool storage volume was calculated for each pond with less than 60 percent total phosphorus removal and compared to the existing storage volume. City of Edina 2018 Comprehensive Water Resources Management Plan 5-1 5.0 Nine Mile Creek—North 5.1 General Description of Drainage Area Figure 5.1 depicts the Nine Mile Creek—North drainage basin. The Nine Mile Creek—North drainage area is located in the northwest portion of Edina. The drainage basin encompasses approximately 2,050 acres that ultimately drain to the stretch of Nine Mile Creek between the intersection of the North fork with TH 169 and TH 62. 5.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ponding basins, wetlands, drainage ditches, and overland flow paths. The Nine Mile Creek—North drainage basin has been divided into several major watersheds based on the drainage patterns. These major watersheds are depicted in Figure 5.2. Each major watershed has been further delineated into numerous subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located. Table 5.1 lists each major watershed and the associated subwatershed naming convention. Table 5.1 Major Watersheds within the Nine Mile Creek—North Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Mirror Lake ML_## 40 288 Highlands Lake HI_## 23 276 Hawkes Lake HL_## 54 336 Mud Lake MD_## 51 432 Nine Mile North NMN_## / EdCrk## 91 718 5.1.1.1 Mirror Lake The Mirror Lake watershed is located in the northwest portion of Edina. The 288-acre watershed contains six ponding basins of varying sizes that drain to Mirror Lake via storm sewer. There are also three landlocked ponds within the watershed. The Mirror Lake watershed is almost entirely residential area, with the exception of a few subwatersheds that are a part of the Interlachen Country Club golf course. Mirror Lake spans approximately 26.5 acres. The water level of the lake is controlled at an elevation of approximately 904 feet by a pumped outlet (4 cfs) on the southwest side of the lake. The pumped outlet flows in a southwest direction and eventually connects to the storm sewer system along Blake Road. 5.1.1.2 Highlands Lake The Highlands Lake watershed is located east of Mirror Lake and north of Vernon Avenue. This 276-acre watershed is bordered on the north by Interlachen Boulevard and portions of the Interlachen Country Club golf course. The Highlands Lake watershed has been delineated into 23 subwatersheds, with land use City of Edina 2018 Comprehensive Water Resources Management Plan 5-2 characterized by residential areas, part of the Interlachen golf course, several ponding basins that ultimately drain to Highlands Lake, a wetland area directly east of the lake, Highlands Park directly south of the lake, and a portion of the drainage from Highlands Elementary School. Highlands Lake spans approximately 10.6 acres. The water level of Highlands Lake is controlled at elevation of 888.5 feet by a pumped outlet (approximately 1 cfs). The lift station was installed in 1994 and is located in the southwest corner of Highlands Park, near the intersection of Ayrshire Boulevard and Glengarry Parkway. Water from the pumped outlet flows south, connecting with the storm sewer system along Vernon Avenue, which discharges into Hawkes Lake. 5.1.1.3 Hawkes Lake The Hawkes Lake watershed is located south of the Highlands Lake watershed. The 336-acre watershed comprises 54 subwatersheds. Land use within the watershed includes residential (low and high density), institutional, open space/parks, and a small commercial area. Portions of Highland Elementary and Countryside Elementary drain to Hawkes Lake. Garden Park is also located within this watershed. There are several ponding basins within the watershed that drain to Hawkes Lake via drainage ditches and storm sewer systems. Hawkes Lake spans approximately 8.7 acres. A pumped outlet at an elevation of 888 feet prevents flooding conditions in Hawkes Lake. However, the average water level for this lake between the period of 1963 to 2001 is 885.5 feet (MnDNR Lake Finder webpage http://www.dnr.state.mn.us/lakefind/index.html). The pumped outlet, located on the western side of the lake near the intersection of Wycliffe Road and Merold Drive, discharges southwest into the Mud Lake watershed. 5.1.1.4 Mud Lake (Bredesen Park) The Mud Lake watershed spans an area of approximately 432 acres and is composed of 51 subwatersheds. The land use within the Mud Lake watershed is predominantly residential (ranging from very low to medium density). The watershed has a complex drainage system characterized by numerous ponding basins connected by storm sewer and a unique diversion structure that routes stormwater from the northwest portion of the watershed to the North Fork of Nine Mile Creek or Mud Lake, depending on the amount of precipitation and the water level of the pond near the structure. The diversion structure is located within a manhole on Blake Road, between Saxony Road and Jeffrey Lane, and receives water from the upstream Blake Road storm sewer system and Mirror Lake outlet. The structure controls the amount of incoming water that flows southward toward Mud Lake or into the pond directly west of Blake Road and encircled by Knoll Drive (Knoll Pond). A small orifice in the structure directs flows from small precipitation events southward to Mud Lake. A weir structure within the manhole directs larger stormwater flows into the adjacent Knoll Pond. During large rain events, stormwater will continue to flow into Knoll Pond until the water level within the pond has equalized with the weir elevation; at that point, the remainder of the water will drain south towards Mud Lake. In the event that inflow to Knoll Pond from upstream watersheds surpasses the capacity of the normal outlet to the North Fork of Nine Mile Creek, the diversion structure will act as a second overflow from the pond, directing water to Mud Lake. City of Edina 2018 Comprehensive Water Resources Management Plan 5-3 Mud Lake is a meandered lake located just east of the North Fork of Nine Mile Creek, between TH 62 and Vernon Avenue. The lake and surrounding wetlands are part of Bredesen Park. The park spans an area of approximately 126 acres and is a mix of open water, wet marsh, and floating bog. Mud Lake outlets to the North Fork of Nine Mile Creek just north of TH 62 through a culvert at elevation 849 feet. 5.1.1.5 Nine Mile North The Nine Mile North watershed encompasses the area in northwest Edina that drains directly to the floodplain of the North Fork of Nine Mile Creek. The floodplain within this area is relatively flat and is characterized by wetland conditions. The Nine Mile North watershed is bounded by TH 169 on the west and Schaeffer Road on the east, extending north to Malibu Drive and south to TH 62. The 718-acre watershed consists of 91 subwatersheds that drain to the creek through a series of storm sewer systems and stormwater detention ponds. There are a wide range of land uses within the watershed, including residential (very low density, low density, and medium density), industrial, commercial, highway, wetlands, and natural/park area. 5.2 Stormwater System Results 5.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Nine Mile Creek—North drainage basin. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis Table 5.2 presents the watershed information and results for the 10- and 1-percent-annual-chance frequency hydrologic analyses for the Nine Mile Creek—North basin. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance frequency hydraulic analysis for the Nine Mile Creek—North drainage basin are summarized in Table 5.3. Figure 5.3 illustrates the results of the 1-percent-annual-chance frequency hydraulic analyses. The figure depicts the Nine Mile Creek—North drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, and the 1-percent-annual-chance flood inundation areas identified in the modeling analyses. Figure 5.3 illustrates that several modeled storm sewer junctions (i.e., manholes or catchbasins) within the Nine Mile Creek—North drainage basin are predicted to surcharge during both the 10- and 1-percent- annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to convey all of the stormwater through the storm sewer system at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. City of Edina 2018 Comprehensive Water Resources Management Plan 5-4 To evaluate the level of protection of the stormwater system within the Nine Mile Creek—North drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 5.3. Discussion and recommended improvement considerations for these areas are included in Section 5.3. 5.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 5.4 depicts the results of the water quality modeling for the Nine Mile Creek—North drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 5.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and the 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary and feasible to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 5.3.1 Flood Protection Projects The 2017 Atlas 14 hydrologic and hydraulic modeling analyses identified several locations within the Nine Mile Creek—North drainage basin where the 1-percent-annual-chance flood elevations may impact structures or public safety. Several of these problem areas, and potential corrective measures, were evaluated as part of this plan development and are discussed in more detail in this section. There may be additional flood-prone areas within the drainage basin that warrant further analysis— see Figure 5.3 for the 1-percent-annual-chance flood inundation areas. The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Nine Mile Creek—North drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done in those areas since 2003. City of Edina 2018 Comprehensive Water Resources Management Plan 5-5 5.3.1.1 Maloney Avenue and Tyler Court (ML_35 and ML_19) On either side of Tyler Court, south of Maloney Avenue, there are local depressions with inlets and outlets draining to Mirror Lake. Stormwater runoff from a drainage area of approximately 29 acres discharges into this area. These depressions are drained by a 24-inch pipe. However, downstream, at the intersection of Arthur Street and Waterman Avenue, the pipe flowing east toward Mirror Lake is reduced to 18 inches. Modeling results indicate that the 1-percent-annual-chance flood elevation in this area (940.0 feet west of Tyler Court and 938.1 feet east of Tyler Court) exceeds the low house elevations at 505, 509, and 513 Tyler Court (surveyed at 932.9, 933.1, and 934.07 feet, respectively in 2003) and the apparent low elevations at 500 and 508 Tyler Court. Additionally, the 1-percent-annual-chance flood elevation is more than 2 feet higher than the low elevation on Tyler Court, with the duration of the impacts more than 60 hours, based on a 24-hour duration storm event. This area was also identified as an area of concern in the 2003 and 2009 CWRMPs. The flooding problem in this area is primarily related to the capacity of the storm sewer system between this area and Mirror Lake. To alleviate a portion of the flooding problem, it is recommended that the 18-inch pipe flowing east from the Arthur Street and Waterman Avenue intersection be upgraded to a larger pipe. There are currently no potentially impacted principle structures around Mirror Lake during the 1-percent-annual-chance 24-hour storm event, which is more critical than the 10-day snowmelt event. Therefore, the additional conveyance of water to Mirror Lake does not appear to create problems downstream. Further analysis is needed to balance reducing impacts in this area without creating impacts around Mirror Lake. 5.3.1.2 Between Leslee Lane and Kaymar Drive (MD_22) A backyard depression area exists between the properties on the south side of Leslee Lane and north side of Kaymar Drive. The depression area collects stormwater from a drainage area of approximately 10 acres with 6.4 acres directly contributing. A 15-inch pipe extends southward into the backyard depression area from Leslee Lane, collecting stormwater from the low area, and continues west toward Jeffrey Lane. This system eventually connects with the Blake Road South system at the intersection of Blake Road South and Kaymar Drive. During the 1-percent-annual-chance 24-hour storm event, flow is restricted in the 15-inch pipe and water pools in the backyard depression area to a peak flood level of 916.8 feet. Eventually, the water overflows to the west between 6104 Jeffrey Lane and 6017 Leslee Lane. Based on the LiDAR data and the approximate building footprints, it appears that seven principle structures may be impacted (6016–6028 Kaymar Drive and 6001–6009 Leslee Lane). This area was also identified as an area of concern in the 2003 and 2009 CWRMPs. To reduce the backyard flooding, it is recommended that the size of both the 15-inch pipe draining the backyard depression and the downstream 18-inch pipe be increased to increase discharge capacity. It is also recommended that the surface overflow from this area to Jeffrey Lane be lowered if existing or future road grades allow for it. At a minimum, the existing surface overflow should be maintained. City of Edina 2018 Comprehensive Water Resources Management Plan 5-6 5.3.1.3 Parkwood Road and Schaefer Road (MD_28, MD_29, and MD_35) A small, 0.5-acre stormwater detention pond is located just northwest of the intersection of Schaefer Road and Parkwood Road. The outlet from the pond is a 12-inch pipe that drains south to Parkwood Road, east toward Blake Road, and then south toward the wet pond along Knoll Drive. During the peak of the 1- percent-annual-chance 24-hour storm event, inundation occurs along Parkwood Road due to downstream pipe capacity restrictions and overflows to the south between 6213 and 6217 Parkwood Road (approximately 936.5 feet based on LiDAR data). As the water level rises along Parkwood Road, flow from the detention pond west of Schaefer is reduced due to tailwater effects. The detention pond then fills up, overtopping Schaefer Road to the east, at an elevation of approximately 937.6 feet, to another stormwater detention basin in MD_29. Inundation from the 1-percent-annual-chance event appears to impact four principle structures within this area: 6216 and 6217 Parkwood Road, 6316 Westwood Court, and 5316 Schaefer Road. This area was also identified as an area of concern in the 2003 and 2009 CWRMPs. Due to the presence of downstream flood-prone structures, increasing downstream pipe capacity is not recommended. Review of LiDAR data and approximate building footprints indicates there may be impacts to the principle structures identified above. A survey of the low entry elevations of these structures is recommended. It is also recommended that the surface overflows across Schaefer Road, between 6213 and 6217 Parkwood Road, and between 6212 and 6216 Parkwood Road be maintained or slightly lowered during any future road improvement projects in this area. Underground storage may be an option to reduce flood risk in this area. In particular, Parkwood Road has a significant depression area. If Parkwood Road is reconstructed it could be regraded to have positive drainage to the east with storage under Parkwood Road. Soil maps indicate that the soils here are “B” soils, with moderate infiltration capacity. The effectiveness of underground storage could be optimized by allowing infiltration from the bottom of the underground system. 5.3.1.4 Schaefer Road and View Lane (MD_38) Adjacent to Bredesen Park on the west side, where View Lane, Schaefer Road, and Killarney Lane South meet, there is a backyard depression with a private lift station. Surface overflow to the east, between 6008 and 6012 Schaefer Road, occurs at an elevation of approximately 867.5 feet (based on LiDAR data), which is higher than the 1-percent-annual-chance flood level. This particular area has a history of flooding and of private efforts to reduce flooding. Modeling results indicate that during the 1-percent-annual-chance 24-hour storm event, runoff from the MD_38 watershed would drain to the backyard depression, resulting in a peak flood level of 865.0 feet, and may impact 6021 View Lane and 6016–6032 Schaefer Road. It is recommended that a gravity outlet be installed from the backyard depression area to Bredesen Park to lower the flood elevation in the depression area. This proposed gravity outlet would supplement or replace the private lift station. Due to the larger area of Bredesen Park, and the relatively small volume of water that would be conveyed from the backyard depression, the impact to flood elevations in Bredesen Park would likely be negligible. Further analysis is warranted to verify. City of Edina 2018 Comprehensive Water Resources Management Plan 5-7 5.3.1.5 Nine Mile Village Townhomes (MD_49) The Nine Mile Village Townhomes are located east of Bredesen Park, across Villa Lane. Flood water overtops Villa Lane (surface overflow at approximately 857.3 feet) during the 1-percent-annual-chance 24-hour storm event, with water flowing down Sandpiper Court towards several townhomes. These townhomes may be impacted at the 1-percent-annual-chance flood level (857.7 feet). Water can then overflow from MD_49, traveling southeast to a pond around Colonial Church (CO_2). Modeling results indicate that the peak flood level of the waterbodies within Bredesen Park during this event is 858.2 feet. Construction of a berm on the west side of Villa Lane is recommended to prevent surface overflows from waterbodies within Bredesen Park to the Nine Mile Village Townhomes. Potential surface overflows from Bredesen Park should be directed towards the low area between Sandpiper Court and Red Fox Lane, which eventually flows to the ponds around Colonial Church. If the opportunity arises, additional surface grading within the Nine Mile Village Townhomes complex, particularly in the southeast corner where MD_49 overflows into CO_2, should be considered to promote drainage of the local contributing watershed through a surface overflow. 5.3.1.6 Hawkes Lake and Upstream Surrounding Area (HL_1, HL_11c, HL_11w, HL_49, and HL_12) Hawkes Lake is in the Nine Mile Creek watershed, south of Vernon Avenue South and west of Tracy Avenue. The lake has many inlet points from all directions and one pumped outlet. The pumped outlet drains through a gravity system under Merold Drive to the south, crosses Amy Drive, and eventually discharges to a wetland area (subwatershed MD_3) within Bredesen Park. The 1-percent-annual-chance flood level of Hawkes Lake (HL_1) and the immediately surrounding area is determined by the 10-day snowmelt event (894.1 feet). The 1-percent-annual-chance flood level of HL_12 to the east of Hawkes Lake is determined by the 24-hour precipitation event (903.1 feet). Based on modeling results, LiDAR data, and approximate building footprints, there are nine principle structures around Hawkes Lake (5621, 5625, 5629, and 5701 Wycliffe Road, 5708 and 5705 Warden Avenue, 5717 Hawkes Drive, and 5712 and 5716 Tracy Avenue), six principle structures immediately north of Vernon Avenue South (5533, 5537, and 5604 Dundee Road, 5532, 5536, and 5541 Mirror Lakes Drive), and one principle structure near Warden Avenue (5537 Warden Avenue) that are potentially impacted at the 1-percent-annual-chance flood level. It is recommended that capacity of the pumped outlet and the downstream gravity storm sewer system be increased to reduce flood risk around Hawkes Lake; however, this may require that the capacity be increased all the way downstream to Bredesen Park, where the downstream impacts are expected to be minimal. The capacity of the storm sewer systems draining to Hawkes Lake, particularly from north of Vernon Avenue South and from Warden Avenue, should also be increased to alleviate flooding in the areas upstream of Hawkes Lake. Providing additional flood storage within the city-owned parcel in subwatershed MD_15 could be considered to mitigate the additional flows to Bredesen Park, if needed, assuming flood elevations in MD_15 aren’t increased and the existing surface overflow elevation is maintained or lowered. A cursory analysis of this option was completed by the city in 2015 in preparation for the city’s 2016 street reconstruction project (Countryside H). City of Edina 2018 Comprehensive Water Resources Management Plan 5-8 5.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the annual removal of total phosphorus from several ponds in the Nine Mile Creek—North drainage area was predicted to be below the desired 60 percent removal rate. For those ponds with total phosphorus removal below 60 percent, the permanent pool storage volume was analyzed to determine whether additional capacity is necessary. The ponds with deficiencies in total phosphorus removal and permanent pool volume are listed below (and are also summarized in Appendix D), with recommended pond upgrades. Construction of new or expansion of existing water quality basins is one way to increase pollutant removal prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. 5.3.2.1 MD_15 Pond MD_15 is located just north of the 5904, 5908, and 5912 Sun Road properties, south of Amy Drive. The pond receives runoff from an area of approximately 25 acres. Pond MD_15 outlets to the storm sewer system along Sun Road via an 18-inch RCP pipe. The pond is a Type 5 wetland and was assumed to have an average depth of 4 feet. Based on this depth assumption and the 2-foot topographic information for the pond, the current permanent pool storage is 1.1 acre-feet. This is less than the MPCA-recommended storage volume for detention basins. It is recommended that an additional 0.3 acre-feet of dead storage volume be provided to meet the MPCA design criteria for detention basins. 5.3.2.2 NMN_27 Pond NMN_27 is located northeast of the TH 62 and TH 169 intersection. The pond is south of Langford Court, directly east of Lincoln Road, and northwest of Waterford Court. The pond receives runoff from an area of approximately 37 acres, including drainage from TH 169 and Lincoln Drive. The pond is a Type 5 wetland and was assumed to have an average depth of 4 feet. Based on this depth assumption and the 2-foot topographic information for the pond, the current permanent pool storage volume is 1.7 acre-feet. This is less than the MPCA-recommended storage volume for Pond NMN_27. It is recommended that an additional 1.4 acre-feet of dead storage volume be provided to meet the MPCA design criteria for detention basins. 5.3.2.3 NMN_24 Pond NMN_24 is located between Waterford Court and Habitat Court, downstream and to the southeast of Pond NMN_27. The pond receives runoff from a 5-acre watershed. The pond is a Type 4 wetland and was assumed to have an average depth of 2 feet. Based on this depth assumption and the 2-foot topographic information for the pond, the current permanent pool storage volume is 1.7 acre-feet. This is greater than the MPCA-recommended storage volume for detention basins; however, because water City of Edina 2018 Comprehensive Water Resources Management Plan 5-9 quality modeling results indicate that the total phosphorus removal in Pond NMN_24 is below desired levels, it is recommended that the depth of the pond be increased to 4 feet to improve removal efficiency. 5.3.2.4 NMN_49 Pond NMN_49 is a sedimentation basin located directly west of the 5521 Malibu Drive property. The sedimentation basin receives runoff from a watershed of approximately 6 acres, in addition to incoming flows from the upstream sedimentation basin (NMN_48). Pond NMN_49 discharges to the North Fork of Nine Mile Creek. Based on storm sewer information from the City, a 2-foot average depth was assumed. Considering this depth assumption and the 2-foot topographic data for the pond area, the current permanent pool storage volume is 0.14 acre-feet. Compared to the calculated MPCA-recommended storage volume for Pond NMN_49, this is not an adequate amount of permanent pool storage for this basin. It is recommended that 0.2 acre-feet of dead storage volume be added to meet the MPCA design criteria for detention basins. 5.3.2.5 MD_3 Pond MD_3 is located in Bredesen Park, directly east of the parking area off Olinger Boulevard. Pond MD_3 receives runoff from a 48-acre watershed, in addition to discharges from ponds MD_15 and MD_13. The pond is a Type 5 wetland and was assumed to have an average depth of 4 feet. Based on this depth assumption and 2-foot topographic information for the pond area, the current permanent pool storage volume is 4.7 acre-feet—greater than the MPCA-recommended storage volume for detention ponds. However, because water quality modeling results indicate that the total phosphorus removal in Pond MD_3 is below desired levels, it is recommended that the pond be excavated to remove accumulated sediment its depth increased to improve removal efficiency. Table 5.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - North Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) EdCrk1 17.1 11 133 8.5 3.2 10.2 66 4.3 EdCrk2 8.4 20 76 3.8 1.6 5.0 38 1.8 EdCrk3 71.6 47 415 37.5 13.4 43.0 194 19.5 EdCrk5 45.9 51 336 25.0 8.7 27.5 164 13.3 EdCrk6 5.5 21 49 2.5 1.0 3.3 24 1.2 EdCrk7 23.1 34 209 11.8 4.4 13.9 107 6.1 EdCrk7c 5.0 8 51 2.4 1.0 3.0 27 1.2 HI_1 38.7 46 256 20.9 7.3 23.2 122 11.1 HI_10 42.4 25 264 19.0 8.0 25.4 114 9.1 HI_11 3.5 25 34 1.6 0.7 2.1 17 0.8 HI_12 15.8 25 114 7.0 3.0 9.4 51 3.4 HI_13 26.1 27 195 12.4 4.9 15.6 92 6.1 HI_14 4.6 25 43 2.1 0.9 2.7 21 1.0 HI_15 10.4 25 80 4.7 2.0 6.2 37 2.2 HI_16 9.5 25 51 4.2 1.8 5.7 21 2.0 HI_17 6.2 16 39 3.0 1.2 3.7 18 1.5 HI_18 21.3 11 107 10.6 4.0 12.8 48 5.3 HI_19 4.5 12 27 2.1 0.9 2.7 12 1.0 HI_2 4.2 23 42 2.0 0.8 2.5 22 1.0 HI_20 18.4 12 95 10.0 3.5 11.1 45 5.2 HI_21 2.7 14 25 1.5 0.5 1.6 13 0.8 HI_22 2.2 30 23 1.2 0.4 1.3 12 0.7 HI_3 8.4 25 65 3.9 1.6 5.0 31 1.9 HI_4 11.0 25 80 4.9 2.1 6.6 36 2.3 HI_5 8.0 33 71 4.4 1.5 4.8 37 2.4 HI_6 9.5 25 77 5.3 1.8 5.7 39 2.8 HI_7 7.0 25 52 3.1 1.3 4.2 23 1.5 HI_7a 5.2 25 48 2.3 1.0 3.1 24 1.1 HI_8 8.3 25 69 3.7 1.6 5.0 32 1.8 HI_9 8.2 25 43 3.6 1.5 4.9 18 1.7 HL_1 25.5 45 213 13.0 4.8 15.3 104 6.7 HL_10 2.7 24 23 1.3 0.5 1.6 11 0.6 HL_11c 2.3 25 25 1.0 0.4 1.4 13 0.5 HL_11e 5.0 25 49 2.2 0.9 3.0 25 1.1 HL_11w 22.5 19 211 10.0 4.3 13.5 106 4.7 HL_12 12.5 25 93 5.8 2.4 7.5 43 2.8 HL_13 2.2 39 23 1.0 0.4 1.3 12 0.5 HL_14 4.4 25 44 2.0 0.8 2.7 23 1.0 HL_15 0.8 25 8 0.3 0.1 0.4 5 0.2 HL_16 4.8 26 43 2.2 0.9 2.9 21 1.0 HL_17 1.3 27 15 0.6 0.3 0.8 8 0.3 HL_18 3.1 25 26 1.4 0.6 1.8 12 0.7 HL_19 1.1 25 11 0.5 0.2 0.7 6 0.2 HL_2 5.6 25 49 2.5 1.1 3.4 24 1.2 HL_20 4.5 25 33 2.0 0.8 2.7 15 0.9 HL_21 11.7 16 73 4.7 2.2 7.0 28 2.0 HL_23 4.4 29 40 2.0 0.8 2.7 20 1.0 HL_25 2.2 25 19 0.9 0.4 1.3 8 0.4 HL_26 8.6 25 66 3.9 1.6 5.2 30 1.8 HL_27 1.2 25 11 0.6 0.2 0.7 6 0.3 HL_28 5.6 49 51 3.0 1.1 3.4 26 1.6 HL_29 15.5 30 130 7.9 2.9 9.3 65 4.1 HL_29a 0.2 20 2 0.1 0.0 0.1 1 0.1 HL_29b 6.4 20 57 3.3 1.2 3.8 29 1.7 HL_3 6.8 25 37 3.0 1.3 4.1 15 1.4 HL_30 2.6 25 24 1.2 0.5 1.6 12 0.6 HL_31 6.9 26 54 3.1 1.3 4.1 25 1.5 HL_32 1.0 17 11 0.4 0.2 0.6 6 0.2 HL_33 4.3 33 43 2.0 0.8 2.6 22 1.0 HL_34 1.7 25 16 0.7 0.3 1.0 8 0.4 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) Table 5.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - North Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) HL_35 4.5 25 44 2.1 0.8 2.7 23 1.0 HL_35a 0.6 31 7 0.3 0.1 0.3 4 0.1 HL_36 12.8 30 88 5.8 2.4 7.7 39 2.8 HL_37 4.6 22 42 2.1 0.9 2.8 21 1.0 HL_38 0.7 42 9 0.4 0.1 0.4 5 0.2 HL_39 16.0 30 128 7.4 3.0 9.6 60 3.6 HL_4 5.6 25 44 2.5 1.1 3.3 21 1.2 HL_40 17.5 25 143 8.1 3.3 10.5 69 4.0 HL_41 1.7 25 18 0.8 0.3 1.0 10 0.4 HL_42 11.2 25 100 5.0 2.1 6.7 49 2.4 HL_43 5.0 50 46 2.6 0.9 3.0 24 1.4 HL_44 2.4 52 25 1.3 0.5 1.4 13 0.7 HL_45 6.8 25 57 3.0 1.3 4.1 27 1.5 HL_46 3.0 25 29 1.4 0.6 1.8 15 0.7 HL_46a 0.8 25 9 0.4 0.2 0.5 5 0.2 HL_47 16.2 40 140 7.9 3.1 9.7 69 4.0 HL_48 4.6 55 47 2.4 0.9 2.8 24 1.2 HL_49 4.4 25 39 2.0 0.8 2.7 19 1.0 HL_5 1.8 25 18 0.8 0.3 1.1 9 0.4 HL_50 11.2 38 83 5.5 2.1 6.7 39 2.7 HL_6 3.3 25 29 1.5 0.6 2.0 15 0.8 HL_7 3.8 25 31 1.7 0.7 2.3 15 0.8 HL_8 14.0 28 89 6.3 2.6 8.4 38 3.0 HL_9 6.6 35 57 3.2 1.3 4.0 28 1.6 MD_1 33.3 67 165 19.1 6.1 20.0 79 10.5 MD_10 1.0 20 10 0.4 0.2 0.6 5 0.2 MD_11 6.9 2 36 2.9 1.3 4.2 15 1.3 MD_12 14.0 25 108 6.3 2.7 8.4 50 3.0 MD_13 12.4 38 100 6.0 2.3 7.4 48 3.0 MD_14 8.6 24 68 3.9 1.6 5.1 32 1.9 MD_15 6.7 33 48 3.7 1.3 4.0 24 2.0 MD_16 5.2 25 45 2.6 1.0 3.1 23 1.3 MD_17 6.6 25 47 3.1 1.3 4.0 22 1.5 MD_18 2.3 24 18 1.0 0.4 1.4 9 0.5 MD_19 5.2 30 45 2.4 1.0 3.1 21 1.2 MD_2 12.5 40 109 6.8 2.4 7.5 56 3.6 MD_20 12.9 25 86 5.8 2.4 7.7 38 2.8 MD_21 9.1 43 73 4.4 1.7 5.5 35 2.2 MD_22 6.4 25 58 3.0 1.2 3.8 29 1.5 MD_23 2.2 25 19 1.0 0.4 1.3 10 0.5 MD_24 3.0 25 25 1.4 0.6 1.8 12 0.7 MD_25 7.9 52 71 4.0 1.5 4.7 35 2.1 MD_26 2.8 23 24 1.2 0.5 1.7 12 0.6 MD_27 18.0 25 140 8.0 3.4 10.8 64 3.8 MD_28 5.8 25 33 2.6 1.1 3.5 14 1.2 MD_29 11.9 22 76 5.2 2.3 7.2 32 2.4 MD_3 6.6 18 44 3.4 1.3 4.0 21 1.7 MD_30 1.9 25 19 0.8 0.4 1.1 10 0.4 MD_31 5.6 25 44 2.5 1.1 3.3 20 1.2 MD_32 5.1 25 24 2.2 1.0 3.1 10 1.0 MD_33 2.7 25 29 1.2 0.5 1.6 15 0.6 MD_34 3.0 25 15 1.3 0.6 1.8 6 0.6 MD_35 4.8 21 44 2.1 0.9 2.9 22 1.0 MD_36 7.0 19 64 3.2 1.3 4.2 32 1.5 MD_37 2.8 19 29 1.2 0.5 1.7 15 0.6 MD_38 6.1 25 50 2.8 1.2 3.7 24 1.3 MD_39 6.3 19 51 2.7 1.2 3.8 24 1.3 MD_4 13.7 50 115 7.6 2.6 8.2 58 4.1 MD_40 11.2 27 71 5.2 2.1 6.7 32 2.6 MD_41 8.4 25 75 4.0 1.6 5.0 38 2.0 Table 5.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - North Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) MD_42 10.4 25 78 4.7 2.0 6.3 36 2.2 MD_43 8.8 25 58 3.9 1.7 5.3 25 1.8 MD_44 1.3 25 12 0.6 0.3 0.8 6 0.3 MD_45 7.8 25 50 3.4 1.5 4.7 21 1.6 MD_46 6.9 24 51 3.1 1.3 4.1 23 1.5 MD_47 5.2 36 47 2.5 1.0 3.1 23 1.2 MD_48 6.4 23 61 2.8 1.2 3.8 30 1.4 MD_48a 16.7 22 122 7.4 3.2 10.0 55 3.5 MD_49 5.2 23 42 2.5 1.0 3.1 21 1.3 MD_5 1.4 18 14 0.8 0.3 0.9 8 0.4 MD_50 53.4 63 250 30.3 9.7 32.0 118 16.5 MD_6 6.1 24 45 3.0 1.2 3.7 21 1.5 MD_7 7.9 31 56 3.6 1.5 4.8 25 1.8 MD_8 10.5 31 54 4.8 2.0 6.3 23 2.3 MD_9 4.6 25 36 2.2 0.9 2.7 18 1.1 ML_1 53.9 53 476 27.5 10.2 32.3 233 14.3 ML_10 6.7 25 55 2.9 1.3 4.0 25 1.3 ML_11 1.8 14 18 0.8 0.3 1.1 9 0.4 ML_12 2.5 22 20 1.1 0.5 1.5 9 0.5 ML_12a 1.6 25 17 0.7 0.3 1.0 9 0.3 ML_13 9.2 17 56 4.0 1.7 5.5 24 1.8 ML_14 0.9 25 10 0.4 0.2 0.5 5 0.2 ML_15 11.1 40 89 5.3 2.1 6.7 42 2.7 ML_16 8.1 55 66 4.2 1.5 4.8 32 2.2 ML_17 7.0 20 55 3.0 1.3 4.2 25 1.4 ML_18 14.2 21 122 6.2 2.7 8.5 59 3.0 ML_19 5.3 22 48 2.4 1.0 3.2 24 1.2 ML_2 13.2 36 115 6.3 2.5 7.9 56 3.1 ML_20 5.2 27 40 2.4 1.0 3.1 18 1.1 ML_21 15.9 18 95 6.9 3.0 9.5 40 3.2 ML_22 3.1 25 27 1.4 0.6 1.9 13 0.7 ML_23 0.9 25 10 0.4 0.2 0.6 5 0.2 ML_24 2.1 20 21 0.9 0.4 1.3 10 0.4 ML_25 4.3 25 40 1.9 0.8 2.6 20 0.9 ML_26 7.1 33 59 3.3 1.3 4.2 28 1.6 ML_27 2.9 18 24 1.3 0.6 1.8 11 0.6 ML_28 13.0 36 104 6.1 2.5 7.8 48 3.0 ML_29 3.7 24 35 1.7 0.7 2.2 17 0.8 ML_29a 2.3 25 24 1.0 0.4 1.4 12 0.5 ML_3 1.2 17 9 0.5 0.2 0.7 4 0.2 ML_30 10.7 23 82 4.7 2.0 6.4 37 2.2 ML_31 14.7 11 101 6.1 2.8 8.8 44 2.8 ML_32 3.8 63 42 2.1 0.7 2.3 22 1.1 ML_33 0.7 20 7 0.3 0.1 0.4 4 0.1 ML_34n 4.3 27 40 2.1 0.8 2.6 20 1.1 ML_34s 4.8 33 52 2.3 0.9 2.9 27 1.1 ML_35 7.1 15 48 3.0 1.3 4.2 21 1.4 ML_38 8.0 10 48 3.8 1.5 4.8 22 1.9 ML_4 1.7 24 17 0.8 0.3 1.0 8 0.4 ML_40 13.7 13 85 6.8 2.6 8.2 40 3.4 ML_5 3.8 18 32 1.7 0.7 2.3 15 0.8 ML_6 3.5 26 29 1.6 0.7 2.1 14 0.8 ML_7 2.2 23 22 1.0 0.4 1.3 11 0.5 ML_8 8.7 23 71 3.8 1.6 5.2 33 1.8 ML_9 2.9 23 22 1.3 0.6 1.7 10 0.6 NMN_10 2.5 25 22 1.1 0.5 1.5 11 0.5 NMN_11 1.0 23 11 0.5 0.2 0.6 6 0.2 NMN_13 5.3 23 36 2.3 1.0 3.2 16 1.1 NMN_14 4.3 25 31 1.9 0.8 2.6 14 0.9 NMN_15 4.8 25 40 2.2 0.9 2.9 19 1.0 Table 5.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - North Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) NMN_16 3.0 25 30 1.4 0.6 1.8 15 0.7 NMN_17 2.9 24 28 1.3 0.6 1.8 14 0.6 NMN_18 4.7 24 36 2.1 0.9 2.8 17 1.0 NMN_19 18.1 25 143 8.1 3.4 10.9 66 3.9 NMN_20 10.6 12 78 4.5 2.0 6.3 35 2.0 NMN_21 0.6 25 6 0.3 0.1 0.3 3 0.1 NMN_22 0.6 25 7 0.3 0.1 0.4 3 0.2 NMN_23 3.9 37 35 1.8 0.7 2.3 17 0.9 NMN_24 4.1 49 42 2.2 0.8 2.5 22 1.2 NMN_25 0.7 25 7 0.3 0.1 0.4 3 0.1 NMN_26 5.9 25 52 2.7 1.1 3.5 26 1.3 NMN_27 2.6 47 28 1.3 0.5 1.5 15 0.7 NMN_28 6.7 40 49 3.2 1.3 4.0 22 1.6 NMN_29 0.6 27 6 0.3 0.1 0.3 3 0.1 NMN_3 1.3 15 15 0.7 0.3 0.8 8 0.3 NMN_31 4.0 40 31 2.0 0.8 2.4 15 1.0 NMN_32 20.8 67 155 11.4 3.9 12.5 75 6.1 NMN_33 7.4 42 55 3.7 1.4 4.5 26 1.9 NMN_34 2.9 41 32 1.4 0.5 1.7 17 0.7 NMN_35 5.4 25 50 2.6 1.0 3.2 26 1.3 NMN_36 9.0 25 76 4.1 1.7 5.4 36 1.9 NMN_37 13.3 25 108 6.0 2.5 8.0 50 2.8 NMN_38 36.2 24 180 15.9 6.8 21.7 74 7.4 NMN_39 8.1 23 68 3.6 1.5 4.9 32 1.7 NMN_40 3.9 78 38 2.2 0.7 2.3 20 1.2 NMN_41 9.3 67 73 5.1 1.8 5.6 36 2.8 NMN_42 11.0 71 64 6.0 2.1 6.6 30 3.2 NMN_43 12.8 25 107 5.8 2.4 7.7 51 2.8 NMN_44 6.1 25 39 2.7 1.1 3.6 17 1.3 NMN_45 2.9 24 25 1.3 0.5 1.7 12 0.7 NMN_46 2.5 22 23 1.2 0.5 1.5 12 0.6 NMN_47 3.7 25 30 1.7 0.7 2.2 15 0.9 NMN_48 0.4 1 4 0.2 0.1 0.3 2 0.1 NMN_49 0.9 18 8 0.5 0.2 0.6 4 0.2 NMN_50 17.8 33 142 8.3 3.4 10.7 66 4.1 NMN_51 0.8 25 8 0.4 0.2 0.5 4 0.2 NMN_52 0.3 43 4 0.2 0.1 0.2 2 0.1 NMN_53 0.6 63 7 0.3 0.1 0.4 4 0.2 NMN_54 2.4 64 28 1.3 0.5 1.5 15 0.7 NMN_55 4.7 36 43 2.2 0.9 2.8 21 1.1 NMN_56 8.0 19 62 3.5 1.5 4.8 29 1.6 NMN_57 3.0 25 28 1.5 0.6 1.8 14 0.7 NMN_58 4.9 25 36 2.2 0.9 2.9 16 1.0 NMN_59 3.5 65 39 1.9 0.7 2.1 21 1.0 NMN_60 34.1 15 212 16.4 6.5 20.5 98 8.1 NMN_61 8.3 25 71 3.7 1.6 5.0 34 1.8 NMN_62a 0.8 15 6 0.3 0.1 0.4 3 0.1 NMN_62b 9.0 16 74 3.9 1.7 5.4 35 1.8 NMN_62c 3.9 18 38 1.8 0.7 2.4 19 0.9 NMN_62d 1.6 15 16 0.7 0.3 0.9 8 0.4 NMN_62e 4.6 46 48 2.4 0.9 2.7 26 1.2 NMN_62f 0.5 17 4 0.2 0.1 0.3 2 0.1 NMN_63a 2.9 19 29 1.3 0.6 1.8 15 0.6 NMN_63b 4.0 17 38 1.7 0.8 2.4 19 0.8 NMN_63c 2.7 27 27 1.2 0.5 1.6 14 0.6 NMN_64 15.4 39 139 7.4 2.9 9.2 68 3.7 NMN_65 4.6 23 43 2.1 0.9 2.8 22 1.0 NMN_66 7.9 23 67 3.6 1.5 4.8 32 1.7 NMN_67 10.5 25 90 4.7 2.0 6.3 43 2.3 NMN_68 2.3 18 19 1.0 0.4 1.4 10 0.5 Table 5.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - North Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) NMN_7 11.6 25 94 5.2 2.2 6.9 44 2.5 NMN_70 4.0 25 37 1.8 0.8 2.4 18 0.9 NMN_71 6.1 24 54 2.7 1.2 3.6 26 1.3 NMN_72 7.0 25 60 3.1 1.3 4.2 29 1.5 NMN_73 10.0 36 68 4.7 1.9 6.0 31 2.3 NMN_74 3.4 80 36 1.9 0.6 2.0 19 1.1 NMN_75 14.7 32 88 6.7 2.8 8.8 38 3.2 NMN_76 10.5 38 84 5.0 2.0 6.3 39 2.5 NMN_77 7.6 37 60 3.6 1.4 4.6 28 1.8 NMN_78 6.4 25 37 2.9 1.2 3.8 16 1.4 NMN_8 6.7 25 48 3.0 1.3 4.0 21 1.4 NMN_80 8.2 15 61 3.5 1.6 4.9 27 1.6 NMN_81 1.9 33 20 1.0 0.4 1.1 11 0.5 NMN_82 8.9 25 65 4.0 1.7 5.3 29 1.9 NMN_83 3.0 25 25 1.4 0.6 1.8 12 0.7 NMN_84 7.1 25 46 3.2 1.3 4.2 20 1.5 NMN_85 7.5 19 43 3.4 1.4 4.5 19 1.7 NMN_9 9.6 25 53 4.9 1.8 5.8 24 2.5 NMN_90 3.0 37 30 1.5 0.6 1.8 16 0.7 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1098 916.0 914.1 1100 915.9 914.0 1113.1 965.9 965.7 1114.1 964.1 964.1 1115.1 957.0 957.0 1119 931.1 929.6 1121.1 916.4 916.0 1122.1 914.8 914.6 1124.1 922.5 922.2 1127 925.1 925.1 1130.1 917.5 915.9 1131 914.9 914.5 1141 939.2 939.3 1144 916.0 915.8 1154 street 894.1 ¹ 893.0 1168 894.9 894.7 124 917.2 914.6 126 916.1 911.2 128 913.1 909.8 129 908.0 904.7 134 910.9 910.2 137 907.3 906.8 138 907.5 906.8 1386 917.2 914.0 1387 917.2 914.0 139 907.9 907.0 140 908.1 906.9 141 street 908.2 906.8 143 904.6 903.6 145 899.5 899.2 1454 925.8 925.8 1455 921.8 921.7 1467 978.9 977.2 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1468 976.7 976.4 1469 975.1 975.1 1475 951.7 951.1 1477 952.5 951.6 1478 953.9 950.9 1480 949.4 949.2 1481 947.6 947.4 1482 940.8 940.4 1484 936.7 936.5 150 908.4 906.3 152 908.1 906.4 153 907.6 906.3 157 898.5 898.4 1607 899.3 899.3 1622 911.5 909.7 1625 923.1 920.0 1626 923.3 922.0 1627 928.8 928.7 1628 936.8 936.8 1629 939.2 938.6 1630 940.5 939.5 1631 941.6 940.4 1632 942.4 941.0 1633 942.5 941.0 1634 942.5 941.0 1636 943.1 941.5 172 894.6 ¹ 889.6 174 905.1 902.8 1743 920.0 918.8 1745 depression 860.4 860.3 175 896.7 896.4 1750 866.5 865.3 1752 866.5 865.5 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1762 879.5 878.5 1774 878.9 874.4 178 922.7 922.4 1785 914.5 913.8 1794 930.2 930.2 1795 941.6 941.1 1797 941.6 941.1 1798 940.8 938.5 1810 888.5 884.3 1815 891.8 890.2 1817 914.5 911.2 1818 914.3 913.3 183 907.2 906.0 185 905.7 905.1 186 901.2 900.7 187 894.6 ¹ 889.6 188 ditch/byd 909.1 905.5 189 909.2 905.5 190 909.6 908.9 193 904.5 904.5 194 903.2 903.2 195 894.6 894.6 1950 912.9 912.9 197 870.8 870.5 198 865.8 865.5 202 864.8 864.0 203 864.8 864.5 204 862.4 861.5 209 879.2 878.2 210 879.2 878.6 211 879.2 878.9 212 879.2 878.8 214 877.8 877.5 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 215 874.2 873.9 2158 863.5 863.4 2162 918.6 918.3 2174 902.0 901.7 224_NMN 860.9 860.7 226_NMN 861.0 860.6 2274 907.5 904.9 228 863.6 863.2 229 859.4 858.8 2290 916.2 914.1 2292 919.2 918.8 230 858.8 858.7 2394 903.9 903.7 2395 908.9 908.8 2411 925.3 925.0 2412 925.4 925.4 2417 939.3 936.5 242 863.1 863.0 245 938.8 937.9 246.1 937.3 936.7 247.1 937.4 934.9 250 921.4 921.0 2504 885.5 884.6 2505 890.1 890.1 2506 903.7 903.7 2507 920.4 920.4 2508 894.9 894.8 2509 907.5 906.6 2512 921.2 921.2 2515 937.4 935.2 2517 894.9 893.2 252.1 918.6 918.0 2520 938.2 935.4 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2521 948.0 947.9 2522 948.1 947.9 2527 919.3 919.1 2528 918.5 918.4 2531 902.0 899.4 2532 911.6 906.1 2534 ditch 865.8 864.5 2538 927.1 928.5 2539 910.7 910.4 2540 929.7 929.6 2541 922.2 922.2 2549 933.0 930.1 255 915.4 914.2 2550 936.0 930.1 2551 936.2 929.2 2552 971.1 968.2 2553 973.8 973.6 258 909.3 908.8 260 899.3 899.1 261 897.6 897.3 262 890.9 890.6 264_NMN 866.2 865.9 267 890.5 890.2 268_NMN 885.6 885.6 269_NMN 878.1 876.0 2699 907.7 907.3 270 878.1 876.0 2701 hwy ditch 906.3 905.6 2702 896.4 896.3 2706 902.3 901.1 2709 902.3 901.2 2710 902.3 901.2 2712 902.3 901.2 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2718 916.1 915.5 2719 911.5 909.7 2726 899.8 899.8 275 862.0 861.9 278.1 942.3 942.3 279.1 941.6 941.6 280.1 941.0 941.0 281 938.7 938.7 2822 894.6 891.9 2824 896.8 895.1 2847 879.5 879.2 2848 879.3 878.9 2849 879.3 878.3 285 935.9 935.9 2850 879.2 877.6 2851 878.8 877.2 2853 893.7 892.9 2854 895.9 894.9 2855 897.8 896.9 2856 906.0 903.2 2857 908.0 904.3 286 935.8 935.8 287 931.6 931.6 289 918.8 917.4 2908 868.4 868.1 2915 894.6 ¹ 891.4 2916 894.6 ¹ 889.6 292 912.0 911.6 293 910.2 910.2 294 910.0 909.9 295 909.7 909.5 2956 858.2 855.8 296 909.5 909.0 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2961 858.2 855.4 297 909.4 908.9 298 938.0 938.0 584 938.3 937.5 585.1 937.3 936.7 587.1 934.0 933.4 591 918.9 918.4 592 918.9 918.4 596 914.6 911.8 597 914.2 911.7 598 913.4 911.5 599 907.5 907.3 600 892.8 892.6 601 877.1 876.7 603 866.5 865.4 609.1 872.8 872.3 611.1 870.6 870.2 627 863.6 860.9 629 878.0 877.2 631 892.2 892.1 639 884.9 884.2 641 876.4 875.6 651.1 874.9 873.6 652 874.7 873.9 654 874.9 874.1 655 876.3 874.0 656 878.6 874.1 658 884.5 884.4 663.1 892.7 892.6 667 890.1 890.1 674 908.4 908.2 675.1 912.5 912.2 676.1 915.1 913.8 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 CBMH_432 902.4 901.2 CBMH_433 901.5 900.1 EdCrk1 creek 878.7 874.3 EdCrk2 873.2 871.7 EdCrk2a 875.4 873.0 EdCrk2b 874.3 872.6 EdCrk2c 873.7 872.1 EdCrk3 creek 868.3 866.4 EdCrk3a 873.0 871.5 EdCrk5 pond 858.5 866.5 8.0 864.7 6.2 EdCrk6 863.2 859.1 EdCrk6a 866.4 862.0 EdCrk6b 863.5 859.8 EdCrk6b_1 865.4 860.9 EdCrk6c 863.4 859.2 EdCrk6d 863.4 859.1 EdCrk7 creek 858.2 855.4 EdCrk7a 859.9 856.9 EdCrk7b 859.4 856.9 EdCrk7c 858.8 856.3 EdCrk7d 858.4 856.0 EdCrk7d_1 858.4 856.0 EdCrk7e 858.3 855.7 EdCrk7e_1 858.3 855.6 EdCrk7f 858.3 855.6 EdCrk7g 858.3 855.6 EdCrk7h 858.2 855.4 HI_1 pond 888.4 894.1 ¹ 5.7 891.5 3.1 HI_10 street/lot 894.1 ¹ 893.0 HI_11 925.6 925.2 HI_12 903.1 902.9 HI_13 wetland 885.3** 889.1 ¹ 3.8 886.5 1.2 HI_14 street 901.1 897.3 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 HI_15 cul-de-sac 902.9 902.6 HI_16 906.4 906.1 HI_17 pond 901.0 903.0 2.0 902.5 1.5 HI_18 pond 899.6 902.3 2.7 901.2 1.6 HI_19 depression 914.5 912.5 HI_2 894.1 891.6 HI_20 pond 899.6 903.8 4.2 901.5 1.9 HI_21 depression 903.8 901.5 HI_22 pond 901.0 903.4 2.4 902.1 1.1 HI_3 pond 899.6 902.1 2.5 901.8 2.2 HI_4 street/park 894.1 ¹ 893.0 HI_5 pond 888.3 894.3 6.0 891.7 3.4 HI_6 ditch 902.7 901.8 HI_7 911.8 911.6 HI_7a 911.3 911.0 HI_8 902.2 901.9 HI_9 908.2 908.0 HL_1 pond 885.5 894.6 ¹ 9.1 889.6 4.1 HL_10 street 908.2 905.8 HL_11c street 894.9 893.4 HL_11e street 894.9 892.1 HL_11w street 895.2 894.5 HL_12 street 908.6 906.8 HL_13 wetland 904.0** 907.7 3.7 906.2 2.2 HL_14 byd 909.6 908.9 HL_15 907.8 905.7 HL_16 street 908.1 906.3 HL_17 900.6 898.7 HL_18 byd 903.4 901.9 HL_19 street 914.3 913.4 HL_1A 894.6 ¹ 889.6 HL_2 street 902.2 901.5 HL_20 902.7 902.6 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 HL_21 byd 898.0 895.9 HL_23 street 911.8 911.1 HL_25 byd 898.0 895.8 HL_26 street 899.1 897.9 HL_27 cul-de-sac 926.3 925.6 HL_28 pond 898.2 907.6 9.4 904.4 6.2 HL_29 depression 910.0 908.1 HL_29a 907.8 907.4 HL_29b ball field 911.2 910.8 HL_3 byd 908.0 907.7 HL_30 street/yd 918.8 918.7 HL_31 street 930.6 929.0 HL_32 street 907.7 904.4 HL_33 913.0 912.8 HL_34 914.3 914.1 HL_35 wetland 906.9 917.2 10.3 912.6 5.7 HL_35a 939.1 938.6 HL_36 byd 924.4 919.9 HL_37 911.8 908.6 HL_38 914.6 910.5 HL_39 pond 902.2** 908.7 ¹ 6.5 904.7 2.5 HL_4 street 897.4 897.2 HL_4$I 897.1 897.1 HL_40 wetland 899.7 907.0 7.3 901.1 1.4 HL_41 ditch 920.0 918.7 HL_42 925.3 925.0 HL_43 street 913.7 912.0 HL_44 wetland 904.6 908.2 3.6 905.2 0.6 HL_45 908.8 905.9 HL_46 894.6 ¹ 889.6 HL_46a 909.8 905.5 HL_47 byd 917.2 916.6 HL_48 929.5 928.1 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 HL_49 byd 894.9 892.3 HL_5 917.5 912.2 HL_50 pond 927.8** 933.2 ¹ 5.4 930.5 2.7 HL_6 911.4 911.2 HL_7 937.6 937.5 HL_8 pond 901.9 908.1 6.2 906.1 4.2 HL_9 pond 905.4 908.8 3.4 907.0 1.6 MD_1 pond 851.5 858.2 6.7 855.4 3.9 MD_10 street 861.6 861.4 MD_11 pond 853.0 858.2 5.2 855.4 2.4 MD_12 863.2 862.9 MD_13 pond 876.0 879.2 3.2 876.7 0.7 MD_14 street 861.5 861.1 MD_15 pond 859.8 864.4 4.6 863.7 3.9 MD_16 871.8 871.7 MD_17 862.0 861.7 MD_18 878.1 876.0 MD_19 889.2 888.3 MD_2 pond 854.0 858.2 4.2 854.5 0.5 MD_20 905.6 905.4 MD_21 pond 889.8 891.5 1.7 890.7 0.9 MD_22 byd 916.8 915.7 MD_23 byd 919.2 917.9 MD_24 byd 915.4 913.7 MD_25 pond 910.0 916.2 6.2 912.0 2.0 MD_26 931.2 931.1 MD_27 street/yd 916.2 914.5 MD_28 pond 936.0 939.3 3.3 938.4 2.4 MD_29 pond 935.0 938.5 3.5 937.7 2.7 MD_3 pond 854.0 858.5 4.5 856.4 2.4 MD_30 byd 940.7 940.2 MD_31 street 918.9 918.4 MD_32 byd 921.0 920.7 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 MD_33 928.0 927.8 MD_34 932.0 931.4 MD_35 street 937.3 936.7 MD_36 street 861.3 858.6 MD_37 street 863.3 863.2 MD_38 byd 865.0 863.9 MD_39 pond 935.5 939.1 3.6 938.0 2.5 MD_4 creek 860.8 860.6 MD_40 street/field 879.4 879.0 MD_41 street 865.3 865.0 MD_42 888.9 888.6 MD_43 932.6 932.3 MD_44 918.9 917.3 MD_45 922.6 922.2 MD_46 ditch 873.0 869.3 MD_47 885.4 879.9 MD_48 939.3 938.6 MD_48a street/yd 939.2 938.3 MD_49 857.7 857.3 MD_5 867.1 864.1 MD_50 wetland 850.0 858.2 8.2 855.4 5.4 MD_6 street 863.8 863.6 MD_7 pond 859.0 862.5 3.5 860.1 1.1 MD_8 865.7 865.1 MD_9 862.2 860.8 ML_1 pond 908.5 911.5 3.0 909.7 1.2 ML_10 929.7 929.4 ML_11 street 931.1 929.2 ML_12 street 941.3 937.4 ML_12a 935.9 934.4 ML_13 park 931.1 930.1 ML_14 942.9 941.0 ML_15 pond 939.5 940.9 1.4 937.4 -2.1 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 ML_16 pond 936.8 940.8 4.0 938.5 1.7 ML_17 street 942.0 941.1 ML_18 914.5 913.8 ML_19 byd 938.2 935.3 ML_2 pond 908.4 914.5 6.1 911.6 3.2 ML_20 937.4 937.2 ML_21 street/byd 941.4 939.6 ML_22 941.4 940.7 ML_23 934.3 932.8 ML_24 914.3 911.8 ML_25 914.3 912.1 ML_26 pond 939.1** 941.3 2.2 939.4 0.3 ML_27 pond 948.1 953.2 5.1 952.1 4.0 ML_28 pond 935.1** 939.0 ¹ 3.9 937.2 2.1 ML_29 byd 936.4 936.1 ML_29a byd 936.4 936.0 ML_3 pond 941.2 943.8 2.6 942.5 1.3 ML_30 941.3 940.9 ML_31 depression 916.2 914.6 ML_32 pond 908.4 914.5 6.1 911.6 3.2 ML_33 945.6 942.8 ML_34n byd 943.2 943.1 ML_34s byd 944.1 943.7 ML_35 street 940.0 939.5 ML_38 pond 916.1 919.1 3.0 916.7 0.6 ML_4 street 945.9 940.6 ML_40 pond 916.1 918.7 2.6 916.6 0.5 ML_5 923.1 919.8 ML_6 pond 939.7 942.7 3.0 941.2 1.5 ML_7 byd 932.3 931.2 ML_8 911.5 909.7 ML_9 depression 969.2 968.3 N16 916.8 916.3 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 N20 866.8 866.2 N25 863.4 863.1 N265 872.7 871.3 N32 949.2 949.1 N5 920.3 920.2 N6 928.4 928.1 N76 863.5 863.5 N92 913.5 909.4 NMN_10 866.7 866.5 NMN_11 street 862.5 861.1 NMN_13 873.3 864.6 NMN_14 868.9 868.5 NMN_15 street 866.5 865.5 NMN_16 869.1 868.6 NMN_17 860.2 859.7 NMN_18 street 862.3 860.2 NMN_19 876.4 876.0 NMN_20 ditch 884.9 884.3 NMN_21 890.3 888.5 NMN_22 882.7 882.2 NMN_23 byd 874.8 874.1 NMN_24 pond 885.0 888.9 3.9 888.5 3.5 NMN_25 891.3 891.0 NMN_26 867.0 866.8 NMN_27 pond 891.0 896.4 5.4 896.1 5.1 NMN_28 875.2 873.3 NMN_29 891.9 891.5 NMN_3 street 866.4 862.0 NMN_31 street 879.3 878.0 NMN_32 hwy ditch 907.6 907.3 NMN_33 882.6 882.4 NMN_34 905.4 905.3 NMN_35 869.6 868.7 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMN_36 871.9 871.5 NMN_37 street 872.3 871.8 NMN_38 877.5 877.0 NMN_39 882.9 882.7 NMN_40 895.9 890.5 NMN_41 street 878.0 877.3 NMN_42 878.8 878.1 NMN_43 883.3 883.0 NMN_44 880.6 880.2 NMN_45 884.0 883.9 NMN_46 880.8 880.6 NMN_47 879.7 879.5 NMN_48 creek 878.9 874.4 NMN_49 creek 879.1 874.3 NMN_50 pond 895.4** 898.6 ¹ 3.2 896.9 1.5 NMN_51 cul-de-sac 871.8 869.0 NMN_52 874.7 872.0 NMN_53 920.1 917.6 NMN_54 hwy ditch 901.2 900.5 NMN_55 pond 909.0 909.1 0.1 907.3 -1.7 NMN_56 street/ditch 866.5 864.7 NMN_57 863.7 861.0 NMN_58 street 891.3 891.2 NMN_59 hwy ditch 908.1 907.2 NMN_60 creek 878.5 874.2 NMN_61 street 883.5 882.0 NMN_62a cul-de-sac 910.4 905.0 NMN_62b 924.0 915.6 NMN_62c pond 884.2 891.1 6.9 889.8 5.6 NMN_62d depression 891.0 890.2 NMN_62e pond 885.8 890.8 5.0 889.3 3.5 NMN_62f 919.2 919.0 NMN_63a 930.5 930.3 Table 5.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMN_63b pond 920.4 921.4 1.0 921.1 0.7 NMN_63c byd 910.9 910.2 NMN_64 street 880.7 880.4 NMN_65 892.4 890.1 NMN_66 939.6 939.3 NMN_67 893.3 892.9 NMN_68 byd 949.8 949.7 NMN_7 892.8 892.5 NMN_70 street 952.3 950.9 NMN_71 961.7 961.5 NMN_72 954.3 951.2 NMN_73 basin 878.6 877.0 NMN_74 basin 905.7 ¹ 903.7 NMN_75 pond 912.7 914.7 2.0 914.0 1.3 NMN_76 pond 905.3 908.1 2.8 905.6 0.3 NMN_77 pond 916.4 918.4 2.0 917.9 1.5 NMN_78 970.7 966.9 NMN_8 868.1 867.8 NMN_80 940.2 936.4 NMN_81 byd 977.5 977.4 NMN_82 975.6 975.5 NMN_83 980.4 978.5 NMN_84 pond 917.6 919.3 1.7 919.1 1.5 NMN_85 946.1 945.8 NMN_9 byd 866.6 866.2 NMN_90 street 874.8 873.9 Node271 866.5 864.7 £¤212 £¤169 100 4567158 Vernon Ave Blake Rd Tracy Ave Interlachen Blvd Olinger Rd Gleason Rd Schaefer Rd MudLake MirrorLake HighlandsLake HawkesLake HopkinsHopkins MinnetonkaMinnetonka Eden PrairieEden Prairie Saint Louis ParkSaint Louis Park North Bran c h Nine MileCreek EdCrk3 ML_1 HI_1 MD_50 HI_10 EdCrk5 MD_1 HL_1 HI_13 NMN_38 NMN_60 HI_18 EdCrk7 HI_20 HL_11w HL_40 HI_12 HL_8 MD_27 HL_47 NMN_32 HL_39 HL_29 ML_21 EdCrk1 ML_2 MD_4 HI_4 ML_31 NMN_19 NMN_50 ML_18 MD_2 MD_48a ML_40 MD_12 HL_36 HI_6 ML_28 HL_12MD_20 NMN_64 HL_21 MD_8 MD_13 HI_15 NMN_75 HL_50 HI_3 HL_42 HI_8 MD_29 HI_9 ML_15 HI_5 HI_16 ML_30 MD_40 NMN_37 NMN_7 ML_8 NMN_43 MD_42 HI_7 ML_13 MD_7 HL_26 NMN_9 NMN_42 MD_21 HL_3 NMN_20 MD_43NMN_76 HL_9 MD_14 ML_16 ML_38 MD_41 NMN_73 EdCrk2 MD_25 MD_3 MD_45 NMN_41 NMN_36 HL_31 ML_26 ML_35 HL_45 HL_2 HI_17 MD_6 HL_4 MD_11 ML_10 MD_46 NMN_80 MD_15 MD_17 NMN_62b NMN_66 MD_22 MD_48 NMN_77 MD_39 NMN_85 NMN_33 HL_28 HL_29b NMN_72 MD_28 NMN_28 ML_19 ML_20 HI_14 MD_9 HL_43 HI_19 EdCrk6 MD_19 HL_16 MD_16 MD_49 MD_32NMN_44 HL_48 HL_37HL_7 HL_20 MD_35 HL_14 HL_23 ML_5 HL_11e HL_33 NMN_35 ML_34s NMN_13 ML_6 NMN_58 ML_32 NMN_15 NMN_55 ML_34n ML_9 HL_18 ML_22 ML_27 NMN_47 HL_10 HL_44 NMN_67 NMN_82 ML_17 MD_36 NMN_61 NMN_39 NMN_56 NMN_8 MD_38 HI_7a HI_2NMN_84 MD_31 NMN_78 MD_47 NMN_71 NMN_26 HL_35 HL_49 ML_25 HL_6 EdCrk7c HI_11 NMN_18 ML_29 NMN_65 NMN_14 NMN_24 NMN_62e NMN_70 NMN_31 HL_46 NMN_23 NMN_40 HI_21 MD_24 MD_34 NMN_62c NMN_59 NMN_63b NMN_74 HL_30 MD_37 MD_26 ML_7 MD_33 ML_12 HI_22 NMN_16 NMN_90 NMN_57 NMN_83 NMN_17 NMN_45 NMN_34 HL_25 HL_5 MD_18 HL_13 ML_24 HL_11c NMN_63a MD_23 NMN_27 ML_4 ML_29a NMN_46 NMN_10 NMN_54 NMN_63c ML_11 NMN_68 MD_30 HL_41 HL_34 MD_5 NMN_81 ML_12a ML_3 HL_17 MD_44 HL_27 NMN_3 HL_19 NMN_62d HL_32 MD_10 ML_23 ML_14 NMN_11 HL_15 HL_38 NMN_49 HL_46a ML_33 NMN_51 NMN_62a NMN_25 NMN_53 NMN_22 HL_35a NMN_29NMN_21 NMN_62f NMN_48 NMN_52 HL_29a Barr Footer: ArcGIS 10.4.1, 2017-09-21 08:58 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_5_1_NMC_North_Drainage_Basins.mxd User: EMANINE MILE CREEK - NORTH DRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 5.1 0 1,200 Feet !;N Nine Mile Creek - NorthDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 £¤212 £¤169 100 4567158 Vernon Ave Blake Rd Tracy Ave Interlachen Blvd Olinger Rd Gleason Rd Schaefer Rd MudLake MirrorLake HighlandsLake HawkesLakeNine Mile North Mud Lake Mirror Lake Hawkes Lake Highlands Lake HopkinsHopkins MinnetonkaMinnetonka Eden PrairieEden Prairie Saint Louis ParkSaint Louis Park North Bran c h Nine MileCreek Barr Footer: ArcGIS 10.4.1, 2017-09-21 09:02 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_5_2_NMC_North_Major_Watersheds.mxd User: EMANINE MILE CREEK - NORTH MAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 5.2 0 1,200 Feet !;N Nine Mile Creek - NorthDrainage Basin Major Watershed Hawkes Lake Highlands Lake Mirror Lake Mud Lake Nine Mile North Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 City of Edina 2018 Comprehensive Water Resources Management Plan 5-33 Figure 5.3 Nine Mile Creek—North Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. Nine M il e Creek HopkinsHopkins MinnetonkaMinnetonka Eden PrairieEden Prairie St. Louis ParkSt. Louis Park ML_1 MD_50 MD_1 HI_1 HL_1 MD_4 ML_16 MD_25 HI_13 MD_1 MD_50 ML_28 HL_44 ML_15 NMN_50 MD_2 ML_2 HI_18 HL_28 MD_21 NMN_75 ML_32 NMN_76 HI_5 MD_13 HI_20 ML_40 MD_2 MD_4 ML_26 MD_3MD_2 NMN_77 NMN_62 MD_11 HL_9 HL_50 HL_39 NMN_24 MD_7 HL_40 ML_38 MD_15 NMN_55 HL_24 ML_19 MD_28 HL_13 NMN_27 MD_2 NMN_84 MD_29 HI_17 NMN_20 NMN_63 HL_25 NMN_73 MD_39 ML_6 HI_21 HI_22 NMN_74 ML_3 ML_27 NMN_49 NMN_48 Barr Footer: ArcGIS 10.4.1, 2017-09-21 07:57 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_5_4_NMC_North_Water_Quality.mxd User: rcs2NINE MILE CREEK NORTHWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 5.4 1,200 0 1,200Feet !;N 400 0 400Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Area Draining Directly to the NorthFork of Nine Mile Creek Flow Direction Imagery Source: USDA 2016 NAIP via MnGeo City of Edina 2018 Comprehensive Water Resources Management Plan 6-1 6.0 Nine Mile Creek—Central 6.1 General Description of Drainage Area Figure 6.1 depicts the Nine Mile Creek—Central drainage basin. The Nine Mile Creek—Central drainage basin is located in the central portion of Edina and encompasses 1,236 acres that ultimately drain to the stretch of the North Fork of Nine Mile Creek between TH 62 and West 70th Street. 6.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ponding basins, drainage ditches, and overland flow paths. The Nine Mile Creek—Central drainage basin has been divided into three major watersheds based on the drainage patterns. These major watersheds are depicted in Figure 6.2. Each major watershed has been further delineated into many subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located Table 6.1 lists each major watershed and the associated subwatershed naming convention. Table 6.1 Major Watersheds within the Nine Mile Creek—Central Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Colonial Ponds CO_## 13 115 Indian Pond IP_## 4 24 Nine Mile Central NMC_## 129 1097 6.1.1.1 Colonial Ponds The Colonial Ponds watershed is located in central Edina and encompasses approximately 115 acres. The watershed is bordered by TH 62 to the south, Villa Lane on the west, extends northward to Benton Avenue, and slightly eastward past Westridge Boulevard. Six stormwater detention ponds are located within the watershed. The most downstream detention basin is located just south of the Colonial Church (subwatershed CO_1) and outlets to the North Fork of Nine Mile Creek via a 48-inch culvert under TH 62. The land use within the watershed is primarily residential, with the exception of the Colonial Church property and adjacent Countryside Park. 6.1.1.2 Indian Pond The Indian Pond watershed is located in central Edina, southwest of Creek Valley Elementary School. The 24-acre watershed is characterized by a single storm sewer system that drains to Indian Pond. Indian Pond is a land-locked basin. In the unlikely event of overflow from this pond, which would occur at an approximate elevation of 897 feet, the overflow would discharge to the intersection of Indian Hills Pass and Cherokee Trail. It would then be picked up by the Gleason Road storm sewer system and eventually City of Edina 2018 Comprehensive Water Resources Management Plan 6-2 discharge to the North Fork of Nine Mile Creek, just northwest of the Edina High School complex. The land use within the Indian Pond watershed is low-density residential. 6.1.1.3 Nine Mile Central The Nine Mile Central watershed is also located in central Edina and spans approximately 1,097 acres. Stormwater within the watershed drains to the North Fork of Nine Mile Creek between TH 62 and West 70th Street via a network of ponding basins and storm sewer. The watershed extends north to the intersection of Hansen Road and West 56th Street and includes the area north of TH 62 that drains to the storm sewer system along the Soo Line railroad. The Soo Line storm sewer system flows beneath TH 62 and eventually discharges to the creek near the intersection of Valley Lane and Limerick Lane. The watershed is bordered by West 70th Street on the south, Gleason Road on the west, and TH 100 on the east. There are five stormwater detention basins within the Nine Mile Central watershed. The watershed has been delineated into 129 subwatersheds, with land use characterized by residential areas, the Edina High School complex, freeway, several parks, the Soo Line Railroad, several ponding basins, and the floodplain of the North Fork of Nine Mile Creek. 6.2 Stormwater System Results 6.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Nine Mile Creek—Central drainage basin. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis Table 6.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses for the Nine Mile Creek—Central basin. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analyses for the Nine Mile Creek—Central drainage basin are summarized in Table 6.3. Figure 6.3 illustrates the results of the 10- and 1-percent-annual-chance hydraulic analyses. The figure depicts the Nine Mile Creek—Central drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood- prone areas identified in the modeling analyses. To evaluate the level of protection of the stormwater system within the Nine Mile Creek—Central drainage area, the 1-percent-annual-chance frequency flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 6.3. Discussion and recommended improvement considerations for these areas are included in Section 6.3. City of Edina 2018 Comprehensive Water Resources Management Plan 6-3 6.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 6.4 depicts the results of the water quality modeling for the Nine Mile Creek—Central drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 6.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 6.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Nine Mile Creek—Central drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for problem areas. These preliminary corrective measures are also discussed below. As the City evaluates flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Nine Mile Creek—Central drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done in those areas since 2003. City of Edina 2018 Comprehensive Water Resources Management Plan 6-4 6.3.1.1 Antrim Road and Chapel Drive (NMC_41) A depression exists in the backyards of the homes between Antrim Road and Erin Terrace, south of Chapel Drive. The backyard depression has a 12-inch CMP outlet that connects to the existing storm sewer system on Chapel Drive. Modeling results indicate that the 1-percent-annual-chance flood elevation (943.3 feet) in this area is determined by the 24-hour precipitation event and may exceed up to five low principle structure- elevations, based on LiDAR data and approximate building footprint information. The problem is caused by the limited capacity of the 12-inch pipe and the capacity of the surface overflow between homes (approximate elevation of 942.5 feet based on LiDAR). It is recommended that a survey of low house elevations be conducted at 5901 and 5905 Chapel Drive, and 6812–6820 Antrim Road to determine potential flood impacts. Flood-proofing measures on the individual properties could be considered for those that are demonstrated to be impacted. Additionally, the natural surface overflow north to Chapel Drive between 5901 and 5905 Chapel Drive should be maintained, and potentially lowered if feasible. Increasing the capacity of the outlet pipe is not recommended due to the long length of pipe (approximately 5,000 feet) between NMC_41 and the ultimate discharge, Nine Mile Creek. Increasing the capacity at any point may require increasing the capacity in all downstream pipes from that point. 6.3.1.2 Ridgeview Drive (NMC_106 and NMC_107) A depression exists in the backyards of the homes along Ridgeview Road, adjacent to the Soo Line railroad tracks south of West 66th Street. The backyard depression is not connected to a storm sewer pipe, but does have a private lift station in NMC_107. Modeling results indicate that the flood elevation from the 1-percent-annual-chance 24-hour storm event (846.0 in NMC_106 and 844.5 in NMC_107) may exceed the low house elevations of 10 principle structures, based on LiDAR data and approximate building footprints. The results of the 24-hour precipitation event and the 10-day snowmelt event are nearly identical. It is recommended that a survey of low house elevations be conducted at 6700–6716 Ridgeview Road and 6808–6824 Ridgeview Road to determine potential for flood impacts. This area was also identified as an area of concern in the 2003 and 2009 CWRMPs. The problem is due to the land-locked nature of these subwatersheds and the limited capacity of the private lift station. It is recommended that a gravity storm sewer system with a backflow preventer be installed that conveys stormwater from the backyard depression areas to Nine Mile Creek (on the other side of the railroad tracks). Finally, a storm sewer pipe could be added and connected to the existing storm sewer system at the intersection of Tifton Drive and Ridgeview Drive (upstream invert of existing system is approximately 840.7 feet). 6.3.1.3 West 66th Street and Naomi Drive (NMC_71, NMC_74, and NMC_103) During intense rainstorms, flooding problems have historically occurred at the low-lying intersection of West 66th Street and Naomi Drive. The backyard depression area in the rear of the homes on the east and west sides of Naomi Drive and Normandale Park have also been subject to flooding. Stormwater overflow from the West 66th Street and Naomi Drive intersection flows into the adjacent Normandale Park storage City of Edina 2018 Comprehensive Water Resources Management Plan 6-5 area (ball field). The intersection and ball field are eventually drained by a 33-inch trunk storm sewer system that flows northwest to the low area along Warren Avenue and, eventually, west to the North Fork of Nine Mile Creek. Modeling results indicate that the 1-percent-annual-chance flood elevation (863.9 feet in NMC_103 and 863.8 feet in NMC_71 and NMC_74) exceeds the low house elevation of up to nine principle structures (6600 and 6604 Naomi Drive, 6605–6617 Naomi Drive, 6608 and 6612 Kenney Place, and 5177 West 66th Street). The backyard depression area behind the Naomi Drive homes is drained by a 15-inch culvert that connects to the 15-inch pipe heading north from Circle Drive Pond. During periods of intense rainfall, the water in this system backs up and flows south into Circle Drive Pond. A flap gate has been installed on the culvert draining the backyard depression area to prevent backflow from inundating the area. However, with the flap gate closed, there is no outlet from this area and the backyard storage volume is not sufficient to prevent flooding of the structures along Naomi Drive. This flooding problem has been analyzed in the past and recommendations to alleviate the flooding were made, in which case some were implemented. The recommendations to add additional outlet capacity to the backyard depression area via a pumped outlet to the Normandale Park storage area or a separate gravity system flowing west to the North Fork of Nine Mile Creek, have not been implemented but should be considered further. If the recommendation to install a gravity outlet under the railroad tracks from NMC_106 and NMC_107 is implemented, additional storm sewer could be installed to connect this area to NMC_106. If a pumped outlet is installed to drain the backyard area, it will be necessary to add additional storage capacity in Normandale Park. 6.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the annual removal of total phosphorus from several ponds in the Nine Mile Creek—Central drainage area was predicted to be below the desired rate of 60 percent. For those ponds with total phosphorus removal below 60 percent, the permanent pool storage volume was analyzed to determine whether additional capacity was necessary. Based on the MPCA-recommended permanent pool storage volume for detention basins, all of the basins were found to have sufficient dead storage volume. As a result, no specific recommendations for water quality basin upgrades in the Nine Mile Creek—Central drainage basin are being made at this time. Construction of new or expansion of existing water quality basins is one way to increase pollutant removal prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. Table 6.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - Central Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) CO_1 16.8 46 133 9.1 3.2 10.1 66 4.8 CO_10 4.9 29 43 2.3 0.9 2.9 21 1.1 CO_11 3.0 25 31 1.3 0.6 1.8 16 0.6 CO_12 6.6 23 56 3.4 1.3 4.0 28 1.8 CO_13 23.0 25 129 10.2 4.3 13.8 55 4.9 CO_2 5.9 38 47 3.3 1.1 3.5 24 1.8 CO_3 0.5 50 5 0.2 0.1 0.3 3 0.1 CO_4 8.2 23 45 3.9 1.5 4.9 20 1.9 CO_5 7.5 32 38 4.0 1.4 4.5 18 2.1 CO_6 13.7 25 93 6.6 2.6 8.2 43 3.3 CO_7 5.3 32 54 2.5 1.0 3.2 28 1.2 CO_8 8.5 25 72 3.8 1.6 5.1 34 1.8 CO_9 11.0 25 82 4.9 2.1 6.6 37 2.3 IP_1 5.8 34 52 2.4 1.1 3.4 22 1.1 IP_2 11.7 21 89 4.4 2.2 7.0 33 1.9 IP_3 4.2 25 39 1.7 0.8 2.5 16 0.7 IP_4 1.9 24 17 0.7 0.4 1.1 7 0.3 NMC_10 8.7 28 78 4.1 1.6 5.2 38 2.0 NMC_100 9.4 25 64 4.2 1.8 5.6 28 2.0 NMC_101 30.8 25 199 14.1 5.8 18.5 88 6.8 NMC_102 1.2 25 12 0.6 0.2 0.7 7 0.3 NMC_103 4.1 25 38 2.0 0.8 2.5 19 1.0 NMC_104 24.3 65 270 14.1 4.6 14.6 146 7.8 NMC_105 2.9 47 33 1.6 0.5 1.7 18 0.9 NMC_106 3.3 24 31 1.6 0.6 2.0 16 0.8 NMC_107 1.6 24 16 0.7 0.3 0.9 8 0.4 NMC_108 7.8 25 51 3.4 1.5 4.6 22 1.6 NMC_109 1.5 26 13 0.6 0.3 0.9 5 0.3 NMC_11 7.7 20 70 2.9 1.5 4.6 29 1.3 NMC_110e 6.2 25 64 2.8 1.2 3.7 33 1.3 NMC_110n 8.2 25 74 3.7 1.6 4.9 36 1.8 NMC_110w 3.2 25 34 1.4 0.6 1.9 18 0.7 NMC_111 11.7 25 97 5.3 2.2 7.0 46 2.6 NMC_112 9.3 51 89 4.8 1.8 5.6 45 2.5 NMC_113a 7.1 24 62 3.3 1.4 4.3 31 1.6 NMC_113b 4.9 23 47 2.3 0.9 3.0 24 1.1 NMC_113BP 2.0 4 12 0.9 0.4 1.2 6 0.5 NMC_113c 4.2 24 34 1.9 0.8 2.5 16 0.9 NMC_113d 2.8 25 18 1.2 0.5 1.7 8 0.6 NMC_113e 4.0 24 34 1.8 0.8 2.4 16 0.9 NMC_113f 5.2 23 47 2.3 1.0 3.1 23 1.1 NMC_114 2.8 60 29 1.5 0.5 1.7 15 0.8 NMC_115 16.3 24 125 7.3 3.1 9.8 57 3.5 NMC_116 10.2 25 77 4.6 1.9 6.1 35 2.2 NMC_117 41.8 25 304 18.8 7.9 25.1 137 9.0 NMC_117a 19.4 24 118 8.5 3.7 11.6 50 4.0 NMC_118 11.3 22 79 5.3 2.1 6.8 37 2.6 NMC_119 2.4 23 26 1.1 0.5 1.4 14 0.5 NMC_12 8.7 26 42 3.8 1.6 5.2 18 1.8 NMC_120 8.0 26 58 4.3 1.5 4.8 29 2.3 NMC_121 1.7 25 16 0.8 0.3 1.0 8 0.4 NMC_122 27.3 25 172 12.1 5.2 16.4 74 5.7 NMC_13 3.0 30 31 1.6 0.6 1.8 16 0.8 NMC_14 3.6 25 24 1.7 0.7 2.1 11 0.8 NMC_15 0.7 36 8 0.3 0.1 0.4 4 0.2 NMC_16 8.4 25 48 3.5 1.6 5.0 19 1.6 NMC_17 7.5 24 64 3.3 1.4 4.5 30 1.6 NMC_18 1.7 25 17 0.7 0.3 1.0 8 0.3 NMC_19 5.5 25 49 2.2 1.0 3.3 21 1.0 NMC_20 3.2 36 29 1.5 0.6 1.9 15 0.8 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 6.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - Central Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NMC_21 2.3 28 17 0.9 0.4 1.4 6 0.4 NMC_22 4.1 27 38 1.9 0.8 2.5 19 0.9 NMC_23 5.8 25 56 2.6 1.1 3.5 28 1.3 NMC_24 7.3 25 47 3.2 1.4 4.4 20 1.5 NMC_25 1.8 26 18 0.8 0.3 1.1 9 0.4 NMC_26 4.4 29 37 2.0 0.8 2.6 18 1.0 NMC_27 5.5 25 42 2.5 1.1 3.3 19 1.2 NMC_28 8.2 63 46 4.6 1.5 4.9 22 2.5 NMC_29 9.6 24 45 4.1 1.8 5.7 18 1.9 NMC_30 19.3 25 127 8.5 3.7 11.6 55 4.0 NMC_31 2.1 25 21 0.9 0.4 1.2 11 0.4 NMC_32 12.0 29 68 5.4 2.3 7.2 29 2.6 NMC_34 2.1 25 22 0.9 0.4 1.2 11 0.4 NMC_35 5.4 25 46 2.6 1.0 3.2 23 1.3 NMC_36 5.6 25 50 2.5 1.1 3.4 24 1.2 NMC_37 1.8 25 19 0.8 0.3 1.1 10 0.4 NMC_38 2.8 25 23 1.2 0.5 1.7 11 0.6 NMC_39 12.7 25 81 5.6 2.4 7.6 35 2.7 NMC_4 2.0 25 19 0.8 0.4 1.2 9 0.3 NMC_40 2.2 25 24 1.1 0.4 1.3 13 0.6 NMC_41 6.4 25 51 2.9 1.2 3.8 24 1.4 NMC_42 10.1 27 74 4.5 1.9 6.1 33 2.2 NMC_43 2.8 25 27 1.3 0.5 1.7 14 0.6 NMC_44 4.0 43 36 2.0 0.8 2.4 18 1.0 NMC_45 5.6 25 63 2.6 1.1 3.4 34 1.3 NMC_46 24.8 30 171 11.3 4.7 14.9 75 5.5 NMC_47 3.4 30 37 1.6 0.6 2.0 20 0.8 NMC_48 0.8 57 9 0.4 0.2 0.5 5 0.2 NMC_49 8.5 25 68 3.8 1.6 5.1 31 1.8 NMC_5 4.0 29 33 1.8 0.8 2.4 16 0.9 NMC_50 10.6 25 76 4.7 2.0 6.3 34 2.2 NMC_51 9.7 25 73 4.3 1.8 5.8 33 2.1 NMC_52 9.7 25 73 4.4 1.8 5.8 34 2.1 NMC_53 2.2 25 13 1.0 0.4 1.3 6 0.5 NMC_54 10.1 25 78 4.7 1.9 6.1 37 2.3 NMC_55 8.8 25 59 3.9 1.7 5.3 26 1.9 NMC_56 11.2 25 92 5.1 2.1 6.7 44 2.5 NMC_57 5.8 24 37 2.6 1.1 3.5 16 1.2 NMC_58 4.3 25 36 1.9 0.8 2.6 17 0.9 NMC_59 1.1 25 13 0.5 0.2 0.7 7 0.2 NMC_6 3.9 27 32 1.6 0.7 2.3 14 0.7 NMC_60 5.2 21 41 2.9 1.0 3.1 21 1.5 NMC_61 6.4 25 52 3.1 1.2 3.8 26 1.6 NMC_62 13.2 25 90 6.3 2.5 7.9 42 3.1 NMC_63 8.5 25 66 3.8 1.6 5.1 31 1.8 NMC_64 3.6 24 34 1.6 0.7 2.1 17 0.8 NMC_65 8.1 24 64 3.8 1.5 4.8 31 1.9 NMC_66 8.1 25 58 3.6 1.5 4.8 26 1.7 NMC_67 6.5 25 65 3.0 1.2 3.9 33 1.5 NMC_68 3.3 25 29 1.5 0.6 1.9 14 0.7 NMC_69 6.6 25 58 3.0 1.3 4.0 28 1.4 NMC_7 13.2 25 103 6.2 2.5 7.9 50 3.1 NMC_70 7.8 33 65 3.9 1.5 4.7 32 2.0 NMC_71 6.4 25 49 3.0 1.2 3.8 23 1.4 NMC_72 1.0 25 11 0.5 0.2 0.6 6 0.2 NMC_73 3.3 25 28 1.5 0.6 2.0 14 0.7 NMC_74 8.0 21 48 3.7 1.5 4.8 21 1.8 NMC_75 6.4 25 51 2.9 1.2 3.9 23 1.4 NMC_76 1.9 25 18 0.9 0.4 1.2 9 0.4 NMC_77 13.8 37 111 6.5 2.6 8.3 52 3.2 Table 6.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - Central Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NMC_78 4.6 25 41 2.0 0.9 2.7 20 1.0 NMC_79 0.4 24 5 0.2 0.1 0.2 3 0.1 NMC_80 2.2 24 20 1.0 0.4 1.3 10 0.5 NMC_81 3.0 32 23 1.4 0.6 1.8 10 0.7 NMC_82 2.9 25 25 1.3 0.5 1.7 12 0.6 NMC_83 3.7 26 35 1.7 0.7 2.2 18 0.8 NMC_84 6.9 31 54 3.4 1.3 4.1 26 1.7 NMC_85 2.0 25 21 1.0 0.4 1.2 11 0.5 NMC_86 9.5 26 75 4.5 1.8 5.7 36 2.2 NMC_87 1.1 65 13 0.6 0.2 0.7 7 0.4 NMC_88 1.8 50 22 0.9 0.3 1.1 13 0.5 NMC_89 9.0 58 99 4.7 1.7 5.4 52 2.4 NMC_9 1.7 34 18 0.9 0.3 1.0 9 0.5 NMC_90 14.3 25 117 6.8 2.7 8.6 57 3.4 NMC_91 5.2 25 34 2.4 1.0 3.1 15 1.2 NMC_92 2.1 65 23 1.2 0.4 1.3 13 0.7 NMC_93 2.0 65 22 1.1 0.4 1.2 12 0.6 NMC_94 6.6 65 68 3.6 1.3 4.0 35 1.9 NMC_95 7.0 25 59 3.1 1.3 4.2 28 1.5 NMC_96 15.6 25 118 7.1 3.0 9.4 54 3.4 NMC_97 6.1 25 52 2.7 1.2 3.7 25 1.3 NMC_98 7.5 25 66 3.5 1.4 4.5 33 1.7 NMC_99 4.2 25 38 1.9 0.8 2.5 19 0.9 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 100 878.7 877.4 301 883.3 882.9 305 879.1 878.7 307 865.4 864.5 308 864.9 863.6 310 856.6 856.0 327 856.1 855.8 329 858.7 858.3 332 866.2 865.8 335 869.5 869.3 336 872.8 871.6 338 879.0 878.6 340 885.2 884.7 341 887.1 885.8 343 888.3 886.6 348 885.0 884.6 349 891.2 891.0 350 896.2 896.0 351 910.2 910.0 352 911.5 911.3 354 913.5 913.2 356 914.3 914.1 357 915.5 915.3 359 920.6 920.4 369 857.9 857.5 371 865.5 865.2 373 873.3 873.1 374 888.9 888.7 375 893.4 893.2 378 876.9 876.8 379 875.5 875.4 380 875.5 875.3 382 863.6 863.4 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 384 863.6 863.4 385 862.0 860.8 386 862.0 860.7 392 851.8 851.2 393 846.9 845.4 396 852.3 850.6 397 854.8 853.1 398 858.9 857.2 399 862.8 860.4 401 866.7 863.3 402 866.5 863.3 403 866.5 863.3 405 866.5 863.5 406 866.5 863.6 409 863.9 861.8 410 863.9 860.5 411 864.2 860.7 412 864.5 860.8 416 893.6 893.0 417 861.3 859.6 418 852.5 850.7 420 894.4 894.0 421 903.1 903.0 425 867.0 866.7 426 871.6 870.5 427 874.1 872.7 428 875.3 872.9 430 877.7 876.8 431 880.1 880.0 433 886.0 885.9 435 851.3 849.4 438 854.8 852.6 440 863.8 860.1 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 443 863.8 862.7 445 905.3 904.9 454 905.1 903.5 458 905.0 903.4 459 902.7 901.2 460 899.5 898.3 463 919.9 919.4 466 941.6 941.3 468 938.7 936.8 472 922.0 921.5 475 918.8 918.2 476 918.4 916.7 477 918.0 915.0 479 908.6 908.1 480 895.6 895.0 482 896.2 895.8 483 905.4 905.3 488 840.2 837.7 492 875.9 873.1 493 869.9 869.6 494 867.1 866.5 496 854.3 853.2 499 843.2 842.9 501 839.0 838.6 526 892.9 891.6 527 892.8 890.3 528 892.8 890.0 663 905.1 904.3 1609 874.5 874.4 1826 886.0 885.8 1827 899.7 898.3 1828 908.0 903.8 1915 868.2 867.3 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1918 922.3 921.8 1919 922.0 921.7 1921 906.2 906.1 1923 909.3 909.0 1926 941.6 941.3 1927 941.4 941.2 1929 927.2 927.1 1930 940.3 940.2 1935 888.8 888.2 1936 888.8 888.2 1941 846.5 846.4 2072 871.6 871.3 2086 922.1 917.6 2088 951.5 945.9 2271 883.8 883.6 2272 896.9 896.7 2429 850.6 848.5 2431 863.8 862.6 2432 878.5 878.2 2433 887.1 884.0 2434 889.1 886.6 2556 896.1 894.7 2559 886.9 886.4 2560 884.4 883.9 2561 877.4 877.0 2563 861.6 861.2 2565 851.5 850.7 2566 850.5 850.0 2569 854.9 854.5 2570 parking lot 854.9 854.5 2579 905.1 904.0 2580 905.1 903.6 2921 857.1 857.0 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2922 857.1 857.0 2923 857.1 857.0 2924 857.2 857.0 7269 915.1 911.2 7271 906.5 904.4 CBMH_131 904.6 904.2 CBMH_132 905.0 904.7 CBMH_136 904.5 904.3 CBMH_138 904.5 904.3 CO_1 pond 845.7 854.5 8.8 850.7 5.0 CO_10 parking lot 855.1 854.3 CO_11 street 857.8 857.1 CO_12 street/lot 854.9 854.5 CO_13 892.8 892.4 CO_2 pond 849.3 854.5 5.2 850.8 1.5 CO_3 pond 848.5 855.2 6.7 851.8 3.3 CO_4 pond 849.0 855.2 6.2 851.7 2.7 CO_5 pond 847.7** 854.5 6.8 850.8 3.1 CO_6 street 864.3 862.4 CO_7 pond 855.0 857.7 2.7 855.6 0.6 CO_8 890.5 890.0 CO_9 866.9 866.3 EdCrk10 creek 851.1 849.5 EdCrk11 846.0 845.2 EdCrk11a 849.6 848.3 EdCrk11b 849.2 848.1 EdCrk11c 848.4 847.4 EdCrk11c_1 847.8 847.1 EdCrk11c_2 847.4 846.6 EdCrk11c_3 847.3 846.6 EdCrk11d 846.7 845.9 EdCrk12 creek 844.5 844.0 EdCrk13 839.8 837.5 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 EdCrk13a 840.4 838.0 EdCrk13b 840.2 837.8 EdCrk13c 840.2 837.7 EdCrk13d 840.2 837.7 EdCrk13e 840.2 837.7 EdCrk14 834.6 832.6 EdCrk14a 836.6 834.4 EdCrk14b 834.6 832.8 EdCrk14c 834.6 832.7 EdCrk14d 834.6 832.6 EdCrk8 853.5 851.1 EdCrk8a 853.9 852.0 EdCrk8b 853.7 851.7 EdCrk9 creek 853.5 850.7 IP_1 pond 880.3** 890.5 ¹ 10.2 883.6 3.3 IP_2 street 894.0 892.5 IP_3 892.8 889.9 IP_4 byd 888.8 ¹ 886.0 N302 837.6 837.4 N310 862.2 861.5 N312 888.8 888.2 N315 860.1 860.0 NMC_10 859.4 859.2 NMC_100 street 847.4 847.0 NMC_101 841.3 841.0 NMC_102 byd 853.1 851.1 NMC_103 byd 863.9 860.5 NMC_104 860.6 860.1 NMC_105 hwy ditch 886.8 886.3 NMC_106 byd 846.0 845.8 NMC_107 byd 844.5 843.7 NMC_108 918.8 918.1 NMC_109 888.1 886.3 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMC_11 891.1 890.9 NMC_110e street/yard 904.5 904.0 NMC_110n street 905.4 905.2 NMC_110w street 904.5 904.3 NMC_111 street/byd 905.7 905.5 NMC_112 pond 901.0 905.0 4.0 904.2 3.2 NMC_113a byd 903.7 903.1 NMC_113b byd 905.0 903.4 NMC_113BP field 905.1 903.4 NMC_113c byd 903.3 902.4 NMC_113d 903.3 901.9 NMC_113e 893.0 892.0 NMC_113f 893.1 891.8 NMC_114 pond 900.0 905.1 5.1 903.5 3.5 NMC_115 street 905.1 903.4 NMC_116 byd 922.8 922.4 NMC_117 street 905.7 904.3 NMC_117a 917.0 915.4 NMC_118 park 872.1 870.5 NMC_119 byd 921.7 ¹ 919.5 NMC_12 889.2 887.5 NMC_120 street/yd 863.8 860.2 NMC_121 street 905.1 903.5 NMC_122 street 905.1 903.4 NMC_13 field/school 888.1 886.4 NMC_14 street 871.4 871.0 NMC_15 878.3 878.0 NMC_16 878.3 878.1 NMC_17 street 888.6 887.6 NMC_18 street 913.6 913.3 NMC_19 884.8 884.4 NMC_20 byd 853.1 851.4 NMC_21 cul-de-sac 922.6 922.4 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMC_22 941.1 941.0 NMC_23 street 857.3 857.1 NMC_24 910.4 910.0 NMC_25 street 941.6 941.3 NMC_26 929.4 928.7 NMC_27 922.2 921.9 NMC_28 hwy ditch 857.4 854.5 NMC_29 byd 922.8 922.4 NMC_30 942.0 941.5 NMC_31 912.1 912.0 NMC_32 880.6 880.2 NMC_34 935.4 935.3 NMC_35 street 870.7 870.3 NMC_36 street 907.5 907.4 NMC_37 938.3 936.1 NMC_38 971.4 967.8 NMC_39 917.8 913.9 NMC_4 912.4 912.0 NMC_40 cul-de-sac 841.9 841.0 NMC_41 byd 943.3 942.9 NMC_42 street 948.6 948.3 NMC_43 street 944.6 944.1 NMC_44 pond 940.8 944.6 3.8 942.9 2.1 NMC_45 street/yd 854.3 854.2 NMC_46 street/lot 904.3 904.1 NMC_47 street/lot 921.4 921.2 NMC_48 864.3 855.9 NMC_49 street 920.8 920.7 NMC_5 945.2 945.1 NMC_50 904.7 900.1 NMC_51 871.4 870.8 NMC_52 street 850.9 850.6 NMC_53 868.3 868.1 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMC_54 street 862.0 860.8 NMC_55 874.9 874.6 NMC_56 863.6 863.4 NMC_57 863.6 862.9 NMC_58 905.6 905.4 NMC_59 885.5 883.3 NMC_6 920.6 920.4 NMC_60 street 850.5 850.0 NMC_61 854.1 853.8 NMC_61$I 850.2 848.6 NMC_62 street 854.5 854.2 NMC_63 street 866.8 863.4 NMC_64 byd 863.4 861.9 NMC_65 street/yd 853.7 853.3 NMC_66 street/yd 859.4 859.0 NMC_67 street 872.1 871.4 NMC_68 885.6 885.5 NMC_69 906.1 906.0 NMC_69$I 898.6 898.6 NMC_7 866.2 865.2 NMC_70 pond 861.6 864.2 2.6 862.4 0.8 NMC_71 street 863.8 862.6 NMC_72 918.4 912.8 NMC_73 909.1 909.0 NMC_73$I 909.0 904.9 NMC_74 park 863.8 862.5 NMC_75 901.4 896.7 NMC_76 866.9 866.7 NMC_77 pond 857.5 861.3 3.8 859.6 2.1 NMC_78 street 903.2 902.5 NMC_79 864.3 862.7 NMC_80 byd 877.7 874.7 NMC_81 882.8 882.5 Table 6.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - Central Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMC_82 street 877.7 876.9 NMC_83 918.5 918.4 NMC_84 hwy ditch 863.8 861.0 NMC_85 street 872.8 872.1 NMC_86 street/yard 863.8 860.3 NMC_87 hwy ditch 857.4 856.3 NMC_88 890.5 889.8 NMC_89 918.2 917.9 NMC_9 byd 853.1 851.1 NMC_90 871.0 870.7 NMC_91 869.2 868.8 NMC_92 hwy ditch 857.4 853.6 NMC_93 hwy ditch 857.4 856.5 NMC_94 hwy ditch 857.4 854.5 NMC_95 street 836.6 836.1 NMC_96 845.7 845.4 NMC_97 837.8 837.5 NMC_98 840.0 839.4 NMC_99 878.1 877.9 Node393 899.5 897.9 Node394 896.3 895.4 £¤212 62 100 4567158 Gleason Rd Valley View Rd Hansen Rd Ridgeview Dr Valleyview Rd MudLake HawkesLake NorthBranchNine MileCreek NMC_3 NMC_1 NMC_117 CO_13 NMC_101 NMC_46 CO_1 NMC_122 NMC_104 IP_2 CO_6 NMC_30 CO_9 NMC_117a NMC_96 NMC_7 NMC_90 NMC_77 NMC_115 NMC_62 NMC_39 CO_8 NMC_32 CO_4 NMC_56 CO_5 NMC_111 NMC_50 IP_1 NMC_118 NMC_54 NMC_42 NMC_51 NMC_52 NMC_29 NMC_33 NMC_86 NMC_116 NMC_89 NMC_55 NMC_12 NMC_10 CO_2 NMC_49 NMC_63 NMC_16 NMC_112 NMC_100 CO_12 NMC_65 NMC_66 NMC_74 NMC_11 NMC_70 CO_7 IP_3 NMC_98 NMC_17 NMC_24 NMC_120 NMC_95 NMC_84 NMC_108 NMC_110n NMC_94 NMC_69 NMC_75 NMC_71 NMC_41 NMC_61 NMC_47 NMC_97 CO_10 NMC_57 NMC_36 NMC_45 NMC_27 NMC_35 NMC_60 NMC_91 NMC_5 NMC_78 NMC_6 NMC_26 NMC_58 NMC_99 NMC_22 NMC_44 NMC_83 NMC_14IP_4 NMC_68 NMC_13 NMC_81 NMC_82 NMC_38 NMC_114 NMC_53 NMC_85 NMC_28 NMC_67 NMC_23 NMC_113a NMC_19 NMC_110e NMC_113f NMC_113b CO_11 NMC_103 NMC_64 NMC_113c NMC_73 NMC_113e NMC_20 NMC_106NMC_43 NMC_105 NMC_110w NMC_21 NMC_4 NMC_113d NMC_40 NMC_80 NMC_119 NMC_92 NMC_31 NMC_34 NMC_93 NMC_76 NMC_9 NMC_88 NMC_25 NMC_37 NMC_18 NMC_121 NMC_113BP NMC_107 NMC_109 NMC_59 NMC_87 NMC_102 NMC_72 NMC_48NMC_15 CO_3 NMC_79 Barr Footer: ArcGIS 10.4.1, 2017-09-21 09:10 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_6_1_NMC_Central_Drainage_Basins.mxd User: EMANINE MILE CREEK - CENTRALDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 6.1 0 1,000 Feet !;N Nine Mile Creek - CentralDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 £¤212 62 100 4567158 Gleason Rd Valley View Rd Hansen Rd Ridgeview Dr Valleyview Rd MudLake HawkesLake Nine Mile Central Colonial Ponds Indian Pond NorthBranchNine MileCreek Barr Footer: ArcGIS 10.4.1, 2017-09-21 09:13 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_6_2_NMC_Central_Major_Watersheds.mxd User: EMANINE MILE CREEK - CENTRALMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 6.2 0 1,000 Feet !;N Nine Mile Creek - CentralDrainage Basin Major Watershed Colonial Ponds Indian Pond Nine Mile Central Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 City of Edina 2018 Comprehensive Water Resources Management Plan 6-21 Figure 6.3 Nine Mile Creek—Central Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. NMC_112 NMC_112 NMC_114 CO_7 CO_2 CO_5 IP_1 CO_3 CO_4 CO_1 NMC_70 NMC_77 NMC_44 N i n e M ile Creek Barr Footer: ArcGIS 10.4.1, 2017-09-21 07:57 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_5_4_NMC_North_Water_Quality.mxd User: rcs2NINE MILE CREEK CENTRALWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 6.4 1,200 0 1,200Feet !;N 400 0 400Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to the NorthFork of Nine Mile Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 7-1 7.0 Lake Cornelia/Lake Edina/Adam’s Hill 7.1 General Description of Drainage Area Figure 7.1 depicts the Lake Cornelia/Lake Edina/Adam’s Hill drainage basin. This drainage basin is located in the southeast portion of Edina and encompasses 1,477 acres. 7.1.1 Drainage Patterns This chapter discusses four major watersheds within the drainage basin: North Lake Cornelia, South Lake Cornelia, Lake Edina, and the Adam’s Hill Pond drainage area. These major watersheds are depicted in Figure 7.2. North and South Lake Cornelia ultimately drain to Lake Edina, which outlets into the North Fork of Nine Mile Creek. The Adam’s Hill drainage area includes those watersheds within the City of Edina that drain to the Adam’s Hill stormwater detention basin in Richfield. This drainage area was analyzed in conjunction with the North Cornelia watershed because the storm sewer systems draining to North Lake Cornelia and Adam’s Hill Pond are adjoined at the intersection of 69th Street and York Avenue. Each of the four major watersheds have been further delineated into numerous subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located. Table 7.1 lists each major watershed and the associated subwatershed naming convention. The stormwater system within these drainage basins comprises storm sewers, ponding basins, drainage ditches, and overland flow paths. Table 7.1 Major Watersheds within the Lake Cornelia/Lake Edina/Adam’s Hill Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Lake Cornelia—North NC_## 162 863 Lake Cornelia—South SC_## 9 112 Lake Edina LE_## 48 394 Adam's Hill (Richfield) AHR_## 20 108 7.1.1.1 North Cornelia North Lake Cornelia has a large watershed, encompassing 863 acres. The North Cornelia watershed has been delineated into 162 subwatersheds and is characterized by several ponding basins within the watershed. Land use within this watershed comprises a large commercial area (including the Southdale Shopping Center), portions of TH 62 and TH 100, residential areas (high and low density), parks, wetlands, and open water. The majority of the runoff from the highly impervious commercial area drains through the France Avenue and West 66th Street storm sewer system and discharges into the Point of France pond, located just northeast of the West 66th Street and Valley View Road intersection. The Point of France pond drains to the Swimming Pool Pond west of Valley View Road, which typically drains to North Lake Cornelia. During large storms, such as the 1-percent-annual-chance event, when North Lake Cornelia City of Edina 2018 Comprehensive Water Resources Management Plan 7-2 nears its capacity, the Swimming Pool Pond will flow northward through two 60-inch culverts located under TH 62 that connect the Swimming Pool Pond with the Brookview Pond, just north of TH 62. An outlet control structure on the north side of this pond allows flows to the north into Lake Pamela when the water elevation reaches 863.3 feet. North Lake Cornelia covers approximately 29 acres and serves as a recreation area for the City of Edina. The lake outlets to South Lake Cornelia through a 12-inch culvert beneath West 66th Street. 7.1.1.2 South Lake Cornelia The South Lake Cornelia watershed is located south of the North Lake Cornelia watershed. The 112-acre watershed comprises 9 subwatersheds, with two stormwater detention areas in addition to Lake Cornelia. The land use within the watershed is low-density residential and open water. South Lake Cornelia spans approximately 32 acres. The normal elevation of the lake is controlled by a weir structure at 859 feet. Discharge from South Cornelia flows southward through a 54-inch system for approximately 1,000 feet, where it connects with a 21-inch system at the intersection of Dunberry Lane and Cornelia Drive. This system ultimately drains to Lake Edina. During extreme storm events, such as the 1-percent-annual-chance event, the 21-inch pipe at Dunberry Lane and Cornelia Drive restricts flow, resulting in flow northward through the 54-inch system and into South Lake Cornelia. 7.1.1.3 Lake Edina The Lake Edina watershed is located south of the Lake Cornelia drainage basins. The watershed encompasses approximately 394 acres and has been delineated into 48 subwatersheds. Land use within the watershed is mainly low-density residential, with smaller portions of high density residential, commercial, institutional (Cornelia Elementary School), park, wetland, and open water. A wetland along the west side of Lake Edina, directly east of TH 100, receives runoff from an area of approximately 40 acres. Flow from this wetland discharges into Lake Edina via a weir structure and pipe system. Lake Edina spans an area of approximately 23 acres. The normal elevation of the lake is controlled by a weir structure at 822 feet. Discharge from Lake Edina flows through a 36-inch system underneath TH 100 and into the North Fork of Nine Mile Creek. 7.1.1.4 Adam’s Hill Pond The Adam’s Hill drainage area discussed in this analysis includes the 108-acre area within the City of Edina that drains to the Adam’s Hill Pond in Richfield. The outlet from Adam’s Hill Pond is a pumped outlet that discharges 10 cfs to Centennial Lakes. 7.2 Stormwater System Results 7.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Lake Cornelia/Lake Edina/Adam’s Hill drainage basins. The 10-percent-annual-chance analysis was based on a ½-hour storm City of Edina 2018 Comprehensive Water Resources Management Plan 7-3 with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis. Table 7.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analyses for the Lake Cornelia/Lake Edina/Adam’s Hill drainage areas are summarized in Table 7.3. Figure 7.3 illustrates the results of the 10- and 1-percent-annual-chance hydraulic analyses. The figure depicts the boundaries of the drainage areas, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 7.3 illustrates that several XP-SWMM nodes within the Lake Cornelia/Lake Edina/Adam’s Hill drainage areas are predicted to surcharge during both the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manhole and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the Lake Cornelia/Lake Edina/Adam’s Hill drainage areas, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 7.3. Discussion and recommended improvement considerations for these areas are included in Section 7.3. 7.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 7.4 depicts the results of the water quality modeling for the Lake Cornelia/Lake Edina/Adam’s Hill drainage areas. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 7.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options City of Edina 2018 Comprehensive Water Resources Management Plan 7-4 identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 7.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Lake Cornelia, Lake Edina, and Adam’s Hill drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for the problem areas. These preliminary corrective measures are also discussed below. As the City evaluates flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. The 2003 hydrologic and hydraulic modeling analyses identified several locations within the Lake Cornelia, Lake Edina, and Adam’s Hill drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done in those areas since 2003. 7.3.1.1 Valley View and Southdale Road Neighborhood (LE_34, LE_36, and LE_43) A significant local depression exists along Southdale Road south of West 68th Street, extending westward to Dawson Lane and eastward to Valley View Road. Under existing conditions, the low areas at Southdale Road and Valley View Road are drained by a 36-inch pipe that conveys runoff to the storm sewer system along Cornelia Drive. The lowest point along Southdale Road is approximately 862.8 feet, and the surface overflow from this area, to the southeast along West 70th Street, is approximately 869.5 feet. The 1- percent-annual-chance flood elevation for this area (866.6 feet) inundates Dawson Lane, Southdale Road and Valley View Road, portions of which would be under more than 2 feet of water, and may impact up to 28 principle structures (not counting sheds or other smaller outbuildings). The flooding problem in this area is primarily related to the capacity of the existing storm sewer system, which is controlled in part by the size of the local drainage pipe and partly due to tailwater conditions in the downstream storm sewer system on Cornelia Drive. High flow velocities through smaller 24-inch pipes under West 72nd Street result in significant friction losses that limit outflow and back up water in the Cornelia Drive storm sewer system. Additionally, surface overflows from Valley View Road occur at West 68th Street, contributing additional runoff to the low area along Southdale Road. Proposed solutions to the flooding problem are to reduce or eliminate inflow from Valley View Road and to increase the City of Edina 2018 Comprehensive Water Resources Management Plan 7-5 discharge capacity from the Southdale Road low area. Detailed modeling of proposed improvements was performed as part of this Plan update; the results are described below. Surface overflow from Valley View Road at West 68th Street could be reduced or eliminated by preventing surface overflows to Valley View Road from the properties south of West 69th Street (LE_43, NC_119) and raising West 68th Street at the intersection with Valley View Road. These proposed flood reduction measures would decrease the 1-percent-annual-chance peak water surface elevation in the Southdale Road low area by 0.1 feet, preventing flood impacts from only one principle structure. This indicates that while surface overflow from Valley View Road contributes to the problem in this area, the volume of runoff is small in comparison to local drainage. Stormwater is conveyed from the Southdale Road low area via a 36-inch pipe to the west. Upon reaching the intersection of Dunberry Lane and Cornelia Drive, water flows north to South Lake Cornelia through a 54-inch pipe and over a weir, despite the storm sewer sloping south to West 70th Street. This is part of the storm sewer design, using South Lake Cornelia for storage before it peaks due to regional flooding. To evaluate improvement options, the capacity of the storm sewer system under Cornelia Drive between South Cornelia and Dunberry Lane was doubled (both the pipe and weir), and the pipe under Dunberry Lane and Southdale Road was increased to a 54-inch pipe. The resulting 1-percent-annual-chance peak water surface elevation in the Southdale Road low area decreased by 0.7 feet (LE_34 and LE_36), which appears to protect 14 residences from impacts, based on LiDAR data and approximate building footprints. It should be noted that the individual measures of doubling the capacity of the Cornelia Drive pipe or the weir at South Cornelia had marginal impacts (0.0 to 0.2 feet reduction) on the Southdale Road neighborhood. To evaluate improvement options, the capacity of the storm sewer system south of West 70th Street was also increased to reduce friction losses. The resulting 1-percent-annual-chance peak water surface elevation in the Southdale Road neighborhood decreased by about 0.2 feet, which appears to protect four principle structures from impacts based on LiDAR data and approximate building footprints. However, the added capacity to the south had a negative impact on Lake Edina, raising the peak water surface elevation by 0.3 feet. Other flood improvement measures, contingent on proposed and future development east of Valley View Road and throughout the larger area, are possible. Additional pipe capacity under Valley View Road and West 66th Street to Lake Cornelia and/or storage in public land along Valley View Road may be available. If capacity and/or storage is available, additional storm sewer could be installed to connect the Southdale Road low area to the Valley View Road storm sewer system, draining this area to North Lake Cornelia. Raising the surface overflow elevation from North Lake Cornelia to South Lake Cornelia along West 66th Street is another option for consideration, as this could reduce the flood elevation in South Lake Cornelia. City of Edina 2018 Comprehensive Water Resources Management Plan 7-6 7.3.1.2 Southwest Corner of TH 62 and TH 100 (NC_7, NC_8, NC_13, NC_11, NC_12, NC_14, NC_15, NC_16, and NC_20) A portion of the Normandale Park neighborhood southwest of the TH 62 and TH 100 interchange and north of West 66th Street drains to North Lake Cornelia via a storm sewer pipe under TH 100. There are several depressions within this area that include portions of Warren, Mildred, Rolf, Tingdale, Wilryan, and Josephine Avenues. Peak water surface elevations in these low areas from the 1-percent-annual-chance 24-hour storm event may impact up to 22 principle structures in the area north of West 64th Street between Mildred Avenue and Josephine Avenue, not counting sheds or other smaller outbuildings, based on LiDAR data and approximate building footprints. The flooding problem in this area is primarily related to the capacity of the storm sewer system that conveys stormwater from this area to North Lake Cornelia, particularly one 30-inch pipe segment running from west to east under Parnell Avenue along West 65th Street, where the friction losses are significant under full pipe flow conditions. The limited capacity raises upstream flood elevations. Additionally, the number of catch basins limits the flow that can enter the storm sewer system. When the inlets and/or storm sewer system are overwhelmed, water pools in the depression areas, impacting structures that are below the surface overflow elevations. A few alternatives were evaluated that moderately reduced the 1-percent-annual-chance flood elevations, but did not significantly reduce the number of potentially impacted principle structures. Those alternatives were focused on increasing the size of the 30-inch pipe segment, and on increasing the number of inlets north of West 64th Street. The additional pipe capacity had a significant local impact on the east side of TH 100, but did not have positive impacts far upstream. One of the most effective improvement alternative evaluated for this area is the addition of underground storage under the five streets north of West 64th Street. As these streets are reconstructed in the future, the addition of storage should be considered. Assuming installation of 500 lineal feet of 20-foot wide and 3-foot deep storage, the 1-percent-annual-chance flood elevations in NC_7, NC_8, NC_11, and NC_13 are each decreased by approximately 1 foot, potentially preventing impacts to more than 10 principle structures. Another effective improvement alternative evaluated is increasing the pipe capacity of the trunk storm sewer system from Wilryan Avenue (subwatershed NC_9) to North Lake Cornelia. This alternative lowers the 1-percent-annual-chance flood elevation, also potentially preventing impacts to about 10 principle structures. 7.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the annual removal of total phosphorus from several ponds in the Lake Cornelia/Lake Edina drainage area was predicted to be below the desired 60 percent removal rate. For ponds with total phosphorus removal below 60 percent, the permanent pool storage volume was analyzed to determine whether additional capacity was necessary. The ponds with deficiencies in total phosphorus removal and permanent pool volume are listed below (and are also summarized in Appendix D), with recommended pond upgrades. City of Edina 2018 Comprehensive Water Resources Management Plan 7-7 Construction of new or expansion of existing water quality basins is one way to increase pollutant removal prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. 7.3.2.1 LE_38 Pond LE_38 is located along the west side of Lake Edina, directly east of TH 100 (primarily within the Minnesota Department of Transportation [MnDOT] right-of-way). The pond receives runoff from an area of approximately 36 acres. Flow from this pond is discharged into Lake Edina via a weir structure and pipe system. Based on the recommended storage volume discussed above, Pond LE_38 is deficient in permanent pool storage volume. It is recommended that an additional 1.4 acre-feet of dead storage volume be provided to meet the MPCA design criteria for detention basins. 7.3.2.2 NC_88 Pond NC_88 is located southeast of the intersection of York Avenue and West 64th Street. This basin has two pumped outlets, with discharge eventually entering both the Point of France Pond and the Swimming Pool Pond. Based on the MPCA-recommended storage volume for detention basins, there is not an adequate amount of permanent pool storage in this basin. However, since the predicted total phosphorus removal rate from this pond is approximately 50 percent and the pumped stormwater leaving this basin will receive additional water quality treatment through several subsequent ponding basins, recommendations for additional dead-storage volume are not being made at this time. Table 7.2 Watershed Modeling Results for Subwatersheds in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) AHR_1 3.4 27 23 1.4 0.6 2.1 9 0.6 AHR_10 1.2 80 10 0.7 0.2 0.7 5 0.4 AHR_11 7.8 79 40 4.2 1.4 4.7 18 2.3 AHR_12 4.8 80 38 2.7 0.9 2.9 18 1.4 AHR_13 2.1 79 15 1.1 0.4 1.3 7 0.6 AHR_14 8.5 50 67 4.0 1.6 5.1 28 1.9 AHR_15 9.2 54 78 4.4 1.8 5.5 34 2.2 AHR_16 4.2 50 39 2.0 0.8 2.5 18 1.0 AHR_17 3.0 50 27 1.4 0.6 1.8 12 0.7 AHR_18 2.4 80 15 1.3 0.4 1.4 7 0.7 AHR_19 1.0 80 11 0.5 0.2 0.6 6 0.3 AHR_2 2.8 54 31 1.3 0.5 1.7 15 0.7 AHR_20 10.5 42 74 4.6 2.0 6.3 30 2.2 AHR_21 1.9 70 20 1.0 0.4 1.2 10 0.5 AHR_3 4.3 49 36 2.0 0.8 2.5 16 1.0 AHR_4 24.1 46 149 10.8 4.5 14.5 59 5.2 AHR_5 4.9 40 42 2.1 0.9 3.0 17 1.0 AHR_6 1.4 73 11 0.7 0.3 0.8 5 0.4 AHR_7 1.1 32 13 0.5 0.2 0.7 6 0.2 AHR_8 9.3 78 56 5.0 1.7 5.6 26 2.7 LE_1 47.0 64 291 26.1 8.8 28.2 141 14.1 LE_10 4.6 25 42 2.2 0.9 2.7 22 1.1 LE_10a 42.1 25 259 18.6 8.0 25.2 110 8.8 LE_11 2.8 25 21 1.3 0.5 1.7 10 0.6 LE_12 8.7 25 56 3.8 1.6 5.2 24 1.8 LE_13 6.1 25 46 2.7 1.2 3.6 21 1.3 LE_14 3.0 25 31 1.4 0.6 1.8 16 0.6 LE_15 4.2 28 38 1.9 0.8 2.5 18 0.9 LE_16 4.8 26 36 2.1 0.9 2.9 16 1.0 LE_17 12.5 25 78 5.5 2.4 7.5 33 2.6 LE_18 1.8 25 11 0.7 0.3 1.0 4 0.3 LE_19 2.9 8 22 1.2 0.5 1.7 10 0.5 LE_2 3.8 27 34 1.7 0.7 2.2 17 0.8 LE_20 8.1 64 78 4.3 1.5 4.9 40 2.3 LE_21 4.7 23 35 2.1 0.9 2.8 16 1.0 LE_23 2.7 25 22 1.2 0.5 1.6 10 0.6 LE_24 23.5 39 161 11.0 4.5 14.1 71 5.4 LE_25 2.9 25 28 1.3 0.5 1.7 14 0.6 LE_26 12.9 30 102 5.9 2.4 7.7 47 2.8 LE_27 3.5 65 39 1.9 0.7 2.1 21 1.0 LE_28 17.0 25 113 7.9 3.2 10.2 51 3.8 LE_29 6.0 25 48 2.7 1.1 3.6 22 1.3 LE_3 3.9 30 33 1.8 0.7 2.3 16 0.9 LE_30 15.3 26 70 6.7 2.8 9.2 29 3.1 LE_31 7.7 25 68 3.5 1.5 4.6 33 1.7 LE_32 3.8 25 33 1.7 0.7 2.3 16 0.8 LE_33 7.1 25 64 3.2 1.4 4.3 31 1.5 LE_34 19.5 25 123 8.6 3.7 11.7 52 4.1 LE_35 1.8 38 15 0.8 0.3 1.1 7 0.4 LE_36 4.0 25 15 1.6 0.7 2.4 6 0.7 LE_37 1.2 65 13 0.7 0.2 0.7 7 0.3 LE_38 5.9 43 61 3.3 1.1 3.5 32 1.8 LE_39 1.0 65 10 0.5 0.2 0.6 5 0.3 LE_4 9.1 27 74 4.3 1.7 5.5 36 2.1 LE_40 5.8 28 40 2.6 1.1 3.5 17 1.3 LE_41 0.9 65 8 0.5 0.2 0.5 4 0.3 LE_43 5.2 74 41 2.7 1.0 3.1 19 1.5 LE_44 2.9 25 25 1.4 0.5 1.7 12 0.7 LE_45 2.4 25 23 1.1 0.4 1.4 11 0.5 LE_5 10.6 26 80 4.8 2.0 6.4 36 2.3 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 7.2 Watershed Modeling Results for Subwatersheds in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event LE_51 13.1 22 67 5.7 2.5 7.9 28 2.6 LE_52 6.0 25 59 2.7 1.1 3.6 30 1.3 LE_53 6.5 25 65 2.9 1.2 3.9 33 1.4 LE_54 8.6 21 66 3.8 1.6 5.2 30 1.8 LE_6 8.3 25 62 3.8 1.6 5.0 29 1.9 LE_7 10.9 25 55 5.0 2.0 6.6 23 2.4 LE_8 2.1 25 21 1.0 0.4 1.3 11 0.5 LE_9 4.8 25 43 2.2 0.9 2.9 22 1.1 MPLS_130 3.8 25 42 1.7 0.7 2.3 22 0.8 NC_10 4.1 30 34 1.9 0.8 2.5 16 0.9 NC_100 1.5 80 13 0.8 0.3 0.9 7 0.4 NC_101 15.7 80 104 8.6 2.9 9.4 48 4.6 NC_101R 4.8 100 16 2.9 0.8 2.9 8 1.6 NC_102 3.8 80 27 2.1 0.7 2.3 12 1.1 NC_103 2.1 80 13 1.2 0.4 1.3 6 0.6 NC_104 6.5 34 64 2.8 1.2 3.9 30 1.3 NC_105 1.3 25 13 0.5 0.3 0.8 5 0.2 NC_106 6.4 80 35 3.5 1.2 3.9 16 1.9 NC_106a 6.6 90 41 3.8 1.2 4.0 20 2.1 NC_106aP 1.8 100 8 1.1 0.3 1.1 4 0.6 NC_106aR 3.9 100 12 2.3 0.7 2.3 5 1.3 NC_106R 2.1 100 9 1.3 0.4 1.3 4 0.7 NC_107 1.5 80 13 0.8 0.3 0.9 6 0.4 NC_108 1.0 80 9 0.6 0.2 0.6 4 0.3 NC_109 1.1 80 11 0.6 0.2 0.7 6 0.3 NC_11 9.0 26 68 4.0 1.7 5.4 31 1.9 NC_110 1.8 80 18 1.0 0.3 1.1 9 0.5 NC_111 5.8 79 44 3.2 1.1 3.5 20 1.7 NC_112 7.4 80 52 4.0 1.4 4.4 24 2.2 NC_113 11.3 80 82 6.2 2.1 6.7 38 3.4 NC_114 2.1 80 20 1.1 0.4 1.2 10 0.6 NC_115 2.2 80 22 1.2 0.4 1.3 11 0.6 NC_117 1.5 24 16 0.7 0.3 0.9 8 0.4 NC_118 1.3 23 14 0.6 0.2 0.8 7 0.3 NC_119 1.2 80 12 0.6 0.2 0.7 6 0.3 NC_12 7.5 25 57 3.3 1.4 4.5 26 1.6 NC_120 1.9 52 22 0.9 0.4 1.1 11 0.5 NC_121 2.1 80 15 1.1 0.4 1.2 7 0.6 NC_122 3.3 80 35 1.8 0.6 2.0 19 1.0 NC_123 4.1 95 27 2.4 0.8 2.5 13 1.4 NC_123R 2.4 100 7 1.4 0.4 1.4 3 0.8 NC_125 1.9 78 19 1.0 0.4 1.1 10 0.5 NC_126 2.7 65 29 1.4 0.5 1.6 15 0.7 NC_127 2.8 25 28 1.3 0.5 1.7 14 0.6 NC_128 3.3 65 37 1.7 0.6 2.0 19 0.9 NC_129 3.8 80 40 2.1 0.7 2.3 20 1.1 NC_13 2.5 25 25 1.1 0.5 1.5 13 0.5 NC_131 1.7 79 17 0.9 0.3 1.0 9 0.5 NC_132 6.7 59 72 3.3 1.3 4.0 37 1.7 NC_133 3.8 63 41 2.0 0.7 2.3 22 1.1 NC_134 1.6 65 19 0.8 0.3 1.0 10 0.4 NC_135 2.9 25 23 1.3 0.5 1.7 10 0.6 NC_136 5.2 25 37 2.3 1.0 3.1 16 1.1 NC_137 2.0 79 20 1.1 0.4 1.2 10 0.6 NC_138 1.0 61 12 0.5 0.2 0.6 7 0.3 NC_139 4.8 78 30 2.6 0.9 2.8 14 1.4 NC_14 5.2 25 50 2.3 1.0 3.1 25 1.1 NC_140 2.1 79 18 1.2 0.4 1.3 9 0.6 NC_141 2.6 80 17 1.4 0.5 1.6 8 0.8 NC_142 7.9 46 58 3.8 1.5 4.7 26 1.9 Table 7.2 Watershed Modeling Results for Subwatersheds in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NC_143 1.4 80 9 0.8 0.3 0.8 4 0.4 NC_144 7.7 80 65 4.3 1.5 4.6 32 2.3 NC_145 3.3 25 23 1.5 0.6 2.0 10 0.7 NC_146 9.8 70 83 5.1 1.9 5.9 39 2.7 NC_147 0.4 70 5 0.2 0.1 0.3 3 0.1 NC_148 0.8 37 9 0.5 0.2 0.5 5 0.3 NC_149 3.5 79 33 1.9 0.7 2.1 17 1.0 NC_15 4.7 25 39 2.1 0.9 2.8 18 1.0 NC_151 0.7 80 8 0.4 0.1 0.4 4 0.2 NC_152 1.7 80 16 1.0 0.3 1.0 8 0.5 NC_153 2.6 80 25 1.4 0.5 1.6 13 0.8 NC_154 5.1 80 42 2.8 1.0 3.1 20 1.5 NC_155 0.6 80 5 0.3 0.1 0.3 2 0.2 NC_156 3.4 80 32 1.9 0.6 2.0 16 1.0 NC_157 5.5 25 48 2.5 1.1 3.3 23 1.2 NC_158 2.2 25 22 1.1 0.4 1.3 11 0.6 NC_16 5.6 26 46 2.5 1.1 3.3 22 1.2 NC_17 1.8 25 18 0.8 0.3 1.1 10 0.4 NC_18 8.9 25 63 4.0 1.7 5.4 28 1.9 NC_19 7.8 30 64 3.5 1.5 4.7 30 1.7 NC_2 11.5 55 98 6.0 2.2 6.9 48 3.1 NC_20 2.0 28 15 0.9 0.4 1.2 7 0.4 NC_21 7.2 62 67 3.8 1.4 4.3 33 2.0 NC_22 5.8 21 49 2.8 1.1 3.5 24 1.4 NC_23 3.8 65 43 2.1 0.7 2.3 23 1.1 NC_24 6.3 28 55 2.9 1.2 3.8 27 1.4 NC_25 7.7 26 71 3.5 1.5 4.6 35 1.7 NC_26 1.9 65 22 1.0 0.4 1.2 12 0.6 NC_27 12.4 64 135 6.6 2.4 7.5 72 3.5 NC_28 1.1 65 13 0.6 0.2 0.7 7 0.3 NC_29 0.7 58 7 0.3 0.1 0.4 4 0.2 NC_3 16.2 56 146 9.4 3.1 9.7 75 5.2 NC_30 21.7 61 156 11.7 4.1 13.0 75 6.2 NC_31 6.6 27 56 3.0 1.3 4.0 27 1.4 NC_32 6.4 65 49 3.4 1.2 3.9 23 1.8 NC_33 2.5 60 29 1.3 0.5 1.5 15 0.7 NC_34 1.0 65 11 0.5 0.2 0.6 6 0.3 NC_35 10.6 25 86 4.7 2.0 6.3 40 2.3 NC_36 14.1 25 101 6.3 2.7 8.5 45 3.0 NC_37 2.2 23 20 1.0 0.4 1.3 10 0.5 NC_38 3.9 18 33 1.8 0.7 2.3 17 0.9 NC_39 4.7 28 40 2.1 0.9 2.8 19 1.0 NC_4 12.7 73 92 7.0 2.4 7.6 44 3.8 NC_40 7.0 29 50 3.2 1.3 4.2 22 1.5 NC_41 7.8 66 63 4.2 1.5 4.7 30 2.2 NC_42 8.3 65 35 4.3 1.5 4.9 15 2.3 NC_43 14.0 29 108 6.3 2.6 8.4 50 3.1 NC_44 2.8 70 26 1.5 0.5 1.7 13 0.8 NC_45 1.8 27 19 0.8 0.3 1.1 10 0.4 NC_46 15.2 29 64 6.7 2.8 9.1 27 3.1 NC_47 3.2 53 29 1.6 0.6 1.9 14 0.8 NC_48 8.2 25 62 3.7 1.6 4.9 28 1.7 NC_49 1.9 25 20 0.9 0.4 1.1 11 0.4 NC_5 8.6 60 75 4.5 1.6 5.2 37 2.4 NC_50 3.3 25 32 1.6 0.6 2.0 16 0.8 NC_51 3.7 61 37 1.9 0.7 2.2 19 1.0 NC_52 7.6 25 68 3.5 1.4 4.6 33 1.7 NC_53 2.2 25 18 1.0 0.4 1.3 9 0.5 NC_54 5.6 53 43 2.8 1.1 3.3 20 1.4 NC_55 2.5 15 22 1.2 0.5 1.5 11 0.6 Table 7.2 Watershed Modeling Results for Subwatersheds in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NC_56 16.0 27 109 7.2 3.0 9.6 48 3.4 NC_57 4.8 80 37 2.7 0.9 2.9 17 1.4 NC_58 11.6 25 94 5.2 2.2 7.0 44 2.5 NC_59 20.7 27 143 9.3 3.9 12.4 63 4.4 NC_6 5.1 55 51 2.6 1.0 3.0 26 1.4 NC_60 4.4 25 36 2.0 0.8 2.7 17 0.9 NC_61 2.1 25 21 0.9 0.4 1.2 10 0.4 NC_62 61.8 59 342 34.1 11.5 37.1 163 18.3 NC_63 1.7 31 18 0.9 0.3 1.0 10 0.5 NC_64 3.8 25 28 1.7 0.7 2.3 13 0.8 NC_65 2.2 65 26 1.3 0.4 1.3 14 0.7 NC_66 1.8 65 20 1.0 0.3 1.1 10 0.5 NC_67 1.4 29 13 0.6 0.3 0.9 7 0.3 NC_68 1.9 65 22 1.0 0.4 1.1 12 0.6 NC_69 2.0 76 20 1.1 0.4 1.2 10 0.6 NC_7 5.4 26 43 2.4 1.0 3.3 20 1.2 NC_70 2.5 25 25 1.1 0.5 1.5 13 0.5 NC_71 1.6 44 17 0.8 0.3 0.9 9 0.4 NC_72 0.8 47 9 0.4 0.2 0.5 5 0.2 NC_73 1.7 55 18 0.8 0.3 1.0 10 0.4 NC_74 1.1 25 12 0.5 0.2 0.7 6 0.2 NC_75 5.1 44 49 2.6 1.0 3.1 25 1.4 NC_76 1.2 65 14 0.6 0.2 0.7 7 0.3 NC_77 0.9 80 10 0.5 0.2 0.5 5 0.3 NC_78 3.1 31 27 1.7 0.6 1.9 14 0.9 NC_79 3.3 25 25 1.5 0.6 2.0 11 0.7 NC_8 3.3 26 21 1.5 0.6 2.0 9 0.7 NC_80 1.1 65 12 0.5 0.2 0.6 7 0.3 NC_81 6.2 73 56 3.3 1.2 3.7 27 1.8 NC_82 7.6 28 53 3.4 1.4 4.5 23 1.6 NC_83 2.8 72 24 1.5 0.5 1.7 11 0.8 NC_84 5.9 62 62 2.9 1.1 3.5 31 1.5 NC_85 7.8 50 48 3.6 1.5 4.7 20 1.8 NC_86 9.9 50 75 4.6 1.9 5.9 31 2.2 NC_87 2.7 76 28 1.4 0.5 1.6 14 0.8 NC_88 20.8 47 166 9.5 3.9 12.5 69 4.6 NC_89 5.2 76 47 2.8 1.0 3.1 23 1.5 NC_9 1.3 33 14 0.6 0.2 0.7 7 0.3 NC_90 5.2 80 35 2.9 1.0 3.1 16 1.6 NC_91 1.6 80 17 0.9 0.3 0.9 9 0.5 NC_92 3.4 28 31 1.4 0.6 2.0 13 0.6 NC_93 7.8 26 50 3.4 1.5 4.7 21 1.6 NC_94 4.2 28 33 1.9 0.8 2.5 15 0.9 NC_95 9.1 25 65 4.0 1.7 5.4 29 1.9 NC_96 10.2 25 67 4.5 1.9 6.1 29 2.1 NC_97 10.6 51 90 5.1 2.0 6.4 41 2.6 NC_98 1.6 25 16 0.7 0.3 0.9 8 0.3 NC_99 12.6 65 81 6.3 2.4 7.5 35 3.3 SC_1 55.3 72 376 30.6 10.4 33.2 180 16.6 SC_2 14.4 30 119 6.7 2.7 8.6 57 3.3 SC_3 11.6 30 100 5.3 2.2 6.9 48 2.6 SC_4 12.4 25 100 5.6 2.3 7.4 47 2.7 SC_5 2.8 25 25 1.5 0.5 1.7 13 0.8 SC_6 1.9 25 19 0.9 0.4 1.2 10 0.4 SC_7 6.0 25 44 2.7 1.1 3.6 20 1.3 SC_8 1.4 25 13 0.6 0.3 0.8 7 0.3 SC_9 6.6 25 52 3.0 1.2 3.9 25 1.4 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 98 876.4 875.9 99 866.3 865.6 687 868.4 867.9 693 874.6 874.5 694 877.2 876.1 696 939.3 938.6 697 939.1 937.9 698 938.3 937.0 699 938.2 936.9 700 937.6 936.3 701 936.9 935.7 703 936.1 936.5 711 923.2 920.9 712 922.2 919.8 715 street 917.8 915.4 718 913.6 911.9 719 909.5 907.9 720 868.6 868.6 721 867.4 867.3 722 867.2 866.9 723 867.0 866.2 725 864.8 863.4 727 869.1 868.6 728 869.8 869.3 734 865.6 865.2 738 912.9 912.7 741 892.4 892.0 742 882.1 879.6 743 878.4 873.8 747 868.6 868.6 749 869.6 869.2 755 882.0 881.8 760 888.8 888.7 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 762 895.1 894.7 766 867.1 867.0 768 868.3 867.8 769 869.2 868.3 771 869.2 868.3 776 866.3 865.3 777 865.9 864.7 778 865.4 863.9 779 865.0 863.4 782 868.0 866.7 783 867.6 866.4 785 866.3 865.8 793 868.0 867.5 796 867.6 866.0 797 868.2 866.8 798 867.9 866.4 805 864.8 863.1 808 866.0 863.9 809 866.7 865.3 813 867.4 866.2 816 868.6 867.3 818 869.8 868.1 819 street 869.9 868.3 820 869.9 868.6 821 869.9 868.9 822 869.9 868.9 823 869.9 869.0 824 878.5 875.8 825 875.6 873.1 826 875.6 872.3 830 873.7 870.8 831 880.5 879.5 838 864.6 860.8 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 839 864.5 862.2 841 864.5 863.0 842 864.7 863.4 843 865.2 863.7 844 865.7 863.9 846 868.2 866.0 848 866.2 864.6 849 866.2 864.6 850 866.2 864.7 851 866.3 864.8 852 866.3 864.9 853 866.5 865.0 855 866.6 865.4 856 866.6 865.9 859 866.6 865.7 860 866.1 865.4 861 865.1 864.9 863 862.2 862.1 868 847.2 846.5 869 844.7 844.1 871 838.4 838.4 874 832.1 831.4 876 831.9 831.0 879 830.8 828.8 880 830.7 828.2 881 830.6 827.3 883 827.6 825.6 886 830.5 828.9 889 833.6 833.3 909 854.5 852.3 914 859.4 858.7 1369 864.8 863.0 1373 868.3 868.1 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1377 878.9 878.4 1379 877.1 876.7 1381 874.8 874.5 1390 879.9 878.9 1391 878.9 878.0 1393 877.0 876.1 1487 862.5 857.8 1488 859.9 856.4 1489 857.0 854.8 1490 853.8 852.4 1491 850.3 849.2 1553 878.9 878.7 1555 877.4 876.7 1557 872.5 872.2 1558 868.0 864.9 1560 869.1 867.2 1563 865.9 863.4 1564 860.3 859.2 1566 858.9 855.0 1567 856.2 850.7 1568 853.2 846.0 1569 854.1 850.5 1570 854.0 848.4 1576 879.8 879.0 1577 878.9 878.2 1578 878.9 878.1 1579 878.9 878.0 1581 878.0 877.0 1582 877.6 876.7 1583 877.3 876.5 1584 876.3 875.8 1586 870.0 867.7 1587 867.7 866.5 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1681 873.9 873.3 1833 872.0 870.9 1834 869.9 869.4 1972 826.4 823.9 1997 865.0 864.4 2020 884.5 884.5 2021 882.7 882.3 2027 876.8 876.2 2057 874.9 872.3 2062 875.0 873.6 2063 875.2 873.9 2065 875.2 874.1 2066 876.7 876.5 2067 874.9 874.7 2068 874.9 874.5 2138 867.1 865.9 2143 869.9 869.4 2144 869.7 869.4 2148 858.6 856.2 2150 869.1 867.4 2153 860.1 855.0 2154 860.5 855.1 2155 859.1 855.0 2171 872.7 872.6 2172 872.7 872.7 2186 868.1 867.5 2188 874.6 872.8 2189 878.6 877.8 2215 874.7 869.5 2216 874.7 870.2 2217 874.7 872.0 2219 875.1 874.3 2220 875.9 875.0 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2221 877.9 878.9 2222 878.1 879.4 2223 879.2 879.2 2224 874.7 872.2 2225 874.7 873.1 2228 874.7 873.5 2229 874.7 872.2 2230 880.7 874.6 2232 874.9 874.2 2233 874.9 874.1 2234 874.9 874.5 2238 880.3 880.0 2240 876.3 875.7 2286 881.6 881.2 2299 878.7 876.3 2300 873.9 872.0 2301 873.5 871.5 2302 873.1 871.1 2303 872.9 870.8 2304 872.1 870.1 2305 879.8 877.8 2306 877.8 876.9 2307 877.1 876.9 2308 877.2 877.0 2312 875.1 873.1 2313 878.8 876.9 2314 878.7 876.1 2315 878.7 875.9 2315.1 860.5 859.7 2316 858.5 857.9 2317 878.5 875.0 2317.1 856.5 856.1 2318 878.3 874.6 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2319 854.2 854.0 2320 852.3 852.2 2321 848.9 848.9 2324 876.5 875.5 2327 881.2 880.6 2329 882.8 882.7 2332 880.4 879.9 2333 881.1 880.6 2334 881.5 880.9 2336 881.6 881.0 2337 881.6 880.9 2338 881.6 880.9 2340 877.3 876.4 2345 917.2 914.5 2347 917.4 913.9 2350 919.2 916.5 2351 917.8 914.2 2352 918.7 914.7 2354 919.7 915.4 2355 920.5 915.9 2356 920.5 917.3 2357 922.9 918.9 2358 924.2 920.6 2360 877.0 875.4 2373.1 874.0 874.0 2374.1 872.9 872.9 2375 872.5 872.5 2376.1 872.5 872.5 2377 872.4 872.3 2386 872.3 871.8 2388 878.9 878.0 2466 870.8 869.4 2467 873.4 873.2 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2469 869.9 869.3 2472 872.1 869.4 2473 874.9 873.1 2476 870.4 863.8 2477 866.3 862.1 2761 880.8 878.2 2769 866.9 865.5 2779 881.7 881.2 2780 881.4 880.8 2781 881.7 881.0 2786 879.0 877.6 2796 870.0 869.5 2800 868.7 866.3 2801 860.5 859.4 2802 860.7 860.2 2803 861.0 860.8 2811 896.3 896.2 2813 895.4 895.2 2816 866.1 862.5 2817 865.3 862.6 2818 874.9 873.3 2819 872.6 872.5 2829 841.9 841.2 2839 827.3 825.8 2841 876.0 874.6 2842 875.9 874.8 2844 875.8 875.2 2845 875.9 874.9 2879 880.3 877.4 2903 877.1 876.9 2904 877.1 876.7 2913 875.9 875.0 2968 874.7 871.1 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2066$I 875.2 874.7 2262a 861.6 860.7 2373.1$I 873.5 873.4 2374.1$I 872.3 872.3 2375$I 872.2 872.2 2376.1$I 872.1 872.1 2377$I 869.9 869.0 747$I 867.1 867.1 AHR_1 842.3 838.6 AHR_10 869.1 867.6 AHR_11 street 869.0 867.1 AHR_12 parking lot 876.7 876.1 AHR_13 872.7 872.5 AHR_14 parking lot 864.4 864.2 AHR_15 street/lot 863.7 862.7 AHR_16 863.7 861.7 AHR_17 parking lot 854.3 854.1 AHR_18 872.0 867.1 AHR_19 874.8 874.1 AHR_2 street 860.1 858.4 AHR_20 parking lot 864.8 862.8 AHR_21 873.3 873.2 AHR_3 parking lot 861.2 860.8 AHR_4 street 854.0 847.3 AHR_5 path 852.3 844.1 AHR_6 865.1 861.9 AHR_7 866.6 862.4 AHR_8 street 866.7 864.7 CBMH_2 828.7 827.2 CBMH_6 830.6 829.1 CBMH_7 830.8 829.9 LE_1 lake 822.0 826.4 4.4 824.0 2.0 LE_10 street 830.6 828.8 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 LE_10a street 831.0 830.5 LE_11 831.6 830.4 LE_12 833.9 833.4 LE_13 street 832.1 831.4 LE_14 street 860.6 860.4 LE_15 841.1 840.8 LE_16 859.3 857.7 LE_17 836.5 836.1 LE_18 859.2 858.8 LE_19 dry pond 854.2 850.9 LE_2 840.3 840.0 LE_20 dry pond 843.0 841.8 LE_21 street 854.5 851.9 LE_23 830.9 829.5 LE_24 street 854.2 852.5 LE_25 856.2 855.9 LE_26 school/park 858.8 857.9 LE_27 840.6 840.0 LE_28 street 873.9 873.3 LE_29 street 857.1 855.8 LE_3 835.2 834.6 LE_30 street 866.8 866.1 LE_31 street 873.2 870.7 LE_32 866.4 864.4 LE_33 street 864.5 862.7 LE_34 street 866.6 865.3 LE_35 866.6 866.4 LE_36 byd 866.6 865.3 LE_37 835.5 835.5 LE_38 wetland 822.2 827.3 5.1 825.9 3.7 LE_39 834.9 834.8 LE_4 street 832.6 832.2 LE_40 864.1 863.9 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 LE_40$I 864.0 863.8 LE_41 hwy ditch 829.6 828.7 LE_43 street 866.6 865.9 LE_44 byd 871.3 ¹ 870.0 LE_45 byd 868.0 867.7 LE_5 841.8 841.6 LE_51 byd 840.5 ¹ 835.7 LE_52 street 840.6 839.8 LE_53 street 830.6 827.2 LE_54 park 847.4 ¹ 844.2 LE_6 street 834.0 833.7 LE_7 byd 831.1 830.4 LE_8 street 829.0 825.8 LE_9 street 828.2 827.9 MH_1034 829.5 826.6 MH2061 875.0 873.3 MPLS_130 byd 887.0 ¹ 885.5 N507 884.4 884.2 N510 873.2 873.2 N529 861.0 861.0 N530 cul-de-sac 912.5 912.5 N534 868.5 868.4 N543 858.7 857.6 NC_10 931.1 930.7 NC_100 parking lot 883.9 883.9 NC_100$I 881.1 878.1 NC_101 parking lot 875.7 874.2 NC_101a parking lot 883.1 881.3 NC_101R rooftop 900.0 900.0 NC_102 parking lot 881.1 879.9 NC_103 880.0 878.1 NC_104 street 876.7 876.4 NC_105 876.9 876.1 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NC_106 parking lot 878.7 875.6 NC_106a parking lot 877.5 876.2 NC_106aP parking lot 900.0 900.0 NC_106aR rooftop 900.0 900.0 NC_106b underground 881.6 881.2 NC_106R rooftop 900.0 900.0 NC_107 street 878.6 875.4 NC_108 street 877.1 876.9 NC_109 street 876.7 874.6 NC_11 street 936.7 935.5 NC_110 parking lot 878.7 878.4 NC_111 878.8 876.9 NC_112 parking lot 870.5 869.9 NC_113 parking lot 868.9 867.6 NC_114 parking lot 876.2 875.9 NC_115 878.9 877.8 NC_117 864.8 863.2 NC_118 865.4 863.1 NC_119 ditch 869.7 869.4 NC_12 street 935.3 935.1 NC_12$I 933.2 933.7 NC_120 868.2 866.8 NC_121 parking lot 876.8 875.7 NC_121ds 876.7 875.7 NC_122 875.6 875.2 NC_122a underground 877.4 876.5 NC_123 underground 881.6 879.4 NC_123R rooftop 900.0 900.0 NC_124a 884.5 884.4 NC_124c underground 881.2 879.5 NC_125 875.9 875.2 NC_126 877.7 876.9 NC_127 882.5 879.7 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NC_128 street 869.1 868.0 NC_129 878.8 878.6 NC_129$I 875.0 872.8 NC_13 street 939.2 938.8 NC_131 depression 871.6 868.5 NC_132 hwy ditch 874.7 872.2 NC_133 street 878.5 877.6 NC_134 876.2 875.5 NC_135 byd 909.9 ¹ 908.0 NC_136 870.2 870.0 NC_137 869.6 866.3 NC_138 869.2 868.7 NC_139 876.5 874.4 NC_14 street 932.8 932.6 NC_140 883.3 883.1 NC_141 parking lot 869.9 869.3 NC_142 street 875.9 874.8 NC_143 street 876.5 874.7 NC_144 878.9 878.6 NC_145 byd 880.1 878.8 NC_146 882.9 880.3 NC_147 parking lot 876.6 876.5 NC_148 868.2 865.9 NC_149 875.2 875.0 NC_15 street 928.7 928.2 NC_15$I 925.7 923.6 NC_150 875.2 874.1 NC_151 parking lot 883.5 882.9 NC_152 882.0 881.9 NC_153 loading dock 881.7 881.0 NC_154 879.4 878.5 NC_155 883.9 881.3 NC_156 parking lot 881.2 880.8 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NC_157 street 884.5 880.7 NC_158 byd 881.8 880.9 NC_16 street 928.7 927.0 NC_17 914.8 913.0 NC_18 875.0 874.6 NC_19 street/yard 918.5 916.5 NC_2 pond 863.0 866.3 3.3 865.3 2.3 NC_20 street 928.7 927.1 NC_21 910.1 905.7 NC_22 street 866.8 865.5 NC_23 921.4 919.0 NC_24 street 875.9 875.6 NC_25 881.9 881.8 NC_26 hwy ditch 869.3 868.3 NC_27 889.9 889.4 NC_28 hwy ditch 869.7 868.8 NC_28_CB 869.6 868.5 NC_29 874.5 874.5 NC_29$I 872.9 872.9 NC_3 pond 862.9 866.3 3.4 865.9 3.0 NC_30 pond 862.9 866.3 3.4 865.7 2.8 NC_31 897.7 897.5 NC_32 893.6 893.0 NC_33 888.8 888.7 NC_34 879.4 879.3 NC_34_IN 880.7 880.2 NC_35 896.3 896.0 NC_36 913.3 913.1 NC_37 869.7 863.9 NC_38 street 865.5 865.1 NC_39 street 869.6 869.3 NC_4 pond 862.9 867.2 4.3 866.3 3.4 NC_40 street/byd 869.2 868.3 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NC_41 hwy ditch 916.5 913.5 NC_42 hwy ditch 897.4 897.3 NC_43 depression 894.5 894.2 NC_44 925.4 922.0 NC_45 byd 918.7 916.6 NC_46 street 919.2 915.0 NC_47 byd 918.7 916.5 NC_48 869.5 869.1 NC_49 street 867.6 866.0 NC_5 pond 864.5 868.3 3.8 866.9 2.4 NC_50 byd 877.3 877.0 NC_51 872.4 871.4 NC_52 873.5 873.3 NC_53 895.2 894.9 NC_54 869.0 866.9 NC_55 byd 878.2 877.3 NC_56 street 878.5 878.1 NC_57 878.0 874.0 NC_58 877.3 877.1 NC_59 905.0 904.7 NC_6 pond 864.2** 867.7 3.5 866.0 1.8 NC_60 street 869.2 869.0 NC_61 byd 867.1 866.6 NC_62 pond 859.0 864.8 5.8 863.1 4.1 NC_63 street 870.1 869.7 NC_64 byd 873.7 872.2 NC_65 hwy ditch 867.6 866.3 NC_66 868.0 867.0 NC_67 889.2 889.1 NC_68 871.5 868.2 NC_69 hwy ditch 869.0 867.4 NC_7 street 939.5 939.3 NC_70 street 868.1 867.6 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NC_71 hwy ditch 867.3 866.3 NC_72 pond 860.2** 864.8 4.6 863.1 2.9 NC_73 street 868.1 866.8 NC_74 870.1 869.5 NC_75 street 867.1 865.9 NC_76 868.2 866.9 NC_77 876.9 873.0 NC_78 pond 859.3** 864.8 5.5 863.1 3.8 NC_79 869.3 868.9 NC_8 byd 939.5 938.1 NC_80 876.8 874.8 NC_81 879.5 877.4 NC_82 street 874.7 874.5 NC_83 parking lot 876.0 875.6 NC_84 hwy ditch 874.7 873.5 NC_85 parking lot 880.9 880.7 NC_86 street 880.5 879.5 NC_87 883.6 883.4 NC_88 pond 862.0 873.9 11.9 871.0 9.0 NC_89 street 876.0 875.6 NC_9 935.1 936.5 NC_90 881.0 879.0 NC_91 street 883.8 883.0 NC_92 park 880.1 879.9 NC_93 880.2 878.8 NC_94 880.8 880.6 NC_95 street 884.0 883.6 NC_96 885.6 885.4 NC_97 street 880.5 879.5 NC_98 886.4 881.2 NC_99 street 880.5 879.5 NC-124b underground 883.4 882.5 Node396 872.0 871.9 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Node397 868.7 868.7 Node399 877.2 876.0 Node400 877.7 875.8 Node401 877.2 875.9 Node402 877.3 875.9 Node403 877.4 875.9 Node404 877.5 875.8 Node405 878.5 875.7 Node414 881.0 879.8 Node415 879.6 879.0 Node419 869.0 869.0 Node420 874.9 874.8 Node421 874.9 874.7 Node423 870.8 870.8 Node426 875.4 875.0 Node429 884.1 883.8 Node430 883.5 882.8 Node431 883.4 882.4 Node432 880.0 880.0 Node433 881.2 879.5 Node434 874.5 874.5 Node436 876.8 876.8 Node437 880.4 879.9 Node438 883.8 883.7 Node439 883.7 883.4 Node440 881.7 880.1 Node441 881.5 879.5 Node442 881.4 879.0 Node443 881.2 878.4 Node444 877.8 876.5 Node564 865.3 861.5 Node565 865.3 860.9 Node567 865.3 861.9 Table 7.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Node568 865.3 860.9 Node571 866.3 865.9 Node572 864.8 863.1 SC_1 lake 859.0 864.6 5.6 860.5 1.5 SC_2 dry pond 873.2 871.8 SC_3 pond 874.7 878.5 3.8 876.7 2.0 SC_4 868.3 867.9 SC_5 street 867.0 865.3 SC_6 cul-de-sac 881.5 873.9 SC_7 street 867.5 866.5 SC_8 street 865.9 862.6 SC_9 street/byd 865.0 864.8 To_MHS_53 884.1 884.0 62 100 456717 456753 456731 Wooddale Ave Parklawn Ave Brookview Ave W 70th St Adam's HillPond Lake Edina South Lake Cornelia North Lake Cornelia RichfieldRichfield MinneapolisMinneapolis N o r t h B r anch N i n eMileCreek SC_1 NC_62 LE_1 LE_10a LE_24 AHR_4 NC_30 LE_28 LE_34 NC_88 NC_59 NC_3 SC_2 LE_30 NC_56 NC_46 NC_4 SC_4 NC_101 NC_36 LE_7 LE_51 SC_3 NC_43 LE_26 NC_2 LE_5 LE_17 NC_99 NC_27 LE_4 NC_58 LE_6 NC_97 NC_35 NC_5 NC_96 NC_86 NC_113 LE_12 NC_11 LE_54 NC_95 AHR_8 NC_18 AHR_20 LE_20 NC_146 NC_42 NC_48 LE_31 SC_9 NC_41 NC_85 AHR_15 NC_19 NC_25 LE_33 NC_52 NC_82 NC_12 SC_7 NC_124 AHR_14 NC_21 NC_106a NC_40 NC_106 LE_53 NC_142 AHR_11 NC_31 LE_13 NC_112 NC_7 NC_32 LE_29 LE_52 NC_24 NC_144 LE_40 LE_9 NC_6 NC_132 NC_22NC_16 LE_43 NC_90 NC_14 NC_89 NC_111 LE_3 LE_21 AHR_5 NC_57 NC_39 NC_15 NC_121 LE_15 NC_123 NC_93 AHR_3 NC_10 NC_139 AHR_12LE_32 NC_51 AHR_16 SC_5 AHR_1 NC_133 NC_47 LE_44 LE_11 NC_149 NC_156 LE_23 NC_83 NC_122 SC_6 NC_153 NC_103 LE_38 NC_81 NC_84 NC_104 NC_54 NC_75 LE_16 LE_10 LE_2 NC_157 NC_150 NC_136 NC_60 LE_36 NC_94NC_8 NC_38 NC_23 NC_64 NC_154 LE_27 NC_101R NC_129 NC_92 NC_79 NC_50 LE_14 NC_78 LE_25 LE_19 NC_145 NC_128 NC_102 NC_44 AHR_2 LE_8 NC_87 NC_33 NC_106aR LE_45 MPLS_130 NC_70 AHR_17 NC_55 NC_135 NC_13 NC_127 NC_126 NC_141 NC_65 NC_37 NC_53 NC_61 AHR_18 NC_20 NC_69 NC_26 NC_158 NC_68 NC_155 NC_49 LE_35 LE_18 NC_140 NC_45 NC_114 NC_66 NC_17 AHR_13 NC_123R NC_137 SC_8 NC_63 NC_73 NC_120 AHR_21 NC_125 NC_98 NC_110 NC_71 NC_91 NC_106R NC_152 NC_9 NC_100 NC_115 NC_131 NC_67 NC_134 AHR_6 NC_106aP LE_37 NC_117 NC_76 NC_143 NC_105 NC_28 NC_74 NC_118 NC_107 AHR_7 LE_39 NC_80 AHR_10 NC_119 NC_108 NC_34 NC_109NC_77 LE_41 NC_138 AHR_19 NC_72 NC_148 NC_29 NC_116 NC_151 NC_147 Barr Footer: ArcGIS 10.4.1, 2017-09-21 11:51 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_7_1_Cornelia_Drainage_Basins.mxd User: rcs2ComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 7.1 0 1,200 Feet !;N Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 LAKE CORNELIA/LAKE EDINA/ADAM'S HILL MAJOR WATERSHEDS 62 100 456717 456753 456731 Wooddale Ave Parklawn Ave Brookview Ave W 70th St Lake Cornelia - North Lake Edina Lake Cornelia - South Adam's Hill (Richfield) RichfieldRichfield MinneapolisMinneapolis N o r t h B r anch N i n eMileCreek Lake Edina South Lake Cornelia North Lake Cornelia Barr Footer: ArcGIS 10.4.1, 2017-09-21 14:38 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_7_2_Cornelia_Major_Watersheds.mxd User: EMAComprehensiveWater ResourcesManagement PlanCity of Edina, MinnesotaFIGURE 7.2 0 1,200 Feet !;N Lake Cornelia/Lake Edina/Adam's Hill Drainage Basin Major Watershed Adam's Hill (Richfield) Lake Cornelia - North Lake Cornelia - South Lake Edina Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 LAKE CORNELIA/LAKE EDINA/ADAM'S HILL PONDMAJOR WATERSHEDS Adam's HillPond City of Edina 2018 Comprehensive Water Resources Management Plan 7-32 Figure 7.3 Lake Cornelia/Lake Edina/Adam's Hill Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. NC_5 NC_6 NC_2 NC_30 NC_62NC_78 NC_72 NC_88 NC_4 SC_3 LE_38 LE_1 LE_44 NC_135 SC_2 LE_54LE_51 NC_130 SC_1 SC_1 NC_3 NC_3 RichfieldRichfield MinneapolisMinneapolis NineMileCreek Barr Footer: ArcGIS 10.4.1, 2017-09-21 08:24 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_7_4_Lk_Cornelia_Water_Quality.mxd User: rcs2LAKE CORNELIA/LAKE EDINAWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 7.4 1,200 0 1,200Feet !;N 400 0 400Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 8-1 8.0 Nine Mile Creek South 8.1 General Description of Drainage Area Figure 8.1 depicts the Nine Mile Creek—South drainage basin, located in the southeast portion of Edina. The drainage basin encompasses approximately 1,177 acres that ultimately drain to the North Fork of Nine Mile Creek between West 70th Street and the south Edina City limits. 8.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ditches, overland flow paths, wetlands, and ponding basins. The Nine Mile Creek—South drainage basin has been divided into several major watersheds based on the drainage patterns. These major watersheds are depicted on Figure 8.2. Each major watershed has been further delineated into many subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located Table 8.1 lists each major watershed and the associated subwatershed naming convention. Table 8.1 Major Watersheds within the Nine Mile Creek—South Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Centennial Lakes CL_## 42 208 South Pond SP_## 19 211 Nine Mile South NMS_## / EdCrk## 109 758 8.1.1.1 Centennial Lakes The 208-acre Centennial Lakes watershed is located in southeast Edina and drains to Centennial Lakes. The watershed is bordered by West 69th Street on the north, West 78th Street on the south, France Avenue on the west, and York Avenue on the east. Runoff from France Avenue between West 69th Street and just south of Gallagher Drive drains to Centennial Lakes. France Avenue drainage south of Gallagher Drive flows to the South Pond. The watershed is characterized by mainly commercial and high-density residential land use. Centennial Lakes spans 9.5 acres, stretching south from Gallagher Drive to Minnesota Drive, and receives runoff from the direct watershed as well as flow from Adam’s Hill Pond (10 cfs). The normal elevation of Centennial Lakes is 838 feet, controlled by a weir structure that discharges to the South Pond. 8.1.1.2 South Pond (Border Basin) The South Pond is located on the border between Edina and Bloomington, just west of the intersection of Minnesota Drive and West 77th Street. The watershed draining to the South Pond encompasses 211 acres. The land use within the watershed is entirely commercial and industrial, thus highly impervious. In addition to the runoff from the direct watershed, the South Pond receives flow from Centennial Lakes. The City of Edina 2018 Comprehensive Water Resources Management Plan 8-2 South Pond was categorized as a Type 4 wetland in the wetland inventory, a shallow (0.5 to 3 foot), marshy wetland with vegetation such as grasses, cattails, and bulrushes. The normal elevation of the South Pond is controlled at 814.5 feet by a weir structure. Discharge from the South Pond flows west through the storm sewer system along Viking Drive and eventually discharges to the North Fork of Nine Mile Creek. 8.1.1.3 Nine Mile South The Nine Mile South watershed encompasses the area that drains to the North Fork of Nine Mile Creek between West 70th Street and the southern border of Edina. The 758-acre watershed extends to Cahill Road to the west, France Avenue to the east, West 66th Street to the north, and West 78th Street to the south. The watershed is characterized by multiple land uses, including residential, commercial, industrial, highway, and golf course. The portion of the watershed west of the North Fork of Nine Mile Creek is almost entirely commercial and industrial, thus highly impervious. The northern portion is low-density residential. The southeast portion consists mainly of high-density residential buildings, a large commercial and industrial area, and the Fred Richards Golf Course. The golf course is characterized by a series of ponding basins that receive runoff from an area of approximately 183 acres. Discharge from the golf course ponds flows southward through a storm sewer system located between the 4700 and 4660 West 77th Street properties. This system connects to the trunk system that flows westward from the South Pond to the North Fork of Nine Mile Creek. 8.2 Stormwater System Results 8.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Nine Mile Creek- South drainage basin. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis Table 8.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analyses for the Nine Mile Creek—South drainage basin are summarized in Table 8.3. Figure 8.3 illustrates the results of the 10- and 1-percent-annual-chance hydraulic analyses. The figure depicts the boundaries of the drainage areas, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 8.3 illustrates that several XP-SWMM nodes within the Nine Mile Creek—South drainage basin are predicted to surcharge during both the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to City of Edina 2018 Comprehensive Water Resources Management Plan 8-3 meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the Nine Mile Creek—South drainage basin, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin.. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 8.3. Discussion and recommended improvement considerations for these areas are included in Section 8.3. 8.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 8.4 depicts the results of the water quality modeling for the Nine Mile Creek—South drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. Implementation Considerations 8.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 8.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Nine Mile Creek—South drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for problem areas. These preliminary corrective measures are also discussed below. As the City evaluates flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. City of Edina 2018 Comprehensive Water Resources Management Plan 8-4 The 2003 hydrologic and hydraulic modeling analyses identified several locations within the Nine Mile Creek –South drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done in those areas since 2003. 8.3.1.1 West 70th Street and West Shore Drive (NMS_38 and NMS_50) Approximately 42 acres drain to the local depression at the intersection of West 70th Street and West Shore Drive. A 36-inch storm sewer drains this intersection to the west to approximately TH 100, where the storm sewer size increases to 42-inch and 48-inch pipes and eventually drains to Nine Mile Creek. Water pools in this intersection until it reaches the surface overflow elevation of approximately 869.4 feet (according to LiDAR data) and flows west. The 1-percent-annual-chance flood level is determined by the 24-hour precipitation event and is 869.4 feet. Four principle structures (4701 West 70th Street, and 6905 through 6913 West Shore Drive) are potentially impacted at this intersection and the depth of flooding is approximately 2.0 feet. Additional flow capacity is needed in the West 70th Street system. Additionally, in conjunction with future road reconstruction, a second option would be to lower the high elevation along West 70th Street to the west of the intersection. This would allow for the pooled water to overflow at a lower elevation and limit the peak flooding elevation and extents. Another potential option to reduce flood risk at this intersection is to divert high flows within the existing storm sewer system along West 70th Street southward to the low area in Arnesen Acres Park (LE_54). Further analysis is warranted. 8.3.1.2 Centennial Lakes (CL_1) Centennial Lake is located in the southeast portion of Edina, east of France Avenue and north of Interstate 494 (I-494) within Centennial Lakes Park. Approximately 208 acres drain to Centennial Lake. Water levels in the lake are controlled by a 25-foot long weir structure at elevation 838.04 feet, with a 60- inch pipe that conveys runoff to the Border Basin (SP_1) and eventually to the North Fork of Nine Mile Creek. Modeling results indicate that during the 1-percent-annual-chance 24-hour storm event the peak flood level is 842.3 feet. The storage options around this area are limited and the overall capacity of the outlet could be enlarged to pass more water through the system. However, current flood levels downstream are already elevated and increasing drainage capacity from Centennial Lakes Park may cause further impacts downstream. It is recommended that a survey be conducted to determine low entry elevations for structures adjacent to Centennial Lake. Given the existing flood issues downstream of Centennial Lakes and limited potential for upstream storage, flood-proofing may be the most appropriate strategy to address flood risk in this area. It appears that the structures along the north part of Centennial Lakes have a minimal number of entry locations directly adjacent to the lake; flood proofing may not be necessary in this area. Toward the south end of Centennial Lakes, there are several structures with low entries facing the lake. A 3-foot floodwall around the lake would provide approximately 1 foot of freeboard above the 1-percent-annual-chance flood level. City of Edina 2018 Comprehensive Water Resources Management Plan 8-5 Additional storage could also be created in Centennial Lakes by drawing the lake down during dry periods in anticipation of storm events. This could be accomplished in a number of ways. The current weir structure could be modified to include a small orifice below the existing weir crest. The orifice could be fitted with a gate valve for periodic use if preferred. Alternatively, the valve could be fitted with automatic controls that are based on weather prediction. Another approach could be periodically pumping the lake level down using a small lift station near the outlet, which could be controlled manually or automatically based on weather prediction. 8.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the annual removal of total phosphorus from several ponds in the Nine Mile Creek—South drainage area was below the desired 60 percent removal rate. For ponds with total phosphorus removal below 60 percent, the permanent pool storage volume was analyzed to determine whether additional capacity was necessary. The ponds with deficiencies in total phosphorus removal and permanent pool volume are listed below (and are also summarized in Appendix D), with recommended pond upgrades. Construction of new or expansion of existing water quality basins is one way to increase pollutant removal prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. A large portion of stormwater runoff from the Nine Mile Creek—South drainage basin drains through the storm sewer system directly to the North Fork of Nine Mile Creek without any water quality treatment prior to entering the creek. The large area draining directly to the Creek (approximately 500 acres) is depicted on Figure 8.4. To remove pollutants and improve the quality of the discharge to Nine Mile Creek, it is recommended that the City consider installation of a water quality treatment basin upstream of the discharge location at West 77th Street and TH 100 (discussed in additional detail below), as well as other water quality treatment techniques as opportunities arise. 8.3.2.1 West 77th Street and TH 100 The southwest portion of the Nine Mile Creek—South drainage basin is an industrial, highly impervious area. Stormwater from this area is collected via storm sewer and discharged to the North Fork of Nine Mile Creek without any water quality treatment. Construction of a water quality basin in the southwest quadrant of the intersection of TH 100 and West 77th Street is being considered to provide some pollutant removal prior to discharge. The basin will receive runoff from an area of approximately 50 acres along Industrial Boulevard. Based on the MPCA-recommended design criteria for permanent pool storage in detention basins, the total required dead storage volume for this basin is 4.4 acre-feet. City of Edina 2018 Comprehensive Water Resources Management Plan 8-6 8.3.2.2 NMS_76 Pond NMS_76 is located on the east side of the Fred Richards Golf Course, just northwest of the intersection of West 76th Street and Parklawn Avenue. The pond receives runoff from an area of approximately 120 acres. The pond outlets to Pond NMS_104 via a 108-inch “round equivalent” arch pipe. The pond is a Type 5 wetland and was assumed to have an average depth of 4 feet. Based on this assumed depth and the 2-foot topographic data, the permanent pool storage volume was estimated to be 4.4 acre-feet in 2004. According to NURP pond design standards, this storage volume is inadequate. In 2008, the City removed approximately 0.9 acre-feet of sediment from Pond NMS_76. To upgrade the pond to meet the NURP standards, an additional 1.6 acre-feet of dead storage volume is recommended. 8.3.2.3 NMS_104 Pond NMS_104 is located along the southeast border of the Fred Richards Golf Course, just north of the parking lot for the Pentagon Park office complex. In addition to runoff from adjacent parking lots, this detention basin receives discharge from Pond NMS_76. Based on the wetland inventory, the pond is a Type 5 wetland and was assumed to have an average depth of 4 feet. Pond NMS_104 is connected to the downstream pond NMS_72 by two 30-inch equalizer pipes. According to MPCA recommendations, there is not an adequate amount of permanent pool storage in this basin. It is recommended that an additional 0.2 acre-feet of dead storage volume be provided. 8.3.2.4 NMS_72 and NMS_74 Ponds NMS_72 and NMS_74 are located within the Fred Richards Golf Course, connected by a 36-inch equalizer pipe. Pond NMS_72 is upstream of NMS_74 and receives discharge from Pond NMS_79 and NMS_104, as well as runoff from the 7-acre direct watershed. Pond NMS_74 receives discharge from NMS_72 in addition to runoff from the 6.5-acre direct watershed. Based on the wetland inventory, both ponds are Type 5 wetlands and were assumed to have an average depth of 4 feet. Considering this depth and the 2-foot topographic information, the permanent pool storage volume of each pond is greater than the MPCA-recommended volume for detention ponds. However, because water quality modeling results indicate that the total phosphorus removal in Ponds NMS_72 and NMS_74 is below desired levels, it is recommended that the depth of the ponds be increased to improve removal efficiency. 8.3.2.5 SP_1 (South Pond/Border Basin) Pond SP_1 is located on the border between Edina and Bloomington, just west of the intersection of Minnesota Drive and West 77th Street. In addition to stormwater runoff from a large, highly impervious 215-acre watershed, Pond SP_1 receives discharge from Centennial Lakes. The water level in Pond SP_1 is controlled by a weir structure. Discharge from the pond flows to the North Fork of Nine Mile Creek on the west side of TH 100, just south of the West 77th Street crossing. The pond is a Type 4 wetland and was assumed to have an average depth of 2 feet. Based on this depth and the pond area from the 2-foot topographic data, the existing dead storage volume was calculated to be 6.8 acre-feet, which is less than the MPCA-recommended permanent pool storage volume for this basin. It is recommended that an additional 19.6 acre-feet of dead storage volume be provided to meet the MPCA design criteria for detention basins and improve the efficiency of total phosphorus removal. Table 8.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - South Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) CL_1 56.0 69 446 29.0 10.6 33.6 201 15.2 CL_10 0.9 50 10 0.4 0.2 0.6 5 0.2 CL_11 1.4 70 17 0.7 0.3 0.9 9 0.4 CL_12 1.5 35 16 0.6 0.3 0.9 8 0.3 CL_13 8.4 66 64 4.3 1.6 5.0 29 2.3 CL_14 3.8 42 31 1.8 0.7 2.3 14 0.9 CL_15 3.0 27 25 1.2 0.6 1.8 10 0.5 CL_16 3.9 67 38 2.0 0.7 2.4 18 1.1 CL_17 2.6 75 27 1.4 0.5 1.6 14 0.8 CL_18 1.9 65 22 1.0 0.4 1.1 12 0.5 CL_19 1.6 46 17 0.7 0.3 0.9 9 0.3 CL_1a 1.2 50 12 0.6 0.2 0.7 6 0.3 CL_20 11.7 50 89 5.4 2.2 7.0 37 2.7 CL_21 1.9 75 21 1.0 0.4 1.1 11 0.5 CL_22 2.7 75 23 1.4 0.5 1.6 11 0.8 CL_23 3.8 75 32 2.0 0.7 2.3 15 1.1 CL_25 5.0 72 48 2.7 0.9 3.0 24 1.4 CL_27 9.5 80 54 5.2 1.8 5.7 25 2.8 CL_3 8.2 50 66 3.8 1.5 4.9 28 1.9 CL_35 2.9 80 33 1.6 0.6 1.7 18 0.9 CL_38 5.3 51 48 2.5 1.0 3.1 21 1.2 CL_4 3.3 46 34 1.5 0.6 2.0 17 0.7 CL_48 8.9 80 74 4.9 1.7 5.3 36 2.7 CL_49 4.3 80 39 2.4 0.8 2.6 19 1.3 CL_5 7.5 44 53 3.4 1.4 4.5 22 1.6 CL_50 3.8 80 34 2.1 0.7 2.3 16 1.1 CL_51 5.2 80 48 2.9 1.0 3.1 24 1.5 CL_52 1.6 80 17 0.9 0.3 1.0 9 0.5 CL_53 4.6 80 33 2.5 0.9 2.8 15 1.4 CL_53a 1.1 80 10 0.6 0.2 0.7 5 0.3 CL_53b 2.0 80 20 1.1 0.4 1.2 10 0.6 CL_54 3.2 72 35 1.7 0.6 1.9 18 0.9 CL_55 5.8 80 48 3.2 1.1 3.5 23 1.7 CL_56 4.6 79 45 2.5 0.9 2.7 23 1.4 CL_57 3.2 58 29 1.7 0.6 1.9 14 0.9 CL_58 0.9 80 11 0.5 0.2 0.6 6 0.3 CL_59 0.7 80 8 0.4 0.1 0.4 4 0.2 CL_60 1.5 80 15 0.8 0.3 0.9 8 0.4 CL_61 3.4 80 31 1.9 0.7 2.1 15 1.0 CL_62 0.9 80 9 0.5 0.2 0.6 4 0.3 CL_8 1.8 50 19 0.8 0.3 1.1 9 0.4 CL_9 2.4 50 19 1.1 0.5 1.4 8 0.5 EdCrk17 7.8 73 91 4.5 1.5 4.7 50 2.5 EdCrk18 4.8 75 55 2.8 0.9 2.9 30 1.6 EdCrk19 4.3 53 45 2.4 0.8 2.6 24 1.3 EdCrk20 23.4 66 163 13.5 4.4 14.0 80 7.5 NMS_10 4.7 76 44 2.8 0.9 2.8 23 1.6 NMS_100 3.4 70 34 2.0 0.6 2.1 18 1.1 NMS_101 2.4 75 21 1.3 0.4 1.4 11 0.7 NMS_102 2.8 20 25 1.4 0.5 1.7 13 0.7 NMS_103 8.2 19 60 4.4 1.6 4.9 30 2.3 NMS_104 6.3 57 63 3.6 1.2 3.8 33 2.0 NMS_105 2.8 75 26 1.6 0.5 1.7 13 0.9 NMS_106 3.5 75 32 1.9 0.7 2.1 16 1.0 NMS_107 3.2 74 30 1.8 0.6 1.9 15 1.0 NMS_108 12.8 80 74 7.3 2.4 7.7 36 4.0 NMS_11 4.0 80 30 2.4 0.8 2.4 15 1.3 NMS_12 4.4 80 33 2.6 0.8 2.6 16 1.4 NMS_13 10.9 80 81 6.3 2.1 6.6 40 3.5 NMS_14 11.1 69 79 6.1 2.1 6.7 38 3.3 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 8.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - South Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NMS_15 7.7 75 65 4.3 1.5 4.6 33 2.3 NMS_16 9.0 80 67 5.1 1.7 5.4 33 2.8 NMS_18 5.8 75 49 3.2 1.1 3.5 24 1.7 NMS_19 1.2 80 11 0.7 0.2 0.7 6 0.4 NMS_20 5.4 75 50 3.1 1.0 3.2 26 1.7 NMS_21 3.1 75 28 1.6 0.6 1.8 13 0.9 NMS_22 8.7 77 79 5.1 1.6 5.2 41 2.8 NMS_23 0.5 29 5 0.3 0.1 0.3 3 0.2 NMS_24 3.3 25 24 1.5 0.6 2.0 11 0.7 NMS_25 6.4 74 45 3.4 1.2 3.8 20 1.8 NMS_26 3.2 52 31 1.5 0.6 1.9 14 0.8 NMS_27 17.9 79 118 10.2 3.4 10.7 58 5.6 NMS_28 23.0 68 155 12.5 4.3 13.8 73 6.7 NMS_29 12.2 68 100 6.3 2.3 7.3 46 3.3 NMS_30 10.2 75 48 5.6 1.9 6.1 22 3.0 NMS_31 17.0 78 105 9.8 3.2 10.2 52 5.4 NMS_31a 2.0 75 22 1.1 0.4 1.2 12 0.6 NMS_32 8.7 74 62 5.1 1.6 5.2 31 2.8 NMS_33 2.3 73 26 1.3 0.4 1.4 14 0.7 NMS_34 0.6 71 7 0.4 0.1 0.4 4 0.2 NMS_35 0.6 63 6 0.3 0.1 0.3 3 0.2 NMS_36 1.2 53 14 0.7 0.2 0.7 8 0.4 NMS_37 10.4 71 91 5.5 2.0 6.2 44 2.9 NMS_38 24.2 25 129 10.6 4.5 14.5 53 5.0 NMS_39 7.0 65 48 3.9 1.3 4.2 23 2.1 NMS_4 3.8 77 35 2.2 0.7 2.3 18 1.3 NMS_40 21.8 55 165 11.2 4.1 13.0 78 5.8 NMS_41 6.9 31 65 3.2 1.3 4.2 32 1.6 NMS_42 3.9 80 25 2.1 0.7 2.3 12 1.2 NMS_43 3.4 81 34 2.0 0.6 2.0 18 1.1 NMS_44 5.0 37 56 2.3 0.9 3.0 29 1.1 NMS_45 6.7 75 59 3.7 1.3 4.0 28 2.0 NMS_46 7.2 25 68 3.2 1.4 4.3 34 1.6 NMS_47 14.1 25 93 6.2 2.7 8.4 40 3.0 NMS_48 4.6 25 38 2.1 0.9 2.8 18 1.0 NMS_49 11.2 25 90 5.0 2.1 6.7 42 2.4 NMS_5 2.0 75 22 1.2 0.4 1.2 12 0.7 NMS_50 17.9 25 104 7.9 3.4 10.7 44 3.7 NMS_51 14.6 75 71 7.8 2.7 8.8 31 4.1 NMS_52 5.7 20 42 2.7 1.1 3.4 20 1.3 NMS_53 3.5 63 34 2.0 0.7 2.1 18 1.1 NMS_54 1.3 48 14 0.6 0.2 0.8 8 0.3 NMS_55 9.0 62 74 4.8 1.7 5.4 36 2.5 NMS_56 2.9 80 29 1.6 0.6 1.8 14 0.9 NMS_57 11.4 75 61 6.4 2.1 6.9 29 3.5 NMS_58 5.8 75 51 3.2 1.1 3.5 25 1.7 NMS_59 1.3 64 15 0.7 0.2 0.8 8 0.4 NMS_6 13.5 77 85 7.3 2.5 8.1 39 3.9 NMS_60 1.6 76 17 0.9 0.3 1.0 9 0.5 NMS_61 0.8 75 9 0.4 0.2 0.5 5 0.2 NMS_62 6.6 76 40 3.6 1.2 3.9 19 1.9 NMS_63 4.9 64 44 2.7 0.9 2.9 22 1.4 NMS_64 17.7 75 99 9.7 3.3 10.6 46 5.2 NMS_65 2.4 75 21 1.4 0.4 1.4 11 0.8 NMS_66 4.5 43 34 2.0 0.8 2.7 14 1.0 NMS_67 1.9 52 19 0.9 0.4 1.1 9 0.4 NMS_68 2.5 25 26 1.0 0.5 1.5 12 0.4 NMS_69 4.5 42 40 2.1 0.9 2.7 18 1.0 NMS_7 16.1 78 84 9.1 3.0 9.7 40 4.9 NMS_70 11.6 51 69 5.4 2.2 7.0 28 2.6 Table 8.2 Watershed Modeling Results for Subwatersheds in the Nine Mile Creek - South Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NMS_71 4.4 78 30 2.4 0.8 2.6 14 1.3 NMS_72 7.3 12 48 3.9 1.4 4.3 23 2.1 NMS_73 6.7 50 53 3.3 1.3 4.0 24 1.6 NMS_74 6.5 19 44 3.6 1.2 3.9 22 1.9 NMS_75 5.3 68 48 3.1 1.0 3.2 25 1.7 NMS_76 10.8 39 91 5.8 2.0 6.5 46 3.1 NMS_77 7.2 39 50 3.3 1.4 4.3 21 1.6 NMS_78 2.5 50 21 1.2 0.5 1.5 9 0.6 NMS_79 6.6 9 37 3.6 1.2 4.0 18 1.9 NMS_8 2.9 75 32 1.6 0.6 1.7 16 0.8 NMS_80 3.5 60 33 1.7 0.7 2.1 16 0.9 NMS_81 11.5 55 92 5.6 2.2 6.9 41 2.9 NMS_82 7.8 25 61 3.1 1.5 4.7 24 1.4 NMS_83 3.6 25 29 1.5 0.7 2.1 13 0.7 NMS_84 11.8 12 64 5.9 2.2 7.1 29 2.9 NMS_85 3.1 74 18 1.7 0.6 1.8 9 0.9 NMS_86 3.1 25 30 1.3 0.6 1.9 14 0.6 NMS_87 1.1 25 10 0.4 0.2 0.6 5 0.2 NMS_88 3.6 26 31 2.0 0.7 2.2 16 1.1 NMS_89 7.2 69 50 3.8 1.3 4.3 22 2.0 NMS_90 6.7 50 58 3.1 1.3 4.0 25 1.5 NMS_91 4.0 73 34 2.1 0.8 2.4 16 1.1 NMS_92 6.3 80 47 3.5 1.2 3.8 22 1.9 NMS_93 5.1 70 45 2.8 1.0 3.0 22 1.5 NMS_94 1.3 25 13 0.7 0.2 0.8 7 0.3 NMS_95 8.0 80 65 4.7 1.5 4.8 33 2.6 NMS_96 5.8 80 42 3.4 1.1 3.5 21 1.9 NMS_97 9.4 80 71 5.5 1.8 5.6 35 3.1 NMS_98 6.8 25 45 3.0 1.3 4.0 20 1.4 NMS_99 4.4 35 45 2.1 0.8 2.6 23 1.0 SP_1 89.8 80 312 51.8 15.3 53.9 147 28.4 SP_10 3.7 77 30 2.2 0.7 2.2 15 1.2 SP_11 5.6 80 34 3.1 1.0 3.3 16 1.7 SP_12 3.5 75 29 1.9 0.7 2.1 13 1.0 SP_13 4.6 80 38 2.6 0.9 2.7 19 1.4 SP_14 0.9 78 9 0.5 0.2 0.5 5 0.3 SP_15 4.6 75 49 2.5 0.9 2.7 26 1.3 SP_16 7.7 79 42 4.2 1.4 4.6 19 2.2 SP_17 7.0 80 40 4.2 1.3 4.2 20 2.3 SP_18 8.5 79 91 4.6 1.6 5.1 48 2.5 SP_2 2.0 80 23 1.1 0.4 1.2 12 0.6 SP_3 3.8 80 38 2.1 0.7 2.3 19 1.1 SP_4 2.6 75 27 1.4 0.5 1.6 14 0.8 SP_5 11.6 80 100 6.9 2.2 7.0 51 3.8 SP_6 28.4 80 167 16.5 5.3 17.1 82 9.1 SP_7 14.9 80 130 8.5 2.8 9.0 66 4.6 SP_8 1.2 80 12 0.7 0.2 0.7 6 0.4 SP_9 10.4 75 74 5.8 2.0 6.2 36 3.2 SP_9a 0.5 76 6 0.3 0.1 0.3 3 0.2 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1005 823.0 821.0 1006 822.8 820.6 1010 822.7 820.3 1011 822.7 820.1 1012 822.7 820.0 1014 822.7 819.9 1015 822.7 819.8 1016 822.7 819.7 1017 822.7 819.8 1019 822.7 820.9 1020 823.1 822.1 1021 822.7 820.7 1025 street 822.7 819.5 1029 822.7 819.3 1222 838.3 838.3 1227 831.8 831.8 1229 830.6 830.6 1230 829.6 829.2 1234 828.3 827.9 1237 827.5 824.8 1238 827.4 824.7 1239 829.9 829.9 1239$I 827.3 824.5 1242 829.2 828.9 1245 833.8 832.9 1248 828.8 826.1 1250 828.2 824.6 1254 823.5 820.0 1492 847.1 843.7 1493 845.1 842.7 1498 842.3 840.4 1500 851.7 847.5 1503 845.2 841.5 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1513 840.8 837.7 1515 837.3 832.8 1516 836.6 831.0 1517 835.8 830.8 1518 834.9 830.8 1519 833.7 830.9 1520 833.2 831.2 1521 835.8 835.6 1522 834.6 832.9 1523 833.8 831.7 1528 842.0 840.0 1529 837.8 836.9 1530 836.0 835.5 1531 834.7 833.9 1534 861.6 855.9 1536 861.2 855.2 1538 861.0 854.5 1539 857.9 852.3 1540 856.5 851.4 1542 854.1 849.4 1544 849.8 846.9 1545 844.5 841.2 1547 863.4 856.1 1549 861.8 853.5 1550 858.8 852.7 1683 853.6 846.3 1685 853.1 846.1 1696 839.3 839.0 1713 844.1 840.8 1718 861.8 856.0 1719 861.4 856.2 1726 863.9 857.7 1840 street 853.7 847.9 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1841 854.0 849.7 1842 854.3 850.9 1843 854.9 852.7 1847 827.7 826.9 1851 street 831.0 828.8 1852 833.1 831.5 1901 838.8 836.5 1902 842.2 839.0 1905 824.1 823.2 1907 821.9 819.3 1910 827.1 826.0 1913 827.8 827.4 2069 872.9 872.6 2102 882.6 881.9 2106 821.9 819.4 2108 821.9 819.6 2256 857.2 850.4 2258 854.7 847.2 2259 853.2 845.8 2260 853.6 846.1 2260a 863.7 862.7 2262 852.4 845.4 2263 851.1 845.0 2264 849.6 844.4 2361 847.6 843.7 2362 846.5 843.1 2363 844.9 842.3 2364 843.5 840.5 2370 859.3 859.0 2372 860.9 856.5 2373 862.4 862.0 2374 862.4 862.0 2376 868.8 868.7 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2379 867.0 866.2 2383 870.5 870.4 2389 853.1 846.0 2442 832.7 826.2 2446 845.6 845.4 2448 821.9 819.3 2584 830.9 830.6 2587 842.3 836.0 2588 840.7 835.6 2590 839.1 832.8 2591 833.5 827.8 2737 822.7 820.7 2738 822.7 820.7 2739 822.7 820.7 2744 822.9 821.1 2746 828.3 826.9 2748 824.7 822.2 2752 858.3 855.6 2753 858.2 853.2 2755 858.6 853.7 2784 836.5 836.0 2788 822.7 820.7 2789.1 822.7 820.7 2820 street 827.7 824.7 2821 829.3 827.9 2860 860.6 856.8 2861 860.6 857.8 2862 860.8 858.6 2863 860.8 859.0 2864 860.9 859.6 2866 833.1 827.4 2882 822.7 820.2 2884.1 822.1 819.1 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2886 828.0 827.2 2887 828.1 827.4 2889 828.8 827.9 2892 829.7 828.9 2893 829.7 829.0 2894 829.7 829.0 2896 845.5 845.3 2897 844.6 841.9 2898 843.9 841.9 2899 843.6 841.9 2909 832.1 830.4 2910 831.6 830.7 2911 833.7 833.2 2932 828.4 828.3 2933 832.0 831.4 2934 834.9 834.5 2973.1 822.7 819.3 2974.1 822.7 819.3 898 866.7 866.5 899 866.5 866.3 901 863.4 863.0 903 859.0 854.9 935 863.6 862.1 936 855.7 855.3 937 850.6 849.9 940 860.4 860.4 941 847.7 847.4 942 846.7 845.3 944 846.4 844.7 947 842.6 840.2 948 836.2 834.8 951 844.8 844.0 955 870.1 868.4 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 956 862.8 862.6 958 858.6 858.4 959 846.2 845.8 968 834.5 833.3 972 832.1 831.8 973 831.3 830.4 975 829.8 829.1 976 828.8 828.0 978 827.0 825.8 982 832.6 832.3 983 836.2 835.7 986 826.1 824.9 987 826.1 824.8 990 826.1 825.7 992 828.0 826.5 993 829.0 826.8 996 826.7 826.5 CL_1 pond 838.0 842.3 4.3 840.4 2.4 CL_10 847.0 844.8 CL_11 842.3 840.4 CL_12 851.5 845.7 CL_13 861.3 855.0 CL_14 861.8 856.2 CL_15 cul-de-sac 861.1 860.1 CL_16 863.6 853.7 CL_17 parking lot 850.1 848.9 CL_18 856.8 851.2 CL_19 street 852.9 848.2 CL_1a street 861.7 861.6 CL_20 855.8 850.8 CL_21 862.6 854.0 CL_22 parking lot 864.6 859.2 CL_23 864.9 859.8 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 CL_25 street 860.7 855.8 CL_27 street/lot 857.9 852.8 CL_3 856.8 855.8 CL_35 869.1 868.9 CL_38 parking lot 858.9 858.1 CL_4 850.5 845.3 CL_48 parking lot 865.8 859.8 CL_49 862.5 862.4 CL_5 865.2 859.6 CL_50 parking lot 870.8 870.6 CL_51 parking lot 862.1 860.1 CL_52 862.4 862.0 CL_53 848.6 844.1 CL_53a 851.7 851.4 CL_53b 853.9 851.2 CL_54 858.2 852.5 CL_55 866.1 865.8 CL_56 street 852.9 845.5 CL_57 street 854.1 846.4 CL_58 street 853.1 845.9 CL_59 856.0 855.2 CL_60 parking lot 873.4 873.3 CL_61 parking lot 867.4 866.0 CL_61old 867.4 866.0 CL_62 868.0 867.9 CL_8 parking lot 854.1 849.5 CL_9 852.6 848.6 EdCrk15 828.6 825.5 EdCrk15a 830.7 829.2 EdCrk15b 829.2 826.9 EdCrk15c 828.7 825.5 EdCrk16 828.3 825.0 EdCrk16a 828.6 825.4 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 EdCrk16b 828.5 825.2 EdCrk16c 828.5 825.1 EdCrk17 827.2 824.2 EdCrk17a 827.4 824.6 EdCrk18 creek 826.4 822.8 EdCrk18a 826.8 823.6 EdCrk19 creek 823.7 820.5 EdCrk19a_1 825.4 821.4 EdCrk20 821.7 818.8 EdCrk20a 822.3 819.8 EdCrk20b 821.9 819.3 FID5954 834.2 832.8 FID6262 847.9 847.2 FID6580 867.8 865.4 N399 860.0 859.3 N403 821.9 819.6 N409 830.3 830.2 N416 830.7 830.1 N435 859.7 859.3 N436 825.3 825.0 NMS_10 street 821.9 821.0 NMS_100 street 821.9 819.3 NMS_101 parking lot 832.9 829.0 NMS_102 byd 827.8 827.3 NMS_103 pond 818.2 823.2 5.0 822.2 4.0 NMS_104 pond 818.3 823.2 4.9 822.2 3.9 NMS_105 831.5 831.3 NMS_106 parking lot 839.7 835.5 NMS_107 ditch 842.0 839.2 NMS_108 street/lot 822.7 820.6 NMS_11 street/lot 822.7 820.8 NMS_12 parking lot 822.7 820.1 NMS_13 street/lot 822.4 819.3 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMS_14 parking lot 834.9 834.4 NMS_15 830.8 830.2 NMS_16 street/lot 828.8 825.6 NMS_18 street/lot 834.0 833.4 NMS_19 parking lot 822.7 820.1 NMS_20 street 834.0 833.8 NMS_21 parking lot 831.3 829.5 NMS_22 street 822.7 820.7 NMS_23 pond 818.2 823.2 5.0 822.2 4.0 NMS_24 street/byd 829.7 829.2 NMS_25 837.7 837.4 NMS_26 835.6 835.3 NMS_27 parking lot 828.0 825.4 NMS_28 wetland 825.0 829.2 4.2 827.9 2.9 NMS_29 ditch 837.0 836.0 NMS_30 parking lot 828.4 827.9 NMS_31 parking lot 827.7 826.9 NMS_31a pond 824.2 827.7 3.5 826.9 2.7 NMS_32 832.1 830.4 NMS_33 street 831.3 825.6 NMS_34 827.2 824.2 NMS_35 828.5 825.9 NMS_36 830.0 828.7 NMS_37 844.1 843.9 NMS_38 street 869.4 868.0 NMS_39 831.4 831.3 NMS_4 824.6 824.4 NMS_40 pond 836.3 844.6 8.3 843.4 7.1 NMS_41 886.4 886.2 NMS_42 street/lot 830.8 830.3 NMS_43 parking lot 822.7 820.2 NMS_44 831.6 829.9 NMS_45 831.1 830.9 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMS_46 884.0 883.8 NMS_47 street 848.2 847.8 NMS_48 street 844.5 843.6 NMS_49 street 845.2 844.8 NMS_5 828.1 823.0 NMS_50 street 869.4 866.7 NMS_51 parking lot 833.2 832.4 NMS_52 826.5 825.9 NMS_53 parking lot 829.2 828.9 NMS_54 845.6 845.5 NMS_55 street 844.6 841.7 NMS_56 parking lot 828.7 828.4 NMS_57 parking lot 828.9 828.1 NMS_58 parking lot 828.4 827.7 NMS_59 street 845.5 845.2 NMS_6 parking lot 840.3 839.9 NMS_60 street 850.8 846.3 NMS_61 838.5 836.2 NMS_62 street 828.4 827.9 NMS_63 hwy ditch 825.7 825.3 NMS_64 field 835.7 835.4 NMS_65 parking lot 833.8 833.5 NMS_66 841.9 839.1 NMS_67 838.9 838.5 NMS_68 836.7 836.4 NMS_69 830.0 829.4 NMS_7 street/lot 830.7 827.7 NMS_70 street 826.2 825.0 NMS_71 839.2 838.9 NMS_72 pond 818.2 823.2 5.0 822.2 4.0 NMS_73 831.8 831.4 NMS_74 pond 818.2 823.2 5.0 822.2 4.0 NMS_75 parking lot 824.6 822.5 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMS_76 pond 818.8 826.0 7.2 824.7 5.9 NMS_77 street 828.3 827.2 NMS_78 street 828.3 827.4 NMS_79 pond 818.2 823.2 5.0 822.2 4.0 NMS_8 843.0 839.4 NMS_80 parking lot 827.7 827.6 NMS_81 847.6 847.4 NMS_82 836.0 835.5 NMS_83 street 834.5 833.2 NMS_84 field 826.2 825.1 NMS_85 829.7 828.5 NMS_86 835.9 835.6 NMS_87 834.5 833.8 NMS_88 pond 818.2 823.2 5.0 822.2 4.0 NMS_89 827.0 826.3 NMS_90 839.9 836.7 NMS_91 843.6 843.4 NMS_92 830.8 830.5 NMS_93 street 826.1 824.8 NMS_94 street 832.3 831.5 NMS_95 street/lot 822.7 820.7 NMS_96 parking lot 823.1 822.2 NMS_97 parking lot 822.7 820.0 NMS_98 street 870.2 870.0 NMS_99 845.9 845.6 SP_1 pond 814.7 822.7 8.0 820.3 5.6 SP_10 street 824.6 824.4 SP_11 parking lot 829.6 828.4 SP_12 838.2 838.1 SP_13 loading dock 827.9 827.6 SP_14 823.2 821.3 SP_15 834.5 832.4 SP_16 parking lot 829.6 828.9 Table 8.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile Creek - South Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 SP_17 parking lot 826.2 823.4 SP_18 parking lot 834.9 833.5 SP_2 850.9 850.7 SP_3 839.8 835.8 SP_4 837.4 832.9 SP_5 street 822.7 820.5 SP_6 824.5 822.1 SP_7 831.2 829.6 SP_8 parking lot 843.4 841.8 SP_9 parking lot 823.9 822.6 SP_9a depression 823.7 822.3 §¨¦494 62 100 456717 456731 456728 W 77th St Parklawn Ave W American Blvd Hazelton Rd Normandale Rd Minnesota Dr Dewey Hill Rd BloomingtonBloomington RichfieldRichfield NorthBra nc h N in e Mile C reek SP_1 CL_1 SP_6 NMS_38 EdCrk20 NMS_28 SP_7 NMS_3 NMS_40 NMS_7 NMS_27 NMS_50 NMS_64 SP_5 NMS_31 SP_9 NMS_6 CL_20 NMS_51 NMS_47 CL_3 NMS_29 CL_27 NMS_84 NMS_70 NMS_81 CL_5 CL_48 NMS_57 NMS_108 NMS_14 NMS_13 CL_13 NMS_76 SP_18 NMS_37 NMS_30 SP_16 NMS_97 NMS_16 SP_17 NMS_22 NMS_95 NMS_82 NMS_15 CL_55 NMS_103 NMS_72 NMS_46 NMS_77 SP_11 NMS_39 NMS_41 NMS_98 NMS_45 NMS_73 CL_38 NMS_90 CL_51 NMS_79 NMS_74 NMS_25 NMS_92 CL_53 NMS_75 CL_56 NMS_58 NMS_18 NMS_96 SP_13 NMS_52 NMS_104 NMS_93 CL_16 CL_4 CL_50 CL_23 NMS_63 CL_14 SP_10 CL_61 NMS_12 NMS_71 NMS_4 EdCrk19 NMS_11 SP_4 NMS_42 CL_9 NMS_88 NMS_83 CL_17 NMS_21 NMS_107 NMS_49 NMS_55 NMS_32 EdCrk17 NMS_89 NMS_62 CL_25 SP_3 SP_15 CL_49 NMS_20 NMS_44 EdCrk18 NMS_10 NMS_48 NMS_69 NMS_66 NMS_99 SP_12 CL_57 CL_54 NMS_91 CL_15 CL_35 NMS_53 NMS_80 CL_22NMS_43 NMS_8 NMS_24 NMS_26 NMS_86 NMS_85 NMS_106 SP_2 NMS_100 NMS_56 CL_8 NMS_68 NMS_78 NMS_105 NMS_102 CL_21 CL_18NMS_5 NMS_65 NMS_33 CL_53b NMS_101 CL_52 CL_19 CL_12 CL_60 NMS_67 CL_11 SP_8NMS_31a NMS_60 CL_1a NMS_94 NMS_54NMS_59 CL_53a CL_62 CL_58NMS_36 CL_10 NMS_19 SP_14 NMS_87 CL_59 NMS_61 SP_9a NMS_34 NMS_35 NMS_23 Centennial Lakes Barr Footer: ArcGIS 10.4.1, 2017-09-21 11:53 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_8_1_NMC_South_Drainage_Basins.mxd User: rcs2FIGURE 8.1 0 1,200 Feet !;N Nine Mile Creek - SouthDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NINE MILE CREEK - SOUTHDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota §¨¦494 62 100 456717 456731 456728 W 77th St Parklawn Ave W American Blvd Hazelton Rd Normandale Rd Minnesota Dr Dewey Hill Rd Nine Mile South South Pond Centennial Lakes BloomingtonBloomington RichfieldRichfield NorthBra nc h N in e Mile C reek Centennial Lakes Barr Footer: ArcGIS 10.4.1, 2017-09-21 11:55 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_8_2_NMC_South_Major_Watersheds.mxd User: rcs2FIGURE 8.2 0 1,200 Feet !;N Nine Mile Creek - SouthDrainage Basin Major Watershed Centennial Lakes Nine Mile South South Pond Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NINE MILE CREEK - SOUTHMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota City of Edina 2018 Comprehensive Water Resources Management Plan 8-24 Figure 8.3 Nine Mile Creek—South Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. NMS_76NMS_79 NMS_88 NMS_72NMS_103 NMS_104 SP_1 NMS_23 NMS_40 NMS_28 NMS_84 NMS_74 NMS_74 CL_1 CL_1 AH_1 BloomingtonBloomington RichfieldRichfield NineMi leCreek Barr Footer: ArcGIS 10.4.1, 2017-09-21 08:35 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_8_4_NMC_South_Water_Quality.mxd User: rcs2NINE MILE CREEK SOUTHWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 8.4 1,200 0 1,200Feet !;N 400 0 400Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to the NorthFork of Nine Mile Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 9-1 9.0 Nine Mile South Fork 9.1 General Description of Drainage Area Figure 9.1 depicts the drainage area to the South Fork of Nine Mile Creek and the individual subwatersheds within this area. The Nine Mile South Fork drainage basin is located in the southwest corner of Edina and includes a small portion of Eden Prairie. Several land-locked lakes are located within this drainage basin, including Arrowhead Lake and Indianhead Lake. These areas would become tributary to the South Fork of Nine Mile Creek only under extreme flooding circumstances (storms greater than the 1-percent-annual-chance storm event). 9.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ditches, overland flow paths, wetlands, and ponding basins. The Nine Mile South Fork drainage basin has been divided into several major watersheds based on the drainage patterns. These major watersheds are depicted on Figure 9.2. Each major watershed has been further delineated into many subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located Table 9.1 lists each major watershed and the associated subwatershed naming convention. Table 9.1 Major Watersheds within the Nine Mile South Fork Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Arrowhead Lake AH_## 31 178 Indianhead IH_## 12 108 Pawnee Pond PA_## 13 39 Eden Prairie EP_## 2 217 Braemar Arena/Public Works BA_## 4 27 Nine Mile South Fork NMSB_## / BRCrk## 99 816 9.1.1.1 Arrowhead Lake The Arrowhead Lake watershed extends north of TH 62 and is bordered on the west side by TH 169 and generally bordered on the east and south side by Indian Hills Road/Pass. Land use in the 178-acre watershed mainly single family residential; however, portions of TH 62 and the TH 62/TH 169 intersection are tributary to the lake. Within the watershed there are three stormwater detention basins that ultimately drain to Arrowhead Lake. Arrowhead Lake is a land-locked basin covering approximately 22 acres. 9.1.1.2 Indianhead Lake The Indianhead Lake watershed is located southeast of Arrowhead Lake. Within the 108-acre watershed, there are two stormwater detention basins in addition to the lake. The residential watershed ultimately City of Edina 2018 Comprehensive Water Resources Management Plan 9-2 drains to Indianhead Lake via storm sewer networks and overland flow channels. Indianhead Lake is a land-locked basin covering approximately 14 acres. 9.1.1.3 Pawnee Pond The Pawnee Pond watershed is approximately 39 acres. The watershed is a residential area consisting of two stormwater detention basins, Pawnee Pond, and a smaller basin east of the intersection of Apache Road and Sally Lane. The Pawnee Pond is located directly north of Apache Road, bordered by Indian Way West on the west, Pawnee Road on the east, and Indian Hills Road on the north. The normal elevation of Pawnee Pond is controlled at an elevation of 862 feet by a pumped outlet. The outflow from Pawnee Pond flows westerly through a cross-culvert beneath TH 169, then south on the west side of TH 169, and ultimately into the Braemar Branch of Nine Mile Creek. 9.1.1.4 Eden Prairie The Eden Prairie watershed consists of approximately 217 acres of land west of TH 169 that drains to the South Fork of Nine Mile Creek via the Braemar Branch of Nine Mile Creek. Stormwater runoff from this area flows through a succession of storm sewer systems and ponding basins, eventually outletting to the drainage way that flows south along the west side of TH 169. The Eden Prairie watershed boundaries were based on the watershed divides from the Nine Mile Creek Watershed District Water Management Plan (May 1996). Land use within this area consists mainly of industrial and office property. 9.1.1.5 Braemar Arena/Public Works The Braemar Arena/Public Works watershed includes drainage from the south parking lot of the Braemar Arena, Braemar Boulevard, and the Public Works and Public Safety Training Site. The remaining portion of the Braemar Sports Complex parking lot that does not drain to the south drains westerly to the TH 169 drainage system. The 27-acre Braemar Arena/Public Works watershed drains south through a storm sewer system to a 0.24-acre stormwater detention pond. The water level of this detention pond is controlled at an elevation of 846 feet by a 24-inch-diameter outlet pipe that discharges south to the floodplain of the South Fork of Nine Mile Creek. 9.1.1.6 Nine Mile South Fork The Nine Mile South Fork watershed is composed of 99 subwatersheds that drain through the drainage system of the Braemar Golf Course, ultimately discharging to the South Fork of Nine Mile Creek. The 816-acre watershed has a wide range of land uses, including residential, industrial, wetlands, open area/park, and the golf course. The stormwater system throughout this area is characterized by storm sewer, ditches, ponds, and overland flow networks. The extent of the Nine Mile South Fork watershed spans west of TH 169, where drainage from the Washington Avenue storm sewer system combines with flows from the Eden Prairie and Pawnee Pond watersheds. This stormwater flows easterly under TH 169 through a large culvert, midway between Hamilton Road and West 69th Street, and discharges to the Braemar Branch of Nine Mile Creek. The Braemar Branch drains southward through Braemar Park towards the Braemar Golf Course. The Braemar Branch flows through several ponding basins on the west side of the golf course before discharging to the South Fork. Stormwater from the remaining portion of the Nine City of Edina 2018 Comprehensive Water Resources Management Plan 9-3 Mile South Fork watershed flows through a series of storm sewer pipes, wetlands, and ponds on the east side of the Braemar Golf Course before reaching the South Fork of Nine Mile Creek. 9.2 Stormwater System Results 9.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Nine Mile South Fork Watershed. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis. Table 9.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analyses for the Nine Mile South Fork drainage area are summarized in Table 9.3. Figure 9.3 illustrates the results of the 10- and 1-percent-annual-chance hydraulic analyses. The figure depicts the Nine Mile South Fork drainage area boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 9.3 illustrates that several XP-SWMM nodes within the Nine Mile South Fork drainage area are predicted to surcharge during both the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the Nine Mile South Fork drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin.. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 9.3. Discussion and recommended improvement considerations for these areas are included in Section 9.3. 9.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. City of Edina 2018 Comprehensive Water Resources Management Plan 9-4 Figure 9.4 depicts the results of the water quality modeling for the Nine Mile South Fork drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 9.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 9.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Nine Mile South Fork drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for the problem areas. These preliminary corrective measures are also discussed below. As the City evaluates flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Nine Mile South Fork drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done since 2003. 9.3.1.1 McCauley Trail West (AH_6) A stormwater pond located behind 6533–6545 McCauley Trail West and 6301 Timber Trail receives runoff from approximately 39.3 acres with approximately 13 acres being direct drainage, mostly north of TH 62. The pond has a 21-inch gravity drain outlet that discharges to land-locked Arrowhead Lake. There is a pumped outlet (Lift Station 8) that appears to be in place to draw the pond down below the outlet elevation, but the pump capacity appears to be very minor compared to the gravity drain capacity. Without definitive information on the pump capacity, and due to its relatively small size, this pump was City of Edina 2018 Comprehensive Water Resources Management Plan 9-5 not included in the modeling. Modeling results indicate that the 1-percent-annual-chance flood elevation (885.0 feet) may impact up to nine principle structures for a duration of approximately 6 hours. Several options to alleviate flooding in this area should be considered, including providing additional outlet capacity and storing additional water upstream. An increase in discharge capacity from the pond could likely reduce the number of principle structures potentially impacted in AH_6 without creating impacts to principle structures around Arrowhead Lake. The 1-percent-chance annual flood elevation in downstream Arrowhead Lake is well below the low houses adjacent to the lake. Additionally, the critical 1- percent-annual-chance event for Arrowhead Lake is the 1-percent-annual-chance 10-day snowmelt—not the 24-hour storm event. A restrictive outlet upstream of TH 62 could also be implemented to store more water in AH_3 during a precipitation event and limit the amount of water contributing to AH_6. A restrictive outlet, without changing the invert, would allow for AH_3 to drain dry between events. Finally, there are some options for creating additional stormwater storage. In subwatershed AH_9, there is room for additional regrading work to create additional storage. 9.3.1.2 Sally Lane and Valley View Road (NMSB_52, NMSB_69, and NMSB_77) The ravine located in the backyards of the homes between Sally Lane and McCauley Trail South receives stormwater flows from a 436-acre tributary area that includes portions of Eden Prairie and Edina. This ravine, which is the headwaters of the Braemar Branch of Nine Mile Creek, crosses under Valley View Road through a 6-foot by 11.7-foot box culvert. Modeling results indicate that the 1-percent-annual-chance flood elevations along this ravine may impact up to 19 principle structures (6713–6721 Sioux Trail, 6800– 7008 Sally Lane, 7016, 7020, and 7028 Sally Lane). The storm sewer system at the Paiute Pass and Sally Lane intersection collects stormwater from a total drainage area of approximately 27 acres. The system discharges into the Braemar Branch, west of Sally Lane, via two 24-inch pipes. Flooding issues at the intersection of Sally Lane and Paiute Pass were analyzed in 2013 (Project STS-406). However, that work was focused on the intersection and not the backyards of the principle structures along Sally Lane that are affected by high water levels within the ravine. Some of the recommendations from the 2013 analysis to reduce flood risk at this intersection were implemented as part of the 2016 street reconstruction project. There are several options that should be considered to reduce flood risk in the backyard ravine area, including increasing capacity of the Braemar Branch culvert under Valley View Road and providing additional flood storage in the tributary drainage area. It is recommended that the City work with the NMCWD to evaluate potential impacts of increasing the capacity under Valley View Road. It is also recommended that the City work with the City of Eden Prairie and Nine Mile Creek Watershed District to identify opportunities for increased flood storage upstream of the Braemar Branch. 9.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis predicted that under average conditions the annual removal of total phosphorus from several ponds in the Nine Mile South Fork drainage area would be below the desired 60 percent removal rate. For those ponds with total phosphorus removal below 60 percent, the City of Edina 2018 Comprehensive Water Resources Management Plan 9-6 permanent pool storage volume was analyzed to determine whether additional capacity was necessary. The ponds with deficiencies in total phosphorus removal and permanent pool volume are listed below (and are also summarized in Appendix D), with recommended pond upgrades. Construction of new or expansion of existing water quality basins is one method to increase the pollutant removal achieved prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. 9.3.2.1 NMSB_3 and NMSB_2 Pond NMSB_3 is located on the Braemar Golf Course, southeast of the intersection of Valley View Road and Braemar Boulevard. This pond receives stormwater from an immediate watershed of approximately 21 acres, as well as discharge from the Braemar Branch. The Braemar Branch drains an area of approximately 259 acres and flow from Pond NMSB_33 to the east. The pond is a Type 5 wetland and was assumed to have an average depth of 4 feet. Pond NMSB_2 is downstream of Pond NMSB_3 and connected by a 30-inch equalizer pipe. Pond NMSB_2 receives stormwater from an immediate watershed of approximately 5 acres, as well as the flow from NMSB_3. This pond is also a Type 5 wetland and was assumed to have an average depth of 4 feet. Based on modeling results, the annual removal of total phosphorus from these two ponds was predicted to be below 60 percent. Consequently, the MPCA-recommended permanent pool storage volume for these ponds was calculated and compared to the existing dead storage volume. For the permanent pool volume analysis, the two ponds were considered as one. Based on this assumption, the ponds are deficient in dead storage volume. We recommend that an additional 1.2 acre-feet of dead storage volume be provided to these two ponds to meet the MPCA design criteria for detention basins. 9.3.2.2 NMSB_12 Pond NMSB_12 is located on the Braemar Golf Course, approximately 700 feet southwest of the clubhouse. The pond receives stormwater runoff from the direct watershed of approximately 12 acres, in addition to flow from the upstream wetland NMSB_56. According to the wetland inventory, the pond is a Type 5 wetland and assumed to have an average depth of 4 feet. Based on this depth and the 2-foot topographic information, the current permanent pool storage volume is greater than the MPCA- recommended volume for detention ponds. It is recommended that the basin be maintained on a regular basis to ensure the removal efficiency is maintained. 9.3.2.3 NMSB_86 Pond NMSB_86 is located on the Braemar Golf Course, directly south of the clubhouse parking lot. Pond NMSB_86 is a small pond that receives stormwater runoff from a direct watershed of approximately 21 acres, as well as discharge from the upstream pond (NMSB_57). The pond discharges directly to the City of Edina 2018 Comprehensive Water Resources Management Plan 9-7 South Fork of Nine Mile Creek via a 30-inch pipe. Based on modeling results, the annual removal of total phosphorus from Pond NMSB_86 was predicted to be well below 60 percent. According to the MPCA-recommended storage volume for detention basins, there is not an adequate amount of permanent pool storage in this basin. It is recommended that 0.15 acre-feet of dead storage volume be added to meet the MPCA design criteria for detention basins. 9.3.2.4 NMSB_7 Pond NMSB_7 is located on the Braemar Golf Course on the north side of Braemar Boulevard. Pond NMSB_7 is a small detention pond that receives stormwater runoff from a 2.4-acre watershed in addition to discharge from an upstream wetland (NMSB_90). Pond NMSB_7 discharges to Pond NMSB_85 via a 24-inch pipe. Based on Braemar Golf Course design plans, Pond NMSB_7 was assumed to be shallow, with an average depth of 2.3 feet. Using this depth assumption and the pond area from the 2-foot topographic information, the current permanent pool storage volume was calculated to be 0.6 acre-feet. This volume is greater than the MPCA-recommended storage volume for detention ponds. However, because the water quality modeling results indicate that the total phosphorus removal in Pond NMSB_7 is below 60%, it is recommended that the depth of the pond be increased to 4 feet to improve removal efficiency. 9.3.2.5 NMSB_85 Pond NMSB_85 is located on the Braemar Golf Course, downstream of Pond NMSB_7, on the north side of Braemar Boulevard. Pond NMSB_85 receives stormwater runoff from a 67.5-acre watershed, as well as discharge from Pond NMSB_7 and discharge from a backyard depression area northeast of the intersection of Gleason Road and Dewey Hill Road (NMSB_15). According to the wetlands inventory, the pond is Type 5 and was assumed to have an average depth of 4 feet. Based on this depth assumption and the pond area from the 2-foot topographic data, the current permanent pool storage volume is 1.3 acre- feet. This storage volume is less than the MPCA-recommended storage volume for detention basins. It is recommended that an additional 1.2 acre-feet of dead storage volume be provided to meet the MPCA design criteria for detention basins. Table 9.2 Watershed Modeling Results for Subwatersheds in the Nine Mile South Fork Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) AH_1 50.2 57 394 24.4 9.5 30.1 171 12.4 AH_10 2.0 19 20 0.7 0.4 1.2 9 0.3 AH_11 1.3 26 12 0.7 0.2 0.8 6 0.4 AH_12 1.5 25 16 0.7 0.3 0.9 8 0.3 AH_13 4.3 20 33 2.2 0.8 2.6 16 1.1 AH_15 1.2 25 11 0.5 0.2 0.7 6 0.3 AH_16 0.4 28 5 0.2 0.1 0.3 3 0.1 AH_17 4.9 25 40 1.9 0.9 2.9 16 0.8 AH_18 2.3 26 21 1.1 0.4 1.4 11 0.5 AH_19 6.4 25 47 2.5 1.2 3.8 18 1.1 AH_20 6.4 15 60 2.3 1.2 3.8 25 1.0 AH_21 6.9 16 62 2.6 1.3 4.2 25 1.1 AH_22 8.6 15 64 3.1 1.6 5.2 23 1.3 AH_23 5.9 22 52 2.7 1.1 3.5 26 1.3 AH_24 3.3 38 28 1.5 0.6 2.0 13 0.7 AH_25 4.6 57 39 2.6 0.9 2.8 20 1.4 AH_26 4.2 24 36 1.9 0.8 2.5 17 0.9 AH_27 1.5 25 13 0.6 0.3 0.9 6 0.3 AH_28 4.8 65 45 2.8 0.9 2.9 23 1.5 AH_29 5.9 53 59 3.4 1.1 3.6 31 1.8 AH_3 6.4 53 71 3.4 1.2 3.8 39 1.8 AH_30 4.1 25 36 1.8 0.8 2.4 18 0.9 AH_31 1.7 25 18 0.7 0.3 1.0 9 0.3 AH_32 7.1 65 57 4.1 1.3 4.2 29 2.3 AH_33 3.1 65 30 1.8 0.6 1.9 16 1.0 AH_4 1.1 34 12 0.6 0.2 0.7 6 0.3 AH_5 3.7 25 28 1.5 0.7 2.2 11 0.7 AH_6 13.0 34 112 6.1 2.5 7.8 54 3.0 AH_7 5.6 65 50 3.3 1.1 3.4 26 1.8 AH_8 0.6 41 7 0.4 0.1 0.4 4 0.2 AH_9 5.2 60 53 2.8 1.0 3.1 27 1.5 BA_1 5.9 47 43 2.8 1.1 3.5 19 1.4 BA_2 3.1 80 23 1.7 0.6 1.9 11 1.0 BA_3 9.1 11 67 3.5 1.7 5.4 26 1.4 BA_6 8.6 11 70 3.4 1.6 5.1 31 1.5 BRCrk12 13.4 6 64 5.0 2.5 8.0 21 2.0 BRCrk13 14.0 4 77 5.3 2.7 8.4 27 2.2 BRCrk15 35.1 11 84 14.5 6.2 21.1 33 6.3 BRCrk16 31.2 16 137 15.5 5.8 18.7 60 7.7 BRCrk17 41.2 39 341 21.3 7.8 24.7 170 11.1 BRCrk18 13.5 42 87 7.4 2.5 8.1 42 3.9 BRCrk3 37.3 34 279 19.3 7.1 22.4 136 10.0 BRCrk4 14.2 18 103 7.1 2.7 8.5 50 3.6 EP_1 95.6 76 437 52.2 17.3 57.4 196 28.0 EP_2 121.8 74 405 67.0 20.6 73.1 185 35.9 IH_1 38.3 52 287 18.2 7.2 22.9 123 9.1 IH_10 6.6 21 55 2.5 1.3 4.0 22 1.1 IH_11 2.7 31 21 1.1 0.5 1.6 9 0.5 IH_12 6.3 25 45 2.5 1.2 3.8 17 1.1 IH_13 5.1 22 44 2.0 1.0 3.1 18 0.8 IH_14 5.0 37 40 2.1 0.9 3.0 16 1.0 IH_15 2.9 26 28 1.2 0.6 1.8 13 0.6 IH_3 18.5 18 127 6.8 3.5 11.1 45 2.8 IH_5 1.4 25 13 0.6 0.3 0.8 6 0.2 IH_6 15.1 21 127 5.8 2.9 9.1 50 2.5 IH_7 1.0 25 10 0.4 0.2 0.6 4 0.2 IH_8 4.7 25 40 2.0 0.9 2.8 18 0.9 NMSB_10 0.3 4 2 0.1 0.1 0.2 1 0.1 NMSB_11 1.4 2 14 0.6 0.3 0.8 7 0.3 NMSB_13 8.1 20 68 3.4 1.5 4.8 31 1.5 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 9.2 Watershed Modeling Results for Subwatersheds in the Nine Mile South Fork Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NMSB_14 5.9 25 48 2.6 1.1 3.5 22 1.2 NMSB_15 2.4 25 22 1.0 0.4 1.4 10 0.5 NMSB_16 2.8 24 24 1.3 0.5 1.7 11 0.6 NMSB_17 7.6 23 65 3.1 1.5 4.6 28 1.4 NMSB_18 8.0 25 14 2.7 1.3 4.8 6 1.1 NMSB_19 6.9 26 60 3.0 1.3 4.2 28 1.4 NMSB_20 11.6 7 66 4.3 2.2 7.0 23 1.7 NMSB_21 3.4 28 13 1.4 0.6 2.0 5 0.6 NMSB_22 9.3 27 65 4.0 1.8 5.6 27 1.8 NMSB_23 7.6 25 58 3.0 1.4 4.5 22 1.3 NMSB_24 2.0 65 23 1.1 0.4 1.2 12 0.6 NMSB_25 1.4 25 15 0.6 0.3 0.8 7 0.2 NMSB_26 6.7 25 46 2.7 1.3 4.0 18 1.2 NMSB_27 4.0 25 38 1.7 0.8 2.4 19 0.8 NMSB_28 2.4 25 11 0.9 0.5 1.5 4 0.4 NMSB_29 3.2 25 14 1.2 0.6 1.9 5 0.5 NMSB_30 15.5 25 94 6.1 2.9 9.3 35 2.7 NMSB_31 5.1 24 48 2.0 1.0 3.0 21 0.9 NMSB_32 6.6 25 51 2.6 1.2 3.9 19 1.1 NMSB_34 8.4 22 61 3.2 1.6 5.0 22 1.4 NMSB_35 3.1 20 21 1.2 0.6 1.9 8 0.5 NMSB_36 3.9 24 31 1.6 0.7 2.4 13 0.7 NMSB_37 4.7 25 42 1.9 0.9 2.8 17 0.8 NMSB_38 1.3 25 11 0.6 0.3 0.8 5 0.3 NMSB_39 5.1 25 47 2.0 1.0 3.0 20 0.9 NMSB_40 3.4 23 31 1.4 0.6 2.0 14 0.6 NMSB_41 6.0 8 35 2.3 1.1 3.6 13 0.9 NMSB_42 4.5 22 45 1.9 0.9 2.7 22 0.9 NMSB_43 6.7 22 52 2.8 1.3 4.0 22 1.2 NMSB_44 0.6 3 7 0.3 0.1 0.4 4 0.1 NMSB_45a 4.6 33 39 2.3 0.9 2.8 19 1.2 NMSB_45b 2.3 0 15 0.8 0.4 1.4 5 0.3 NMSB_46 1.2 65 14 0.6 0.2 0.7 7 0.3 NMSB_47 2.7 2 20 1.0 0.5 1.6 8 0.4 NMSB_49 0.6 53 7 0.3 0.1 0.3 4 0.2 NMSB_5 24.6 6 42 8.9 4.3 14.8 15 3.4 NMSB_50 1.9 67 22 1.0 0.4 1.1 12 0.5 NMSB_51 3.4 65 39 1.8 0.6 2.0 21 1.0 NMSB_57 20.6 15 137 8.8 3.9 12.4 59 4.0 NMSB_58 3.6 25 36 1.4 0.7 2.1 16 0.6 NMSB_59 3.8 25 36 1.5 0.7 2.3 15 0.7 NMSB_6 1.7 14 14 0.7 0.3 1.0 7 0.3 NMSB_62 7.3 6 35 2.9 1.4 4.4 13 1.2 NMSB_63 2.7 65 32 1.4 0.5 1.6 17 0.7 NMSB_64 2.7 65 32 1.4 0.5 1.6 17 0.7 NMSB_65 1.3 65 16 0.7 0.3 0.8 9 0.4 NMSB_66 10.0 24 67 3.9 1.9 6.0 25 1.7 NMSB_67 5.8 18 51 2.2 1.1 3.5 20 0.9 NMSB_7 2.4 16 18 1.1 0.5 1.5 9 0.6 NMSB_70 2.9 23 27 1.2 0.5 1.7 12 0.5 NMSB_71 5.6 65 63 3.1 1.1 3.3 34 1.7 NMSB_72 8.5 22 61 3.3 1.6 5.1 24 1.4 NMSB_73 69.6 73 293 37.3 12.5 41.8 128 19.8 NMSB_74 0.7 26 8 0.3 0.1 0.4 4 0.1 NMSB_75 1.6 25 15 0.6 0.3 1.0 7 0.3 NMSB_76 1.4 22 12 0.6 0.3 0.9 5 0.3 NMSB_78 5.6 25 44 2.2 1.1 3.4 18 1.0 NMSB_79 1.2 29 12 0.7 0.2 0.7 6 0.4 NMSB_8 9.8 16 63 4.0 1.9 5.9 26 1.8 NMSB_80 0.5 66 6 0.3 0.1 0.3 3 0.1 Table 9.2 Watershed Modeling Results for Subwatersheds in the Nine Mile South Fork Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event NMSB_81 0.6 65 7 0.3 0.1 0.3 4 0.2 NMSB_82 2.6 22 21 1.0 0.5 1.6 8 0.4 NMSB_83 10.7 25 60 4.5 2.0 6.4 24 2.0 NMSB_84 3.1 25 28 1.3 0.6 1.8 14 0.6 NMSB_85 16.7 9 88 7.5 3.2 10.0 38 3.6 NMSB_86 20.7 2 54 7.3 3.8 12.4 18 2.8 NMSB_87 8.8 75 81 4.8 1.7 5.3 40 2.6 NMSB_88 1.8 76 21 1.0 0.3 1.1 11 0.5 NMSB_90 29.8 35 201 14.7 5.6 17.9 93 7.4 NMSB_91 2.4 25 23 0.9 0.4 1.4 10 0.4 NMSB_92 0.4 25 4 0.1 0.1 0.2 2 0.1 NMSB_93 0.9 34 10 0.4 0.2 0.5 5 0.2 NMSB_94 4.7 25 32 1.8 0.9 2.8 12 0.8 NMSB_95 5.9 25 47 2.3 1.1 3.5 18 1.0 NMSB_96 1.6 27 15 0.6 0.3 1.0 6 0.3 NMSB_97 6.8 23 46 2.6 1.3 4.1 17 1.1 NMSB_98 0.9 26 8 0.4 0.2 0.5 3 0.2 NMSB_99 4.4 25 34 1.7 0.8 2.7 13 0.8 PA_1 7.7 41 72 3.4 1.5 4.6 32 1.6 PA_10 2.2 25 23 0.9 0.4 1.3 10 0.4 PA_11 1.0 25 11 0.4 0.2 0.6 5 0.2 PA_12 2.1 25 17 0.8 0.4 1.3 7 0.4 PA_13 0.6 25 6 0.2 0.1 0.3 3 0.1 PA_2 1.6 23 15 0.6 0.3 1.0 6 0.3 PA_3 8.6 18 66 3.2 1.6 5.1 25 1.3 PA_4 1.5 25 14 0.6 0.3 0.9 6 0.3 PA_5 2.6 25 27 1.0 0.5 1.6 12 0.5 PA_6 3.9 31 33 1.6 0.7 2.3 14 0.8 PA_7 1.5 25 15 0.6 0.3 0.9 7 0.3 PA_8 3.9 25 31 1.5 0.7 2.3 12 0.7 PA_9 1.7 25 19 0.7 0.3 1.0 9 0.3 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1034 890.8 890.5 1035 876.5 876.3 1036 869.0 868.8 1037 868.4 868.1 1038 868.3 867.9 1042 867.0 866.9 1043 864.4 864.3 1045 862.9 862.7 1047 861.8 861.0 1048 861.7 861.0 1049 861.7 861.0 1052 861.8 861.0 1053 861.8 861.0 1059 851.2 850.9 1060 853.5 851.9 1061 854.4 853.0 1062 871.3 864.4 1063 877.9 874.0 1064 878.6 877.7 1068 881.3 880.5 1071 845.0 844.7 1075 860.1 859.1 1077 844.9 844.9 1080 883.8 881.5 1081 884.6 881.4 1083 883.2 879.8 1085 880.7 879.2 1092 963.8 958.1 1093 942.4 942.2 1094 930.5 930.3 1095 902.0 901.7 1096 892.2 885.6 1098.1 street 883.2 877.4 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1100.1 901.7 895.2 1101 887.6 879.9 1102 882.7 877.0 1103 881.7 876.4 1104 880.1 875.4 1105 875.8 872.6 1106 874.1 871.5 1109 865.6 863.4 1111 845.1 845.1 1256 883.9 883.7 1257 873.0 871.4 1260 844.6 844.2 1261 844.6 844.2 1593 889.7 889.0 1644 876.9 874.3 1651 885.0 884.7 1654 890.7 889.6 1656 894.5 894.4 1872.1 841.0 840.1 1879 870.6 866.9 1880 896.2 889.2 1881 918.6 918.4 1883 854.7 854.5 1885 856.2 856.0 1886 856.9 856.7 1932 884.1 883.9 2081 853.0 852.8 2204 868.0 864.1 2205 868.0 864.3 2209 845.0 844.2 2242 858.2 856.8 2244 860.4 859.7 2246 876.2 870.3 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2247 877.5 872.9 2400 890.5 890.0 2401 887.6 886.9 2402 881.6 879.8 2405 870.8 867.7 2407 870.3 869.9 2409 869.7 868.7 2437 888.3 887.8 2571 885.0 883.1 2596 872.0 871.1 2603 886.8 884.9 2604 887.5 885.7 2605 887.8 885.9 2619 841.2 840.3 2622 843.5 842.7 2637 888.0 886.0 2639 904.9 904.8 2641 886.9 885.1 2643 885.5 883.6 2644 886.2 886.1 2646 868.0 865.2 2647 869.3 867.2 2648 868.2 866.3 2649 869.5 869.1 2650 868.6 867.6 2652 878.4 877.8 2653 882.6 882.7 2655 889.8 886.8 2656 887.5 886.2 2657 884.9 884.0 2659 868.8 868.2 2660 hwy ditch 868.9 864.8 2661 867.9 863.8 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2673 882.0 880.8 2676 875.4 875.4 2677 873.3 873.1 2679 879.0 878.7 2694 845.1 844.3 2695 845.8 845.2 2704 889.6 889.0 2727 873.2 870.4 2728 873.8 872.4 2729 874.8 872.8 2730 877.1 874.2 2731 869.0 866.4 2733 841.2 840.1 2868 885.0 884.8 2869 885.0 884.8 2870 885.0 884.8 2871 885.0 884.8 2874 844.4 844.1 2875 844.4 844.0 2947 888.1 886.2 513.1 874.3 873.5 514 street 874.3 873.8 516 872.2 871.5 519 887.2 887.0 520 888.0 887.8 521 891.6 891.4 523 871.3 869.6 534.1 880.0 875.1 536 street 880.6 874.9 537 880.3 874.0 539 875.8 871.1 541 869.2 867.1 543.1 880.6 878.0 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 546 870.1 868.3 548.1 871.2 868.4 549 869.0 868.1 552 884.3 884.3 553 883.5 883.5 555 882.3 878.9 560 950.9 946.4 561 879.9 ¹ 877.5 564 884.6 882.7 565 883.9 881.9 566 881.2 879.6 570 885.0 881.4 571 885.9 884.0 575 887.4 886.9 576 887.5 886.8 578 887.3 886.6 580 886.3 885.7 581 885.4 884.3 AH_1 lake 875.8* 879.9 ¹ 4.1 877.5 1.7 AH_10 955.5 953.4 AH_11 886.9 886.4 AH_12 byd 888.1 886.2 AH_13 school yard 887.7 887.3 AH_15 depression 887.6 886.8 AH_16 street 886.8 886.3 AH_17 895.1 894.9 AH_18 892.1 891.9 AH_19 885.0 884.7 AH_20 885.4 885.2 AH_21 883.3 882.9 AH_22 882.3 881.8 AH_23 889.5 889.1 AH_24 893.9 892.2 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 AH_25 hwy ditch 888.1 886.2 AH_26 905.2 905.1 AH_27 byd 892.6 892.5 AH_28 hwy ditch 888.0 886.1 AH_29 hwy ditch 888.2 886.7 AH_3 hwy ditch 885.0 884.8 AH_30 street 905.6 903.7 AH_31 byd 885.0 883.1 AH_32 hwy ditch 887.9 886.0 AH_33 888.7 888.6 AH_4 pond 885.5 886.4 0.9 886.2 0.7 AH_5 street 885.0 880.9 AH_6 pond 880.0 885.0 5.0 883.1 3.1 AH_7 hwy ditch 889.2 887.9 AH_8 885.0 883.1 AH_9 parking lot 888.2 887.4 BA_1 879.2 875.6 BA_2 892.9 887.3 BA_3 873.1 867.0 BA_6 pond 846.0 854.1 8.1 849.9 3.9 BRCrk1 832.8 831.8 BRCrk10 pond 840.2 845.0 4.8 844.2 4.0 BRCrk10.1 pond 840.2 844.9 4.7 844.2 4.0 BRCrk11 pond 840.2 843.6 3.4 843.4 3.2 BRCrk12 842.7 841.7 BRCrk12a 843.5 842.6 BRCrk12b 842.8 841.8 BRCrk12c 842.7 841.7 BRCrk13 838.8 838.6 BRCrk13a 842.7 841.7 BRCrk13b 842.7 841.6 BRCrk13c 842.0 841.1 BRCrk13d 838.9 838.7 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 BRCrk13e 838.9 838.7 BRCrk14 creek 832.6 831.5 BRCrk15 pond 827.2 832.6 5.4 831.2 4.0 BRCrk16 pond 827.2 832.6 5.4 831.2 4.0 BRCrk16a 832.6 831.2 BRCrk16b 832.6 831.2 BRCrk17a 832.6 831.2 BRCrk17b 832.6 831.2 BRCrk17c 832.6 831.2 BRCrk17d 832.6 831.2 BRCrk17e 832.6 831.2 BRCrk17f 832.6 831.2 BRCrk17g 832.6 831.2 BRCrk17h 832.5 831.1 BRCrk18 pond 827.8 832.6 4.8 831.2 3.4 BRCrk2 832.6 832.4 BRCrk3 creek 832.5 831.3 BRCrk4 creek 832.6 831.2 BRCrk5 861.8 859.9 BRCrk5a 861.9 860.4 BRCrk5b 861.9 860.1 BRCrk6 861.4 859.0 BRCrk7 859.8 857.0 BRCrk7a 860.7 858.0 BRCrk8 850.8 849.8 BRCrk8a 857.6 856.0 BRCrk8b 854.7 853.6 BRCrk8c 852.7 852.2 BRCrk9 creek 848.1 847.5 EP_1 pond 865.4 872.1 6.7 871.3 5.9 EP_2 ponds 892.2 890.0 FID4816 888.1 886.2 FID6047 865.6 865.5 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 FID6048 865.6 865.4 FID6049 865.6 865.3 FID6050 865.5 865.2 FID6121 870.6 869.3 IH_1 lake 863.7* 867.6 ¹ 3.9 865.0 1.3 IH_10 895.7 894.2 IH_11 876.8 874.0 IH_12 street 878.8 878.6 IH_13 880.4 880.1 IH_14 pond 869.8 875.0 5.2 873.7 3.9 IH_15 921.6 921.5 IH_3 depression 872.9 869.9 IH_5 street 874.3 873.5 IH_6 street 875.0 873.7 IH_7 street 874.7 874.6 IH_8 894.0 893.9 MH_5039 859.2 857.9 MH_5040 858.9 857.5 MH_5042 858.2 856.6 MH_5050 860.3 859.4 MH_5051 861.2 860.5 N669 864.0 863.7 N671 882.0 882.0 N672 862.1 862.1 N722 886.2 886.1 N723 885.6 883.6 N724 882.0 882.0 NMSB_10 840.8 840.0 NMSB_11 842.3 842.0 NMSB_13 street 870.6 866.9 NMSB_14 858.6 858.4 NMSB_15 byd 844.8 843.2 NMSB_16 844.6 844.5 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMSB_17 844.6 844.3 NMSB_18 883.1 877.9 NMSB_19 903.5 903.3 NMSB_20 depression 847.0 846.7 NMSB_21 943.5 943.2 NMSB_22 street 882.7 878.8 NMSB_23 street 885.0 881.2 NMSB_24 hwy ditch 876.8 876.3 NMSB_25 932.8 929.6 NMSB_26 street 880.7 871.8 NMSB_27 byd 881.1 879.3 NMSB_28 877.2 869.8 NMSB_29 874.5 868.5 NMSB_30 street 870.6 869.3 NMSB_31 street 866.1 865.8 NMSB_32 861.8 861.6 NMSB_34 byd 875.3 ¹ 869.9 NMSB_35 wetland 880.0 883.5 3.5 881.5 1.5 NMSB_36 848.1 847.7 NMSB_37 street 858.2 854.0 NMSB_38 street 977.6 977.1 NMSB_39 853.4 852.1 NMSB_40 847.0 846.8 NMSB_41 depression 843.9 843.0 NMSB_42 853.3 852.8 NMSB_43 street 856.9 856.7 NMSB_44 street 841.2 840.3 NMSB_45a facility 887.4 884.2 NMSB_45b sports dome 881.5 881.2 NMSB_46 hwy ditch 861.4 859.4 NMSB_47 street 841.2 840.1 NMSB_49 866.9 866.9 NMSB_5 pond 835.6 841.2 5.6 840.2 4.6 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMSB_50 hwy ditch 867.1 866.2 NMSB_51 hwy ditch 877.9 877.1 NMSB_57 pond 835.6 840.5 4.9 839.9 4.3 NMSB_58 896.6 896.4 NMSB_59 byd 866.8 866.5 NMSB_6 pond 835.9 842.6 6.7 841.4 5.5 NMSB_62 pond 835.6 841.1 5.5 840.2 4.6 NMSB_63 hwy ditch 870.3 868.7 NMSB_64 hwy ditch 870.7 867.2 NMSB_65 hwy ditch 868.4 865.6 NMSB_66 street 867.9 867.7 NMSB_67 street 910.1 909.9 NMSB_7 pond 836.3 841.3 5.0 840.3 4.0 NMSB_70 byd 863.1 862.9 NMSB_71 hwy ditch 867.9 863.3 NMSB_72 864.4 864.3 NMSB_73 ditch 867.9 863.7 NMSB_74 862.0 860.4 NMSB_75 street 874.6 873.2 NMSB_76 862.9 862.1 NMSB_78 864.1 863.7 NMSB_79 868.0 867.2 NMSB_8 pond 842.4 845.0 2.6 844.2 1.8 NMSB_80 876.1 876.1 NMSB_81 hwy ditch 869.1 866.1 NMSB_82 depression 879.4 878.8 NMSB_83 street 861.8 861.1 NMSB_84 street 861.8 861.1 NMSB_85 creek 841.2 840.3 NMSB_86 pond 828.4 834.8 6.4 833.4 5.0 NMSB_87 wetland 863.0 867.9 4.9 865.2 2.2 NMSB_88 880.9 880.6 NMSB_90 wetland 839.0 845.0 6.0 844.2 5.2 Table 9.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Nine Mile South Fork Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 NMSB_91 street 871.0 868.2 NMSB_92 870.8 868.4 NMSB_93 883.0 883.0 NMSB_94 871.7 871.6 NMSB_95 871.2 871.0 NMSB_96 street 871.0 870.5 NMSB_97 871.7 871.2 NMSB_98 894.7 894.5 NMSB_99 depression 872.6 871.3 PA_1 pond 864.0 869.2 5.2 867.1 3.1 PA_10 893.6 893.3 PA_11 byd 884.0 882.0 PA_12 street 880.6 875.3 PA_13 byd 890.0 ¹ 888.5 PA_2 byd 886.8 885.6 PA_3 street 877.0 875.9 PA_4 byd 873.9 870.1 PA_5 890.2 889.9 PA_6 pond 872.5 877.6 5.1 875.2 2.7 PA_7 depression 880.4 878.0 PA_8 street/byd 879.8 873.1 PA_9 wetland 885.0** 889.7 4.7 887.2 2.2 §¨¦494 £¤21262 4567158 Indian H i l l s R d Braemer Blvd Flying Cloud Dr Eden PrairieEden Prairie BloomingtonBloomington MinnetonkaMinnetonka NorthBranchNineMileCreek SouthBran ch N i ne M il e Creek EP_2 EP_1 AH_1 IH_1 NMSB_73 BRCrk3 BRCrk17 BRCrk15 IH_3 BRCrk16 IH_6 NMSB_90 NMSB_5 NMSB_68 NMSB_3 AH_6 NMSB_86 NMSB_57 NMSB_4 BRCrk4 NMSB_85 BA_3 BRCrk13 NMSB_30 PA_3 BRCrk18 BA_6 BRCrk12 PA_1 NMSB_45 AH_22 NMSB_12 NMSB_20 NMSB_8 AH_3 IH_10 NMSB_83 BA_1 IH_12 AH_32 NMSB_66 AH_21 AH_7 IH_8 NMSB_22 AH_20 AH_9 NMSB_87 AH_23 NMSB_72 NMSB_34 IH_13 NMSB_13 IH_14 NMSB_18 NMSB_23 AH_17 PA_8 NMSB_19 PA_6 AH_28 NMSB_43 AH_25 NMSB_32 AH_13 AH_26 NMSB_41 NMSB_14 NMSB_95 AH_30 NMSB_67NMSB_78 NMSB_2 BA_2 NMSB_39 NMSB_33 IH_15 NMSB_37 NMSB_94 NMSB_77 AH_33 NMSB_59 NMSB_35 PA_2 NMSB_17 AH_19 AH_29 NMSB_62 NMSB_97 NMSB_26 NMSB_69 AH_5 NMSB_45a NMSB_71 NMSB_52 NMSB_31 PA_5 AH_24 NMSB_42 IH_11 NMSB_99 NMSB_27 NMSB_36 NMSB_58 NMSB_40 NMSB_51 NMSB_21 PA_10 AH_18 NMSB_29 PA_12 PA_9 NMSB_84NMSB_70 AH_10 NMSB_16 IH_5 NMSB_7 NMSB_63 NMSB_64 NMSB_47 PA_4 NMSB_82 PA_7 AH_31 NMSB_28 NMSB_91 NMSB_15 AH_12 AH_27 NMSB_45b NMSB_24 AH_4 AH_11 NMSB_6 NMSB_50 IH_7 NMSB_88 AH_15 NMSB_96 NMSB_75 PA_11 NMSB_76 NMSB_11 NMSB_25 NMSB_38 NMSB_65 NMSB_79 NMSB_46 AH_8 NMSB_93 NMSB_98 PA_13 NMSB_74 AH_16 NMSB_44 NMSB_49 NMSB_80 NMSB_92 NMSB_10 Arrowhead Lake Indianhead Lake Barr Footer: ArcGIS 10.4.1, 2017-09-21 11:57 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_9_1_NMC_South_Fork_Drainage_Basins.mxd User: rcs2FIGURE 9.1 0 1,200 Feet !;N Nine Mile - South ForkDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NINE MILE - SOUTH FORKDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota §¨¦494 £¤21262 4567158 Indian H i l l s R d Braemer Blvd Flying Cloud Dr Nine Mile South Fork Eden Prairie Arrowhead Lake Indianhead Pawnee Pond Braemer Arena/Public Works Eden PrairieEden Prairie BloomingtonBloomington MinnetonkaMinnetonka NorthBranchNineMileCreek SouthBran ch N i ne M il e Creek Arrowhead Lake Indianhead Lake Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:10 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_9_2_NMC_South_Fork_Major_Watersheds.mxd User: rcs2FIGURE 9.2 0 1,200 Feet !;N Nine Mile - South ForkDrainage Basin Major Watershed Arrowhead Lake Braemer Arena/Public Works Eden Prairie Indianhead Nine Mile South Fork Pawnee Pond Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NINE MILE - SOUTH FORKMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota City of Edina 2018 Comprehensive Water Resources Management Plan 9-24 Figure 9.3 Nine Mile South Fork Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. PA_1 PA_6 NMSB_2 NMSB_6 NMSB_7 NMSB_5 NMSB_62 NMSB_86 NMSB_34 NMSB_59 NMSB_15 NMSB_33NMSB_3 NMSB_3 NMSB_85 NMSB_85 NMSB_12 NMSB_12 NMSB_57 NMSB_57 EP_2A NMSB_90 NMSB_8 EP_2B EP_1 PA_9 IH_1 IH_14 AH_4 AH_6 AH_1 AH_32 BA_6 SouthB r a n c h NineMile C re e k N ort h B r a nch NineMil e Creek BloomingtonBloomington Eden PrairieEden Prairie MinnetonkaMinnetonka Barr Footer: ArcGIS 10.4.1, 2018-03-26 11:28 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_9_4_NMC_South_Fork_Water_Quality.mxd User: EMANINE MILE CREEK SOUTH FORKWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 9.4 1,200 0 1,200Feet 400 0 400Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to the SouthFork of Nine Mile Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 10-1 10.0 Southwest Ponds (Dewey Hill Road Area) 10.1 General Description of Drainage Area Figure 10.1 depicts the drainage area to the Southwest Ponds drainage basin and the individual subwatersheds within this area. The Southwest Ponds watershed is located in southwest Edina, bordered by West 70th Street to the north, West 78th Street to the south, Gleason Road on the west, and the Soo Line railroad on the east. The drainage basin encompasses approximately 461 acres that ultimately drain to the South Fork of Nine Mile Creek south of West 78th Street. 10.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ditches, overland flow paths, wetlands, and ponding basins. The Southwest Ponds drainage basin has been divided into two major watersheds based on the drainage patterns. These major watersheds are depicted on Figure 10.2. Each major watershed has been further delineated into numerous subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located. Table 10.1 lists each major watershed and the associated subwatershed naming convention. Table 10.1 Major Watersheds within the Southwest Ponds Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Southwest Ponds SWP_## 67 411 Nine Mile—I-494 NM494_## 7 50 10.1.1.1 Southwest Ponds The Southwest Ponds watershed encompasses approximately 411 acres. The land use within the watershed is mainly low- and medium-density residential, in addition to the commercial and industrial area along Cahill Road and Lewis Park (the eastern portion of the watershed). The watershed is characterized by a series of ponding basins that outlet to the South Fork of Nine Mile Creek via a storm sewer system that travels south from the intersection of West 78th Street and Delaney Boulevard and discharges to a detention pond north of I-494. Discharge from this detention pond flows beneath I-494 and enters the South Fork of Nine Mile Creek. 10.1.1.2 Nine Mile I-494 The Nine Mile I-494 watershed encompasses approximately 50 acres. The land use within the watershed is mainly low- and medium-density residential. There is one stormwater detention basin within the watershed. The watershed ultimately drains to the South Fork of Nine Mile Creek through a storm sewer system that discharges to the creek southeast of the intersection of Marth Court and West 78th Street, on the north side of I-494 City of Edina 2018 Comprehensive Water Resources Management Plan 10-2 10.2 Stormwater System Results 10.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Southwest Ponds drainage basin. The 10-percent-annual-chance event was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis. Table 10.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses for the Southwest Ponds basin. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analysis for the Southwest Ponds drainage basin are summarized in Table 10.3. Figure 10.3 illustrates the results of the 10- and 1-percent-annual-chance hydraulic analyses. The figure depicts the Southwest Ponds drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 10.3 illustrates that several XP-SWMM nodes within the Southwest Ponds drainage basin are predicted to surcharge during both the 10- and 1-percent-annual-chance event. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the Southwest Ponds drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 10.3. Discussion and recommended improvement considerations for these areas are included in Section 10.3. 10.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 10.4 depicts the results of the water quality modeling for the Southwest Ponds drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. City of Edina 2018 Comprehensive Water Resources Management Plan 10-3 10.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 10.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Southwest Ponds drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for problem areas. These preliminary corrective measures are also discussed. As the City evaluates flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Southwest Ponds drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done since 2003. 10.3.1.1 Gleason Road and Bonnie Brae Drive (SWP_24) A local depression exists in the backyards of the homes along Gleason Road, Bonnie Brae Drive, and Hyde Park Drive, with a single 18-inch outlet positioned east. The outlet size increases to 30 inches before the pipes discharge to the existing wet pond to the east. This pipe size increase was part of a 2015 street reconstruction project. Modeling results indicate that flooding would occur in the backyard depression during the 1-percent-annual-chance 24-hour storm event, with a peak flood level of 842.3 feet. Based on LiDAR data and building footprints, two principle structures are potentially impacted by this flooding (7501 and 7505 Gleason Road), and two principle structures are nearly potentially impacted (7436 and 7500 Hyde Park Drive). The problem is mostly caused by the limited capacity of the remaining 18-inch storm sewer pipe. City of Edina 2018 Comprehensive Water Resources Management Plan 10-4 The first recommendation is to survey the potentially impacted principle structures to verify the impact. If the impacts exist, flood-proofing these eight principle structures may be the most cost-effective solution. Alternatively, additional flood storage could be created in the City-owned parcels south of Bonnie Brae Drive, and storm sewer could be added to connect the backyard depression to the new storage. Finally, the remaining portion of the existing storm sewer pipe that has not be upsized could be modified to add more outlet capacity. 10.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the annual removal of total phosphorus from several ponds in the Southwest Ponds drainage area was below the desired 60 percent rate. For those ponds with total phosphorus removal below 60 percent, the permanent pool storage volume was analyzed to determine whether additional capacity is necessary. Based on the MPCA- recommended permanent pool storage volume for detention basins, all of the basins were found to have sufficient dead storage volume. As a result, no specific recommendations for water quality basin upgrades in the Southwest Ponds drainage basin are being made at this time. Construction of new or expansion of existing water quality basins is one method to increase the pollutant removal achieved prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. Table 10.2 Watershed Modeling Results for Subwatersheds in the Southwest Ponds Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) NM494_1 9.5 24 79 3.7 1.8 5.7 32 1.6 NM494_2 5.5 23 46 2.2 1.0 3.3 20 1.0 NM494_3 7.1 16 51 2.7 1.4 4.3 19 1.2 NM494_4 5.3 35 47 2.5 1.0 3.2 22 1.2 NM494_5 12.9 26 94 5.4 2.4 7.7 38 2.4 NM494_6 7.8 28 69 3.2 1.5 4.6 30 1.5 NM494_7 2.1 25 19 0.9 0.4 1.3 9 0.5 SWP_1 4.2 48 39 2.2 0.8 2.5 20 1.1 SWP_10 4.5 44 39 2.0 0.8 2.7 17 1.0 SWP_11 2.6 40 20 1.1 0.5 1.5 8 0.5 SWP_12 2.0 36 20 0.9 0.4 1.2 10 0.4 SWP_13 1.3 17 14 0.6 0.3 0.8 7 0.3 SWP_14 2.7 24 25 1.3 0.5 1.6 13 0.7 SWP_15 0.7 25 4 0.3 0.1 0.4 2 0.2 SWP_16 4.4 40 35 2.1 0.8 2.6 16 1.0 SWP_17 2.8 40 11 1.2 0.5 1.7 5 0.6 SWP_18 3.3 25 32 1.6 0.6 2.0 17 0.8 SWP_19 6.4 25 62 3.2 1.2 3.8 32 1.7 SWP_2 13.3 50 120 6.9 2.5 8.0 60 3.6 SWP_20 3.6 25 33 1.8 0.7 2.1 17 0.9 SWP_21 2.9 25 30 1.2 0.5 1.7 15 0.6 SWP_22 6.3 25 49 2.6 1.2 3.8 20 1.2 SWP_23 3.3 25 32 1.3 0.6 2.0 14 0.6 SWP_24 3.9 25 25 1.7 0.7 2.3 10 0.8 SWP_25 2.9 25 26 1.4 0.6 1.8 13 0.7 SWP_26 3.1 25 26 1.5 0.6 1.9 13 0.8 SWP_27 8.2 5 49 2.8 1.6 4.9 15 1.0 SWP_28 8.9 10 66 3.3 1.7 5.3 25 1.3 SWP_29 4.6 48 44 2.3 0.9 2.8 22 1.1 SWP_3 29.2 29 220 13.2 5.5 17.5 99 6.3 SWP_30 2.5 37 18 1.1 0.5 1.5 7 0.5 SWP_31 11.0 56 92 5.8 2.1 6.6 45 3.1 SWP_32 23.6 69 185 12.5 4.5 14.1 87 6.6 SWP_33 2.3 40 20 1.1 0.4 1.3 10 0.6 SWP_34 16.8 31 146 8.2 3.2 10.0 72 4.1 SWP_35 11.3 37 93 5.7 2.2 6.8 45 2.9 SWP_36 7.7 25 74 3.2 1.5 4.6 35 1.5 SWP_37 2.3 48 21 1.2 0.4 1.4 11 0.6 SWP_38 4.7 25 42 1.9 0.9 2.8 18 0.8 SWP_39 13.0 25 110 5.2 2.5 7.8 46 2.3 SWP_4 13.0 41 116 6.6 2.5 7.8 58 3.4 SWP_40 2.6 44 27 1.3 0.5 1.6 13 0.6 SWP_41 2.5 65 28 1.3 0.5 1.5 14 0.7 SWP_42 4.3 51 33 2.0 0.8 2.6 14 1.0 SWP_43 3.7 60 29 1.8 0.7 2.2 13 0.9 SWP_44 2.4 71 19 1.4 0.5 1.5 9 0.7 SWP_45 1.4 74 11 0.8 0.3 0.8 5 0.4 SWP_46 6.2 56 50 3.2 1.2 3.7 24 1.6 SWP_46x 5.4 72 46 3.0 1.0 3.3 23 1.6 SWP_47 21.5 27 122 9.3 4.1 12.9 49 4.2 SWP_48 0.8 30 9 0.3 0.2 0.5 5 0.2 SWP_49 3.7 25 35 1.5 0.7 2.2 16 0.7 SWP_5 6.5 61 72 3.5 1.2 3.9 39 1.9 SWP_50 8.4 25 66 3.4 1.6 5.0 27 1.5 SWP_51 6.9 25 52 2.8 1.3 4.1 21 1.3 SWP_52 8.2 25 70 3.3 1.6 4.9 29 1.5 SWP_53 13.5 25 96 5.6 2.6 8.1 39 2.5 SWP_54 12.3 25 108 4.9 2.3 7.4 45 2.2 SWP_55 3.5 25 30 1.5 0.7 2.1 14 0.7 SWP_56 7.5 25 62 3.3 1.4 4.5 28 1.5 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 10.2 Watershed Modeling Results for Subwatersheds in the Southwest Ponds Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event SWP_57 1.6 40 16 0.7 0.3 0.9 7 0.3 SWP_58 2.0 40 19 1.0 0.4 1.2 10 0.5 SWP_59 7.2 51 66 3.9 1.4 4.3 34 2.1 SWP_59a 4.6 40 40 2.1 0.9 2.8 18 1.0 SWP_6 5.1 25 34 2.1 1.0 3.0 14 0.9 SWP_60 9.8 39 50 4.5 1.8 5.9 21 2.2 SWP_61 5.3 25 46 2.2 1.0 3.2 20 1.0 SWP_62 1.7 25 17 0.7 0.3 1.0 8 0.3 SWP_63 6.9 13 44 2.6 1.3 4.2 16 1.1 SWP_64 2.1 68 21 1.2 0.4 1.3 11 0.7 SWP_66 4.6 25 29 1.8 0.9 2.7 11 0.8 SWP_7 1.7 36 16 0.8 0.3 1.0 8 0.4 SWP_8 2.6 39 26 1.2 0.5 1.5 13 0.6 SWP_9 2.2 25 24 1.0 0.4 1.3 12 0.4 Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1171 937.5 936.6 1172 932.9 930.2 1173 928.7 927.3 1174 924.0 922.9 1175 923.9 921.6 1176 921.4 919.7 1177 914.2 914.1 1178 897.4 897.2 1180 884.1 883.6 1182 886.6 886.3 1183 890.2 890.0 1184 894.7 894.4 1185 897.1 896.9 1186 880.9 877.1 1187 871.2 868.4 1188 854.5 854.3 1190 848.8 847.4 1191 847.1 845.5 1192 845.2 843.1 1193 842.8 840.1 1197 842.5 842.5 1198 846.4 846.4 1205 837.7 834.6 1207 836.3 833.8 1208 834.9 833.1 1210 834.6 833.1 1211 834.4 833.1 1212 834.4 833.1 1215 834.4 833.1 1216 834.4 833.1 1219 837.7 835.7 1267 844.4 843.2 1270 841.2 839.9 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1271 841.0 839.5 1276 845.1 842.2 1277 street 846.4 843.4 1283 832.1 831.7 1285 831.1 829.8 1286 830.8 829.4 1289 838.1 837.5 1290 841.1 838.2 1291 841.1 838.3 1292 841.4 839.2 1295 842.7 841.0 1296 842.7 840.7 1299 835.0 834.9 1306 834.0 833.4 1310 834.4 831.9 1318 830.1 829.0 132 837.8 835.0 1322 834.3 831.7 1326 825.8 825.8 1327 825.3 825.3 1328 825.1 825.1 1330 822.5 822.2 1344 834.4 832.8 1350 835.9 834.3 1354 833.1 831.2 1356 832.0 829.7 1660 901.9 901.4 1661 924.2 920.4 1662 938.7 934.4 1663 949.2 944.8 1665 925.1 923.0 1667 927.6 924.9 1676 834.8 834.6 Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1678 834.4 833.1 1856 845.6 845.4 1857 846.1 845.8 1859 846.4 843.7 1860 846.4 844.9 1866 845.3 844.0 1894 825.5 825.5 1895 827.2 827.0 2424 838.0 837.5 2425 837.9 837.5 2426 837.8 837.5 2492 834.4 833.1 2494 ditch 944.3 940.2 2497 835.4 834.0 2498 835.4 833.6 2499 834.5 833.4 BRCrk17 832.0 830.8 BRCrk17.1 830.3 829.2 ED7131 834.4 832.8 FID1348 839.8 838.0 FID6116 923.2 921.0 FID6117 934.5 929.6 FID6453 832.0 829.4 NM494_2 841.1 838.0 NM494_3 837.7 837.5 NM494_4 pond 828.2 833.7 5.6 831.7 3.6 NM494_5 832.0 831.3 NM494_6 833.5 833.0 NM494_7 byd 842.0 840.4 NMS_60 street 850.8 846.3 SWP_1 pond 827.0 827.1 0.1 827.0 0.0 SWP_10 pond 830.1 833.6 3.5 831.8 1.7 SWP_11 ditch 839.0 837.9 Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 SWP_12 depression 832.0 829.4 SWP_13 833.3 830.0 SWP_14 pond 828.5 834.4 5.9 831.9 3.4 SWP_15 834.4 831.9 SWP_16 street 834.3 834.0 SWP_17 street 834.4 831.9 SWP_18 847.8 847.5 SWP_19 845.4 845.2 SWP_2 pond 828.0 828.3 0.3 828.1 0.1 SWP_20 street 838.2 837.9 SWP_21 street 834.4 832.5 SWP_22 street 845.3 844.0 SWP_23 851.8 851.7 SWP_24 byd 842.3 840.9 SWP_25 street 840.7 838.7 SWP_26 street 844.9 843.6 SWP_27 846.4 845.8 SWP_28 street 845.0 842.1 SWP_29 street 825.1 824.9 SWP_3 pond 836.5 839.7 3.2 837.9 1.4 SWP_30 street 827.9 827.7 SWP_31 pond 827.1** 829.3 ¹ 2.2 828.1 1.0 SWP_32 ditch 838.1 837.8 SWP_33 depression 839.6 ¹ 837.9 SWP_34 pond 828.0 834.4 6.4 833.1 5.1 SWP_35 pond 828.0 834.4 6.4 832.8 4.8 SWP_36 byd 835.6 835.3 SWP_37 pond 835.4** 835.4 0.0 833.3 -2.1 SWP_38 835.7 835.3 SWP_39 857.5 857.2 SWP_3OUT2 839.7 837.9 SWP_4 pond 828.6 834.0 5.4 832.4 3.8 SWP_40 pond 828.1** 837.7 9.6 835.5 7.4 Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 SWP_41 840.3 833.7 SWP_42 837.6 833.6 SWP_43 836.9 833.2 SWP_44 835.8 832.8 SWP_45 street 834.4 833.4 SWP_46 street/lot 834.4 832.9 SWP_46x parking lot 834.4 832.9 SWP_47 pond 832.0 837.7 5.7 835.7 3.7 SWP_48 street 834.4 832.8 SWP_49 958.4 958.3 SWP_5 pond 828.0 834.4 6.4 831.9 3.9 SWP_5_OUT 834.4 831.9 SWP_50 898.8 898.5 SWP_51 851.6 851.1 SWP_52 depression 945.0 940.1 SWP_53 street 851.1 849.9 SWP_54 884.7 884.6 SWP_55 street 941.5 939.8 SWP_56 884.8 884.5 SWP_57 pond 836.0 839.1 ¹ 3.1 837.4 1.4 SWP_58 depression 840.6 ¹ 839.5 SWP_59 wetland 828.7 831.8 3.1 830.6 1.9 SWP_59a street/lot 836.0 835.8 SWP_6 byd 842.7 842.3 SWP_60 parking lot 837.7 835.7 SWP_61 street 842.7 840.7 SWP_62 byd 845.0 ¹ 842.7 SWP_63 depression 834.9 833.0 SWP_64 parking lot 835.7 835.2 SWP_66 street 849.4 849.1 SWP_7 834.0 830.7 SWP_8 street 835.1 834.9 SWP_9 depression 829.6 ¹ 827.7 Table 10.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southwest Ponds Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 WBlmCrk1a 828.0 827.4 WBlmCrk1b 826.7 826.2 §¨¦494 100 456728 Gleason Rd W 70th St Cahill Rd Dewey Hill Rd 78th St BloomingtonBloomington North B ra n c h NineMileCreek SouthB ranch Nine Mile Creek SWP_3 SWP_32 SWP_47 SWP_34 SWP_2 SWP_4 SWP_53 SWP_39 SWP_54 NM494_5 SWP_35 SWP_31 SWP_60 SWP_28 NM494_1 SWP_50 SWP_52 SWP_27 SWP_36 SWP_56 SWP_5 SWP_59 NM494_6 SWP_63 SWP_51 NM494_3 SWP_19 SWP_22 SWP_46 SWP_6 SWP_61 NM494_2 NM494_4 SWP_46x SWP_1 SWP_38 SWP_29 SWP_66 SWP_10 SWP_16 SWP_42 SWP_59a SWP_49 SWP_43 SWP_55 SWP_18SWP_26 SWP_25 SWP_14 SWP_40 SWP_11 SWP_9 SWP_44 SWP_37 SWP_33 SWP_58 SWP_7 SWP_57 SWP_24 SWP_20 SWP_23 SWP_8 SWP_21 SWP_17 SWP_41 SWP_30 SWP_64 SWP_12 NM494_7 SWP_62 SWP_45 SWP_13 SWP_48 SWP_15 Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:11 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_10_1_SW_Ponds_Drainage_Basins.mxd User: rcs2FIGURE 10.1 0 800 Feet !;N Southwest PondsDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 SOUTHWEST PONDSDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota §¨¦494 100 456728 Gleason Rd W 70th St Cahill Rd Dewey Hill Rd 78th St Southwest Ponds Nine Mile - 494 BloomingtonBloomington North B ra n c h NineMileCreek SouthB ranch Nine Mile Creek Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:12 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_10_2_SW_Ponds_Major_Watersheds.mxd User: rcs2FIGURE 10.2 0 800 Feet !;N Southwest PondsDrainage Basin Major Watersheds Nine Mile - 494 Southwest Ponds Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 SOUTHWEST PONDSMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota City of Edina 2018 Comprehensive Water Resources Management Plan 10-15 Figure 10.3 Southwest Ponds Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. NM494_4 SWP_40 SWP_47 SWP_37 SWP_34 SWP_35 SWP_3 SWP_3 SWP_14 SWP_5 SWP_59SWP_4 SWP_2 SWP_10 SWP_31 SWP_1 SWP_33 SWP_58 SWP_57 SWP_9 Nine M ile C ree k N i n e MileCreek Barr Footer: ArcGIS 10.4.1, 2018-03-26 11:28 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_10_4_SW_Ponds_Water_Quality_Rev052014.mxd User: EMASOUTHWEST PONDSWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 10.4 600 0 600Feet 200 0 200Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to the SouthFork of Nine Mile Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 11-1 11.0 TH 169 North 11.1 General Description of Drainage Area Figure 11.1 depicts the TH 169 North drainage area and the individual subwatersheds within this area. The TH 169 North drainage area is located in the northwest corner of Edina. The drainage area encompasses approximately 141 acres that ultimately drain to the TH 169 drainage system. 11.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ditches, overland flow paths, and ponding basins. Stormwater from this drainage area ultimately flows to the TH 169 storm sewer system at several locations along TH 169 between the intersection of the highway with Malibu Drive and the Edina City limits. The TH 169 North drainage basin has only one major watershed, also referred to as TH 169 North (Figure 11.2). The drainage area has been delineated into 24 subwatersheds. Table 11.1 describes the naming convention for subwatersheds within the drainage area. Land use within the drainage area includes low-density residential, open area, Van Valkenburg Park, and a small commercial area. Table 11.1 Major Watershed within the TH 169 North Drainage Area Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) TH 169 North 169N_## 24 141 11.2 Stormwater System Results 11.2.1 Hydrologic/Hydraulic Modeling Results The 10-percent-annual-chance and 1-percent-annual-chance flood analyses were performed for the TH 169 North drainage area. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis. Table 11.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses for the TH 169 North drainage area. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analysis for the TH 169 North drainage area are summarized in Table 11.3. Figure 11.3 illustrates the results of the 10- and 1-percent-annual-chance hydraulic analyses. The figure depicts the TH 169 North drainage area boundary, subwatershed boundaries, the modeled storm sewer City of Edina 2018 Comprehensive Water Resources Management Plan 11-2 network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 11.3 illustrates that several XP-SWMM nodes within the TH 169 North drainage area are predicted to surcharge during both the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the TH 169 North drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. At this time, none of the areas in the TH 169 North drainage area have been evaluated for flood protection improvements. 11.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 11.4 depicts the results of the water quality modeling for the TH 169 North drainage area. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 11.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 11.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the TH 169 North drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. However, at this time, none of those areas have been evaluated further to identify possible improvement options. It is recommended that those areas be evaluated in the future. City of Edina 2018 Comprehensive Water Resources Management Plan 11-3 11.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the predicted annual removal of total phosphorus from Pond 169N_16 in the TH 169 North drainage area was below the desired 60 percent removal rate. The permanent pool storage volume was analyzed to determine whether additional capacity was necessary. Based on the MPCA-recommended volume of permanent pool storage for removal of particulate phosphorus, the basin was found to have sufficient dead storage volume. As a result, no specific recommendations for water quality basin upgrades in the TH 169 North drainage area are being made at this time. Construction of new or expansion of existing water quality basins is one method to increase the pollutant removal achieved prior to stormwater reaching downstream waterbodies. Many additional techniques are available to reduce pollutant loading, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and improve the quality of stormwater runoff. Table 11.2 Watershed Modeling Results for Subwatersheds in the TH 169 North Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 169N_1 4.1 25 35 1.9 0.8 2.5 17 0.9 169N_10 6.4 24 56 2.9 1.2 3.9 27 1.4 169N_11 8.5 25 59 3.8 1.6 5.1 26 1.8 169N_12 13.1 15 93 5.6 2.5 7.8 42 2.6 169N_13 12.0 12 76 5.0 2.3 7.2 32 2.3 169N_14 3.3 25 31 1.5 0.6 2.0 16 0.7 169N_15 7.7 0 51 3.1 1.5 4.6 22 1.3 169N_16 2.4 32 23 1.1 0.4 1.4 12 0.5 169N_17 19.5 17 137 8.3 3.7 11.7 60 3.9 169N_18 2.5 78 27 1.5 0.5 1.5 14 0.8 169N_18a 2.5 24 26 1.1 0.5 1.5 14 0.5 169N_19 4.2 10 35 1.7 0.8 2.5 16 0.8 169N_2 1.0 25 11 0.5 0.2 0.6 6 0.2 169N_20 7.4 25 58 3.3 1.4 4.4 27 1.6 169N_21 3.2 25 19 1.4 0.6 1.9 8 0.7 169N_22 5.3 67 52 2.9 1.0 3.2 27 1.6 169N_23 6.5 0 45 2.7 1.2 3.9 20 1.2 169N_3 2.0 25 17 0.9 0.4 1.2 8 0.4 169N_4 9.4 25 61 4.3 1.8 5.7 27 2.1 169N_5 3.1 28 29 1.4 0.6 1.8 15 0.7 169N_6 1.0 22 12 0.4 0.2 0.6 6 0.2 169N_7 3.6 31 29 1.7 0.7 2.1 14 0.9 169N_8 2.1 25 21 0.9 0.4 1.2 11 0.5 169N_9 10.2 23 58 4.4 1.9 6.1 24 2.1 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 11.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the TH 169 North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 124.1 938.5 938.3 1395 940.8 938.6 1399_e byd 939.7 938.6 1400_e 937.7 934.2 1401_e 937.4 933.4 1402_e 937.0 932.5 1406_e 924.5 922.7 1413_e 932.8 932.3 1416 915.8 914.7 1416_e 928.1 927.9 1420 912.7 912.6 1427_e 932.6 932.3 1428 909.5 908.0 1428_e 929.9 929.7 1429_e 923.9 923.5 1433 913.9 912.7 1434 913.9 912.7 1435_e 924.5 924.1 1436_e 921.0 920.7 1437_e 910.5 910.5 1439_e 911.1 908.6 1440_e 905.9 904.7 1441_e 905.9 904.6 167.1 918.6 917.9 168 street 918.5 917.5 169N_1 914.9 913.9 169N_10 926.1 925.9 169N_11 922.8 922.4 169N_12 935.5 935.1 169N_13 916.4 916.0 169N_14 byd 939.6 938.5 169N_15 depression 932.9 932.6 169N_16 pond 914.4 924.8 10.4 922.9 8.5 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 11.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the TH 169 North Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 169N_17 927.1 926.7 169N_18 street 905.9 904.6 169N_18a street 915.5 915.4 169N_19 910.3 910.0 169N_2 953.1 953.0 169N_20 935.1 934.9 169N_21 930.5 930.2 169N_22 street 911.4 910.7 169N_23 depression 913.9 912.8 169N_3 927.5 923.4 169N_4 byd 930.7 930.3 169N_5 street 918.3 917.5 169N_6 975.0 974.4 169N_7 street/byd 918.3 917.1 169N_8 947.2 943.2 169N_9 street 922.6 922.2 309 927.5 923.5 312 918.9 918.3 534 916.8 914.6 548 912.4 910.6 621 925.5 925.3 TH169_2 927.5 923.5 £¤169 Maloney Ave Van Buren Ave Washington Ave Interlachen Blvd HopkinsHopkins 169N_17 169N_12169N_13 169N_9 169N_4 169N_11 169N_15 169N_20 169N_23 169N_10 169N_22 169N_1 169N_19 169N_7 169N_5 169N_14 169N_21 169N_18 169N_8 169N_16 169N_3 169N_18a 169N_2 169N_6 Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:13 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_11_1_TH169_Ponds_Drainage_Basins.mxd User: rcs2FIGURE 11.1 0 500 Feet !;N TH 169 NorthDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 TH 169 NORTHDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota £¤169 Maloney Ave Van Buren Ave Washington Ave Interlachen Blvd TH 169 North HopkinsHopkins Barr Footer: ArcGIS 10.4.1, 2017-09-22 12:16 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_11_2_TH169_Ponds_Major_Watersheds.mxd User: jrvFIGURE 11.2 0 500 Feet !;N TH 169 NorthDrainage Basin Major Watershed TH 169 North Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 TH 169 NORTHMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota City of Edina 2018 Comprehensive Water Resources Management Plan 11-9 Reserved for: Figure 11.3 TH 169 North Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. 169N_16 169N_15 HopkinsHopkins Barr Footer: ArcGIS 10.4.1, 2017-09-22 12:14 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_11_4_TH169_Ponds_Water_Quality.mxd User: jrvTH 169 NORTHWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 11.4 400 0 400Feet !;N 150 0 150Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 12-1 12.0 Northeast Minnehaha Creek 12.1 General Description of Drainage Area Figure 12.1 depicts the Northeast Minnehaha Creek drainage area and the individual subwatersheds within this area. The Northeast Minnehaha Creek drainage basin is located in the northeast corner of Edina. This watershed contains a limited number of ponds and no lakes. 12.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ponding basins, wetlands, drainage ditches, and overland flow paths. The Northeast Minnehaha Creek basin has been divided into several major watersheds, based on the drainage patterns. These major watersheds are depicted on Figure 12.2. Each major watershed has been further delineated into numerous subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located. Table 12.1 lists each major watershed and the associated subwatershed naming convention. Table 12.1 Major Watersheds within the Northeast Minnehaha Creek Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Morningside MS_## 59 232 Minnehaha Creek North MHN_## / MHC_## 97 564 Edina Country Club ECC_## 15 116 12.1.1.1 Morningside The 232-acre Morningside watershed is located in the northeast corner of Edina, primarily north of West 44th Street. Land use in this watershed, which includes Weber Park, is primarily single-family residential. The Edina trunk storm sewer system through this area connects to the incoming St. Louis Park system just southeast of Susan Lindgren Elementary School (Natchez Avenue and 41st Street). From this junction the system runs east to the east side of Weber Park and an inlet/outlet to the Weber Park pond. The inlet/outlet allows stormwater to flow into the basin until the head differential between the basin and trunk sewer system results in a discharge from the basin. From the Weber Park Pond, the system drains north to St. Louis Park and then east to connect with the Minneapolis system, eventually draining to Lake Calhoun. 12.1.1.2 Minnehaha Creek North The Minnehaha Creek North watershed lies primarily east of Minnehaha Creek, west of France Avenue, north of West 54th Street and south of West 44th Street. There are only two wetlands within this 564-acre watershed and no ponds; all other areas discharge directly to Minnehaha Creek. Land use is primarily City of Edina 2018 Comprehensive Water Resources Management Plan 12-2 single-family residential; however, there is some commercial land adjacent to France Avenue. There is very little open space in this watershed except for areas directly adjacent to Minnehaha Creek. 12.1.1.3 Edina Country Club The Edina Country Club watershed is a small 116-acre watershed that encompasses the Edina Country Club golf course and areas east of the Country Club to Minnehaha Creek. The watershed area outside of the golf course is low-density residential and contains no ponds or wetlands; all areas discharge directly to Minnehaha Creek. There are no known pipes connecting the ponds of the Edina Country Club to the adjacent storm sewer network along Wooddale Avenue. 12.2 Stormwater System Results 12.2.1 Hydrologic/Hydraulic Modeling Results The 10-, and 1-percent-annual-chance flood analyses were performed for the Northeast Minnehaha Creek drainage basin. For the Minnehaha Creek North and the Edina Country Club drainage areas, the storm sewers were evaluated using 10- and 1-percent-annual-chance storm events. The 10-percent-annual- chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent- annual-chance analysis. Table 12.2 presents the watershed information and the results for the 10-, and 1-percent-annual-chance hydrologic analyses for the Northeast Minnehaha Creek basin. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10-, and 1-percent-annual-chance hydraulic analyses for the Northeast Minnehaha Creek drainage basin are summarized in Table 12.3. Figure 12.3 illustrates the results of the 10-, and the 1-percent-annual-chance hydraulic analyses. The figure depicts the Northeast Minnehaha Creek drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 12.3 illustrates that several XP-SWMM nodes within the Northeast Minnehaha Creek drainage basin are predicted to surcharge during the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10-percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the Northeast Minnehaha Creek drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 12.3. City of Edina 2018 Comprehensive Water Resources Management Plan 12-3 Discussion and recommended improvement considerations for these areas are included in Section 12.3. 12.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 12.4 depicts the results of the water quality modeling for the Northeast Minnehaha Creek drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 12.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 12.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Northeast Minnehaha Creek drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for problem areas. These preliminary corrective measures are also discussed below. As the City evaluates the flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Northeast Minnehaha Creek drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done since 2003. City of Edina 2018 Comprehensive Water Resources Management Plan 12-4 12.3.1.1 Indianola Avenue South of West 50th Street (MHN_72) There is a local depression area south of West 50th Street along Indianola Avenue, which is drained by an existing 12-inch pipe that connects to the trunk storm sewer system on West 50th Street. Modeling results indicate that the 1-percent-annual-chance flood elevation (884.6 feet) may impact several structures in the area, including a single family home (5021 Indianola Avenue), an apartment building (4121 W 50th Street), and a public building (4201 W 50th Street). In addition to the potential impacts to structures, the flood elevation exceeds the low elevation on Indianola Avenue by more than 2 feet. The flooding problem is primarily related to the limited flow capacity of the storm sewer system—partly due to the size of the existing pipe and number of inlets and partly due to water levels in the trunk storm sewer system that can restrict flows. There are several options that should be considered to reduce flood risk in this area, including installing underground flood storage and increasing discharge capacity. Underground storage (with sufficient inlet capacity) would reduce the flood elevation by storing flows that exceed the capacity of the existing storm sewer system and infiltrating a portion of the runoff. Planning-level soil maps indicate that the soils in this area are “A” soils with a high potential for infiltration. A few potential locations for installing underground storage include the grassed field and parking lot on the east side of Indianola Avenue (0.3 acres), the parking lot of Mercy Commons Covenant Church (0.5 acres), and the parking lot north of West 50th Street (0.5 acres). Adding additional flow capacity, either by increasing the size of the outlet pipe and the downstream storm sewer system to Minnehaha Creek, or by installing additional storm sewer, would also reduce the flood elevation. If new storm sewer were installed, it could potentially be routed to the existing storm sewer system under Halifax Avenue South. This option, however, would be contingent on addressing the flooding problems in the Halifax area Section 12.3.1.2. 12.3.1.2 Halifax Avenue South (MHN_84, MHN_3, MHN_4, MHN_56, MHN_89, MHN_55, MHN_61, MHN_62, MHN_87, MHN_90, and MHN_2) Halifax Avenue South is in the Northeast Minnehaha Creek drainage area, east of Minnehaha Creek and north of West 54th Street. The roadway, from West 54th Street up to and including West 52nd Street, is undulating with two main low depression areas along the roadway that extend onto the adjacent properties. The first low area is located at approximately 5320 Halifax Avenue South and the second at approximately 5240 Halifax Avenue South. These two low areas are drained by an existing 18-inch RCP storm sewer system. Pooled water in these two areas would have to rise high enough to flow over the downstream crest in the road before these areas could drain. The controlling crest elevations of the roadway at each of these areas are 879.1 feet and 879.7 feet, respectively. There is another significant depression area at the intersection of Halifax Avenue South and West 52nd Street, with a surface overflow elevation at approximately 878 feet to the southwest between 5200 and 5204 Halifax Avenue South. The size of the trunk storm sewer increases to 48-inch at the intersection of Halifax Avenue and West 52nd Street, where the storm sewer system runs along West 52nd Street to Minnehaha Creek. Modeling results indicate that the 1-percent-annual-chance flood elevations (878.3 feet in the low areas along Halifax Avenue South and 878.4 feet at the intersection of Halifax Avenue South and West 52nd Street) may impact approximately 29 principle structures in this area based on LiDAR and approximate City of Edina 2018 Comprehensive Water Resources Management Plan 12-5 building footprint data. South of West 52nd Street, these principle structures are 5300-5308, 5316, 5324, 5208-5200, 5201, and 5317-5301, 5229-5241 Halifax Avenue South, and 5200 Gorgas Avenue. Calvary Church on the west side of France Avenue may also be impacted. North of West 52nd Street, these principle structures are 5137-5129 and 5128-5120 Halifax Avenue South, and 5128-5112 Indianola Avenue. The flooding problem in this area is primarily related to the restricted storm sewer inlet capacity along Halifax Avenue South; under existing conditions, the portion of storm sewer along Halifax Avenue South between West 54th Street and West 52nd Street has only eight catch basins, allowing a total of approximately 12 cfs to enter into the storm sewer system. Because the storm sewer inlet capacity is limited, the depression areas along the road fill up until the water can overflow the controlling elevations, which are high enough to cause impacts to the surrounding principle structures. The flooding problem is also in part due to capacity restrictions in the downstream most pipes discharging to Minnehaha Creek. The problem does not appear to be tailwater induced because the peak elevation in the creek at this location is approximately 864.5 feet, roughly 14 feet lower than the peak elevation on Halifax Avenue South. Several system modifications were evaluated to reduce flood elevations in the Halifax Avenue South area. The most effective improvement option is to increase the inlet capacity of the storm sewer system along Halifax Avenue to allow more stormwater to enter the storm sewer system during. This improvement option lowers the peak flood elevation by 0.5-1.5 feet and reduces the number of potentially impacted principle structures in half. Peak runoff rates from each individual subwatershed in this area range from about 20-40 cfs during the 1-percent-annual-chance 24-hour precipitation event, so providing sufficient inlet capacity may require installation of many more catch basin inlets than typical or different catch basin types altogether. A second improvement option that was evaluated was regrading portions of Halifax Avenue South and West 52nd Street to remove the controlling road crest elevations that result in the inundation of the roadway and principle structures. This option may not be feasible for the foreseeable future because the roadway was recently reconstructed. The potential reduction in the flood elevation would depend on the final controlling elevations after regrading. Another option to reduce the flood elevation(s) is installing additional gravity storm sewer to some of the low areas near West 54th Street. In particular, subwatershed MHN_87 (backyard depression) has no piped outlet and MHN_90 has only two catch basins. Installation of additional storm sewer running south along Halifax to West 54th Street, then west to Minnehaha Creek, can lower the flood elevation by approximately 1.5 to 2.0 feet, preventing impacts to three principle structures within the MHN_87 subwatershed. For this improvement scenario, a 30-inch pipe was assumed to drain the backyard depression area in subwatershed MHN_87 and an 18-inch pipe was assumed for the MHN_90 subwatershed, both of which tied into a new 36-inch pipe at West 54th Street to Minnehaha Creek. City of Edina 2018 Comprehensive Water Resources Management Plan 12-6 12.3.1.3 Morningside/Weber Park (MS_26, MS_25, MS_41, MS_32, MS_44, MS_24, MS_15, MS_52, MS_53, MS_2, MS_38, MS_40, MS_54, MS_31, MS_33, MS_39a, and MS_39b) The Morningside/Weber Park area is in the far northeastern corner of Edina, bordering St. Louis Park to the north and Minneapolis to the east. The area is characterized by numerous backyard depressions and several large low-lying areas, including Weber Park. There are two large stormwater detention basins in the area, one located just north of West 42nd Street between Lynn Avenue and Kipling Avenue, and the other located just north of West 42nd Street and west of France Avenue South (in Weber Park). The area is drained by a piped outlet that conveys stormwater to Lake Calhoun in Minneapolis. The storm sewer and detention basins in this area were originally designed for the 2-percent-annual-chance (50-year) storm event using TP-40 rainfall frequency estimates. Portions of this area have experienced flood problems historically. Model results indicate that approximately 65 principle structures and Calvin Christian School may be impacted by the 1-percent-annual-chance flood elevations within this area. In the west part of this area, the flood elevation is approximately 872.1 feet (MS_26). In the southwest part of this area, the flood elevation is approximately 871.7 feet (MS_15). In the southeast part of this area, the flood elevation is approximately 870.1 feet (MS_52). In MS_40 and MS_39a and MS_39b, the flood elevation is 870.0 feet. In the smaller depressions without outlets to storm sewer such as MS_58, MS_20, MS_22, MS_57, MS_17, and MS_24, the peak flood elevations are 872.9 feet, 877.3 feet, 872.4 feet, 902.5 feet, 902.5 feet, and 872.1 feet respectively. Flood elevations in subwatersheds MS_20 and MS_22 are controlled by the 10-day snowmelt event, while flood elevations in the remaining subwatersheds are controlled by the 24-hour duration event. The flood problem within this area is primarily related to insufficient outlet capacity from the area and limited flood storage volume. To sufficiently lower water levels in this area would require the addition of at least 35 acre-feet below some of the lowest lying areas in Morningside/Weber Park. Restricted storm sewer pipe capacity within the Morningside/Weber Park area is a tertiary and much smaller problem, localized to a few small areas. Several flood improvement options were evaluated to reduce flood elevations in this area. One of the most effective improvement options is to provide additional discharge capacity from this area to Lake Calhoun or to another receiving water body. The addition of two 48-inch pipes from Weber Park lowers water levels by approximately 2 feet in Weber Park and about 0.5 feet in some areas south of West 42nd Street (e.g., MS_15, MS_18, MS_50, MS_52, and MS_53). This improvement option reduces the number of potentially impacted principle structures by 8 structures. Another potential flood improvement option is to add new pipes to convey runoff from subwatersheds MS_15, MS_2, and MS_53 to the main trunk storm sewer under West 42nd Street, and double the flow capacity of the trunk system along West 42nd Street. The additional and upsized pipes could reduce the peak flood elevations by 0.5 to 1.5 feet, reducing the number of potentially impacted principle structures in that immediate area by 7 structures. However, additional capacity in the upstream storm sewer system City of Edina 2018 Comprehensive Water Resources Management Plan 12-7 could result in increased flood elevations in the low-lying area in and near Weber Park, negatively impacting the surrounding principle structures. A closer evaluation would be needed to determine the best pipe sizes to balance the benefit with the other impacts. Another potential improvement option is to increase flood storage capacity in this area. In the ball fields north of West 42nd Street and east of Grimes Avenue South, there is about 6 acres that could be lowered with the intent of adding additional storage. Also, the approximately 3-acre wooded area east of Calvin Christian School could be regraded to add storage, if necessary. Model results indicate that the additional storage reduces the peak flood elevations by 2.0 to 3.0 feet in the Weber Park area. However, because many of the structures in this area are so low, the corresponding reduction in the number of potentially impacted structures was only 10 principle structures. Several of the subwatersheds impacted by the 1-percent-annual-chance flood elevations are backyard depression areas that do not have outlets. Flood elevations in these areas could be reduced by installing outlets from these areas to existing storm sewer. Subwatersheds that have sufficient elevation above the downstream flood levels are MS_20, MS_57, and MS_17, for example. Flood problems in this area has been evaluated before and by others, including a feasibility study conducted in 2006 by Barr Engineering and a recent analysis by University of Minnesota students as a senior design capstone project. The best improvement option still appears to be providing additional outlet capacity to Minneapolis. The City will consider working with the City of Minneapolis regarding the feasibility of installing additional storm sewer to Lake Calhoun to reduce flood risk in the Morningside/Weber Park area. 12.3.1.4 Edinbrook Lane and Westbrook Lane (MHN_79) There is a backyard depression west of TH 100 and southeast of the intersection of Edinbrook Lane and Westbrook Lane that receives runoff from subwatershed MHN_79, the watershed to the west (MHN_78), and TH 100. The depression has a 21-inch piped outlet to the TH 100 storm sewer system and a surface overflow north at approximately 893.6 feet, adjacent to 5005 Edinbrook Lane. Modeling results indicate that the 1-percent-annual-chance flood elevation (892.5 feet) may impact three principle structures (5013 Edinbrook Lane and 4801–4805 Westbrook Lane), and may very nearly impact three other principle structures (5009 and 5017 Edinbrook Lane, and 4811 Westbrook Lane), based on LiDAR and approximate building footprint data. The modeling results suggest the flooding problem is not driven by the water level in Minnehaha Creek. Instead, it is primarily related to the quantity of water coming into the depression from west of MHN_79 (MHN_78) and from backflow from the TH 100 storm sewer system. There are several options that should be considered to reduce flood risk in this area, including diverting flows to reduce the volume of water to the low area and/or improving outlet conditions. The runoff contributing from MHN_78, which has a peak flow rate of over 50 cfs, could be rerouted through new storm sewer pipes running north under Westbrook Lane to Minnehaha Creek. Alternatively, the surface overflow could be made more efficient (e.g., a concrete flume with vegetation cleared) and the elevation could be lowered. However, this second option may require purchasing 5005 Edinbrook Lane. The City will City of Edina 2018 Comprehensive Water Resources Management Plan 12-8 also consider working with MnDOT to evaluate options to reduce or eliminate flow into this area from the TH 100 storm sewer system, with a backflow preventer or by increasing the conveyance capacity in the TH 100 system, for example. Finally, all of the potentially impacted principle structures in this area could be acquired so that the area could be used and possibly improved as a dry basin for storage and, potentially, a water quality treatment basin. Soil maps show that the soils in this area are “B” soils with moderate potential for infiltration. 12.3.1.5 North of Morningside Road between Lynn Avenue and Crocker Avenue (MS_22) There is a backyard depression north of Morningside Road between Lynn Avenue and Crocker Avenue. The depression is land-locked, with a surface overflow to the east (adjacent to 4226 Crocker Avenue) at approximately 875.8 feet, which is about 5 feet above the approximate low principle structure elevations in this area. The 1-percent-annual-chance flood elevation (872.4 feet) is determined by the 10-day snowmelt event and may impact up to six principle structures (4226–4236 Crocker Avenue), based on LiDAR data and approximate building footprints. It is recommended that a survey be conducted to determine low entry elevations for these seven principle structures. If the survey indicates that these principle structures are potentially impacted by the 1-percent- annual-chance flood elevation, it is recommended that a storm sewer outlet be installed in this backyard depression. A new storm sewer could connect to either the existing system on Crocker Avenue or Lynn Avenue, which both drain to the trunk storm sewer on West 42nd Street and ultimately to Weber Park Pond. Additional pipe capacity downstream to Weber Park Pond and, potentially, additional storage in Weber Park may also be required with this option due to other flood concerns within this general area. Access to the backyard depression for installation of a new pipe may be challenging due to the developed nature of the neighborhood and private property ownership. 12.3.1.6 Branson Street between West 44th Street and Morningside Road (MS_3, MS_48, and MS_7) There are local depression areas along Branson Street and in the backyards north and south of Branson Street just west of Grimes Avenue. Branson Street (MS_48) and the backyard area to the north (MS_3) have catch basins and are drained by a 15-inch pipe originating at Branson Street and connecting north to the storm sewer system on Morningside Road. The backyard depression to the south (MS_7) is land- locked and does not have a piped outlet. It is hydraulically connected via surface overflows between 4303, 4301, and 4215 Branson Street at approximately 901.5 feet (according to LiDAR data). In addition, the storm sewer system on West 44th Street surcharges during the 1-percent-annual-chance 24-hour storm event; as a result, stormwater flows from West 44th Street into the backyard depression area (MS_7). At the 1-percent-annual-chance flood level, there are 12 principle structures that are potentially impacted and Branson Street will have approximately 2 feet of water in its lowest spot. This area was also identified as an area of concern in the 2003 and 2009 CWRMPs. It is recommended that one or more inlets be installed in the backyard depression areas, pipes be added, and pipe sizes increased north to the existing storm sewer system under Morningside Road. The addition City of Edina 2018 Comprehensive Water Resources Management Plan 12-9 of an inlet to MS_7 with a connection to the pipe system on West 44th Street was evaluated, but this alternative would require the entire pipe system along West 44th Street and Morningside Avenue to be upgraded. Additional flow capacity in the storm sewer system to Weber Park Pond and, potentially, additional storage in Weber Park may be required with this option due to other flood concerns within this general area. Other considerations include adding additional storage capacity in this area. Storage could be added in MS_7 by lowering the backyard depression. Alternatively, in the event of street reconstruction, the low area of Branson Street could be raised and underground storage could be added under Branson Street and Oakdale Avenue (up to approximately 700 linear feet). Underground storage under Oakdale Avenue could intercept runoff from the upper parts of the MS_48 watershed. 12.3.2 Construction/Upgrade of Water Quality Basins The 2003 P8 modeling analysis indicated that under average conditions the predicted annual removal of total phosphorus from the ponds and wetlands in the Northeast Minnehaha Creek drainage area is greater than the desired 60 percent removal rate. As a result, no specific recommendations are given for the construction or upgrade of water quality basins in this watershed. Many techniques are available to reduce pollutant loading from stormwater runoff, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and further improve the quality of stormwater runoff from this drainage area. Table 12.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Northeast Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) MS_1 0.5 23 4 0.3 0.1 0.3 2 0.2 MS_10 3.3 48 35 1.6 0.6 1.9 18 0.8 MS_11 1.5 80 16 0.9 0.3 0.9 9 0.5 MS_13 4.8 25 17 2.0 0.9 2.9 7 0.9 MS_14 1.4 27 13 0.6 0.3 0.8 6 0.3 MS_15 1.2 25 12 0.5 0.2 0.7 6 0.3 MS_16 4.0 25 21 1.7 0.8 2.4 9 0.8 MS_17 2.2 25 19 1.0 0.4 1.3 9 0.5 MS_18 2.3 25 16 1.0 0.4 1.4 7 0.5 MS_19 3.2 25 22 1.4 0.6 1.9 9 0.7 MS_2 10.0 25 57 4.4 1.9 6.0 24 2.1 MS_20 5.4 21 44 2.4 1.0 3.3 21 1.2 MS_21 5.0 25 28 2.2 0.9 3.0 12 1.1 MS_22 4.8 25 37 2.1 0.9 2.9 17 1.0 MS_23 1.4 23 9 0.8 0.3 0.8 4 0.4 MS_24 2.0 25 20 1.1 0.4 1.2 10 0.6 MS_25 1.0 22 7 0.5 0.2 0.6 4 0.3 MS_26 4.3 25 38 2.4 0.8 2.6 19 1.3 MS_27 4.0 25 28 1.8 0.8 2.4 13 0.9 MS_28 1.7 25 18 0.8 0.3 1.0 9 0.4 MS_29 4.0 25 25 1.9 0.8 2.4 11 1.0 MS_3 3.3 25 23 1.5 0.6 2.0 10 0.7 MS_30 5.9 25 34 2.8 1.1 3.5 15 1.4 MS_31 6.0 23 37 3.2 1.1 3.6 18 1.7 MS_32 3.6 25 22 1.9 0.7 2.2 10 0.9 MS_33 5.4 26 38 2.5 1.0 3.3 17 1.2 MS_34 3.4 25 23 1.5 0.6 2.1 10 0.7 MS_35 3.8 25 22 1.7 0.7 2.3 9 0.8 MS_36 1.8 25 10 0.8 0.3 1.1 4 0.4 MS_37 2.2 25 18 1.0 0.4 1.3 9 0.5 MS_38 1.5 27 13 0.7 0.3 0.9 7 0.4 MS_39a 5.5 32 42 3.0 1.0 3.3 21 1.6 MS_39b 8.7 24 52 4.3 1.6 5.2 24 2.2 MS_4 3.7 25 34 1.7 0.7 2.2 16 0.8 MS_40 12.0 43 74 6.4 2.3 7.2 35 3.3 MS_41 0.9 21 6 0.5 0.2 0.5 3 0.3 MS_42 4.4 25 26 1.9 0.8 2.6 11 0.9 MS_43 5.2 25 40 2.3 1.0 3.1 19 1.1 MS_44 1.1 23 10 0.6 0.2 0.7 5 0.3 MS_45 2.1 25 21 1.0 0.4 1.2 11 0.5 MS_46 5.5 13 27 2.4 1.0 3.3 11 1.1 MS_47 4.3 25 17 1.9 0.8 2.6 7 0.8 MS_48 10.2 25 38 4.4 1.9 6.1 16 2.0 MS_49 5.3 25 44 2.4 1.0 3.1 21 1.2 MS_5 3.3 25 26 1.5 0.6 2.0 12 0.7 MS_50 3.3 25 25 1.5 0.6 2.0 12 0.7 MS_51 6.9 25 36 3.0 1.3 4.1 15 1.4 MS_52 4.5 25 36 2.0 0.9 2.7 17 1.0 MS_53 1.0 25 10 0.5 0.2 0.6 5 0.2 MS_54 10.1 37 51 4.8 1.9 6.1 22 2.3 MS_55 6.7 27 19 3.2 1.1 4.0 8 1.5 MS_56 0.8 25 6 0.3 0.1 0.5 3 0.2 MS_57 1.8 25 18 0.8 0.3 1.1 9 0.4 MS_58 2.8 11 24 1.5 0.5 1.7 12 0.7 MS_59 1.8 25 14 0.8 0.3 1.1 7 0.4 MS_6 4.2 22 21 1.8 0.8 2.5 8 0.8 MS_7 4.8 25 32 2.1 0.9 2.9 14 1.0 MS_8 3.8 25 29 1.7 0.7 2.3 13 0.8 MS_9 2.5 25 24 1.1 0.5 1.5 12 0.5 MHN_1 10.7 32 87 5.1 2.0 6.4 42 2.5 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) Table 12.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Northeast Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) MHN_10 1.3 25 10 0.6 0.2 0.8 4 0.3 MHN_11 6.7 47 58 3.5 1.3 4.0 29 1.9 MHN_12 2.2 25 20 1.1 0.4 1.3 10 0.6 MHN_13 7.2 25 37 3.2 1.4 4.3 15 1.5 MHN_14 5.9 25 38 2.6 1.1 3.5 16 1.2 MHN_15 5.4 25 35 2.4 1.0 3.2 15 1.1 MHN_16 8.5 25 39 3.7 1.6 5.1 16 1.7 MHN_17 9.9 25 50 5.0 1.8 5.9 22 2.5 MHN_18 2.6 25 13 1.4 0.5 1.5 6 0.8 MHN_19 7.1 25 59 3.4 1.3 4.2 29 1.7 MHN_2 1.4 25 12 0.7 0.3 0.9 6 0.3 MHN_20 8.9 25 40 4.4 1.6 5.3 18 2.2 MHN_21 5.4 25 44 2.7 1.0 3.3 22 1.4 MHN_22 5.7 25 36 3.2 1.1 3.4 18 1.7 MHN_23 9.9 25 78 5.2 1.9 6.0 39 2.7 MHN_24 5.6 25 37 2.8 1.1 3.4 17 1.4 MHN_25 1.8 25 16 0.8 0.3 1.1 8 0.4 MHN_26 2.4 25 25 1.1 0.4 1.4 13 0.5 MHN_27 0.6 30 5 0.3 0.1 0.3 3 0.2 MHN_28 0.5 21 4 0.3 0.1 0.3 2 0.1 MHN_29 7.6 25 71 3.4 1.4 4.6 35 1.6 MHN_3 3.6 29 31 1.6 0.7 2.1 15 0.8 MHN_30 4.7 25 26 2.1 0.9 2.8 11 1.0 MHN_31 7.8 25 61 3.5 1.5 4.7 28 1.7 MHN_32 9.6 25 72 4.6 1.8 5.8 34 2.3 MHN_33 5.2 25 46 2.3 1.0 3.1 22 1.1 MHN_34 4.5 25 38 2.0 0.8 2.7 18 1.0 MHN_35 1.2 25 12 0.5 0.2 0.7 6 0.3 MHN_36 3.5 29 26 1.6 0.7 2.1 12 0.8 MHN_37 0.7 41 8 0.3 0.1 0.4 5 0.2 MHN_38 2.0 51 17 1.0 0.4 1.2 8 0.5 MHN_39 5.3 54 37 2.7 1.0 3.2 17 1.4 MHN_4 3.4 25 14 1.4 0.6 2.0 6 0.7 MHN_40 14.8 22 75 6.4 2.8 8.9 30 2.9 MHN_41 2.4 25 24 1.1 0.4 1.4 12 0.5 MHN_42 6.1 25 31 2.7 1.1 3.6 13 1.3 MHN_43 6.0 25 33 2.7 1.1 3.6 14 1.3 MHN_44 10.7 25 39 4.7 1.9 6.4 16 2.2 MHN_46 5.5 25 59 2.6 1.0 3.3 31 1.3 MHN_47 1.1 25 10 0.5 0.2 0.7 5 0.2 MHN_48 3.4 34 33 1.6 0.6 2.1 17 0.8 MHN_49 1.4 25 15 0.6 0.3 0.8 8 0.3 MHN_5 7.7 25 60 3.4 1.5 4.6 28 1.6 MHN_50 8.4 25 40 3.7 1.6 5.0 17 1.7 MHN_51 2.6 25 26 1.2 0.5 1.6 13 0.6 MHN_52 1.6 25 16 0.8 0.3 0.9 8 0.4 MHN_53 3.7 25 22 1.6 0.7 2.2 9 0.8 MHN_54 1.3 25 9 0.6 0.2 0.8 4 0.3 MHN_55 2.7 25 17 1.2 0.5 1.6 7 0.6 MHN_56 2.1 44 23 1.0 0.4 1.3 12 0.5 MHN_57 1.5 79 12 0.8 0.3 0.9 6 0.5 MHN_58 5.3 75 48 2.9 1.0 3.2 24 1.5 MHN_59 1.3 80 13 0.7 0.3 0.8 6 0.4 MHN_6 3.9 25 24 1.7 0.7 2.4 10 0.8 MHN_60 0.6 25 7 0.3 0.1 0.4 4 0.2 MHN_60b 1.7 25 18 0.8 0.3 1.0 9 0.4 MHN_61 3.9 48 34 2.0 0.7 2.4 16 1.0 MHN_62 6.7 57 68 3.6 1.3 4.0 35 1.9 MHN_63 2.8 80 23 1.6 0.5 1.7 11 0.9 MHN_64 4.6 25 24 2.0 0.9 2.7 10 0.9 Table 12.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Northeast Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) 24-Hour Precipitation Event 10%-Annual-Chance (10-Year)Watershed Information 1%-Annual-Chance (100-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 1%-Annual-Chance (100-Year) MHN_65 14.0 30 110 6.7 2.7 8.4 53 3.4 MHN_66 12.7 38 103 6.4 2.4 7.6 50 3.3 MHN_67 2.1 3 8 0.8 0.4 1.3 3 0.3 MHN_68 0.8 25 9 0.4 0.2 0.5 4 0.2 MHN_69 21.9 25 189 10.0 4.2 13.2 92 4.9 MHN_69B 6.4 31 64 3.0 1.2 3.8 33 1.5 MHN_7 3.8 25 21 1.7 0.7 2.2 9 0.8 MHN_71 6.5 27 19 2.9 1.1 3.9 8 1.3 MHN_72 8.8 34 57 3.8 1.7 5.3 23 1.8 MHN_73 2.1 76 15 1.1 0.4 1.2 7 0.6 MHN_74 15.0 25 80 6.8 2.8 9.0 34 3.3 MHN_76 2.1 80 19 1.1 0.4 1.2 9 0.6 MHN_77 2.3 80 14 1.3 0.4 1.4 6 0.7 MHN_78 9.7 31 75 4.5 1.8 5.8 34 2.2 MHN_79 2.9 29 31 1.3 0.6 1.8 17 0.7 MHN_79a 0.7 31 9 0.3 0.1 0.4 5 0.2 MHN_8 2.8 24 31 1.3 0.5 1.7 17 0.6 MHN_80 8.9 28 64 4.0 1.7 5.4 29 1.9 MHN_81 2.0 63 18 1.0 0.4 1.2 9 0.6 MHN_82 3.3 62 28 1.6 0.6 2.0 12 0.8 MHN_83 5.3 2 21 2.0 1.0 3.1 8 0.8 MHN_84 4.6 62 37 2.4 0.9 2.8 17 1.2 MHN_85 2.0 27 20 0.9 0.4 1.2 10 0.4 MHN_86 1.7 25 13 0.8 0.3 1.0 6 0.4 MHN_87 4.3 25 40 1.9 0.8 2.5 20 0.9 MHN_88 3.5 25 25 1.6 0.7 2.1 11 0.7 MHN_89 7.7 26 51 3.4 1.5 4.6 22 1.6 MHN_9 14.6 23 103 7.4 2.8 8.8 50 3.8 MHN_90 2.5 30 19 1.1 0.5 1.5 9 0.6 MHN_91 0.9 25 8 0.4 0.2 0.6 4 0.2 ECC_1 5.3 8 38 2.2 1.0 3.2 17 1.0 ECC_10 2.8 11 24 1.3 0.5 1.7 12 0.6 ECC_11 3.3 14 26 1.4 0.6 2.0 12 0.6 ECC_12 1.7 25 17 0.8 0.3 1.0 9 0.4 ECC_13 1.8 25 18 1.0 0.3 1.1 9 0.5 ECC_14 3.4 13 31 1.4 0.6 2.0 15 0.7 ECC_15 4.7 2 25 1.9 0.9 2.8 10 0.8 ECC_2 4.0 20 24 1.7 0.8 2.4 10 0.8 ECC_3 8.4 11 53 3.5 1.6 5.0 22 1.6 ECC_4 8.7 8 49 3.8 1.6 5.2 21 1.8 ECC_5 15.6 3 43 5.8 2.9 9.4 15 2.3 ECC_6 10.2 6 62 4.0 1.9 6.1 24 1.7 ECC_7 31.6 2 118 13.4 5.9 18.9 47 6.1 ECC_8 4.6 2 30 1.8 0.9 2.7 12 0.8 ECC_9 10.1 5 59 4.3 1.9 6.1 25 2.0 MHC_100a 4.9 64 58 2.6 0.9 2.9 32 1.4 MHC_100b 2.2 64 25 1.2 0.4 1.3 13 0.6 MHC_100c 2.5 64 29 1.3 0.5 1.5 16 0.7 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 184 885.2 885.1 1608 871.5 869.9 1610 906.1 904.3 1611 904.6 902.1 1612 900.0 899.1 1617 896.0 895.6 1618 873.9 871.9 1619 871.0 870.7 1620 871.0 870.6 1621 870.4 869.4 1624 871.0 869.6 1626 870.0 868.2 1628 870.0 868.2 1629 870.0 868.2 1633 870.0 868.2 1634 870.0 868.2 1636 880.4 880.3 1637 876.9 876.8 1638 874.9 874.7 1640 874.9 874.7 1642 903.1 902.3 1645 899.9 898.7 1648 892.6 892.5 1649 879.6 878.6 1651 875.1 874.9 1653 871.9 869.7 1654 875.4 871.7 1656 872.1 869.9 1659 870.1 869.1 1661 869.4 867.4 1663 869.8 867.8 1669 889.5 887.5 1671 887.0 882.2 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event 1681 887.2 887.2 1682 889.4 889.4 1684 886.9 886.9 1685 882.0 882.0 1687 882.5 882.5 1689 880.2 880.2 1691 880.3 879.0 1692 880.4 879.8 1693 880.4 876.7 1694 880.4 876.3 1695 880.3 877.1 1697 880.3 877.1 1702 878.3 878.0 1704 882.0 882.0 1705 881.0 881.0 1714 868.9 868.9 1718 892.8 892.8 1721 884.4 884.1 1722 889.5 889.5 1728 895.1 894.8 1729 895.1 894.8 1731 895.1 894.8 1732 895.1 894.9 1736 894.0 894.0 1741 895.1 894.7 1744 895.5 895.3 1870 893.4 893.2 1872 881.6 880.9 2151 896.2 896.1 2152 892.2 892.1 2153 890.0 888.5 2154 900.2 899.7 2235 882.6 882.6 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event 2237 867.8 867.8 2257 874.1 873.5 2378 901.6 899.9 2384 870.0 868.2 2385 885.4 885.4 2387 876.3 875.9 2389 875.9 873.3 2390 878.6 878.6 2394 873.7 871.7 2397 880.0 880.0 2398 880.3 877.1 2400 884.3 884.3 2401 883.2 883.2 2402 881.7 881.7 2403 880.8 880.8 2404 880.3 880.3 2406 888.9 ¹ 888.4 2412 877.9 877.9 2430 897.4 897.3 2431 895.2 895.2 2432 894.6 894.6 2459 886.2 886.1 1681$I 881.0 880.5 1682$I 880.2 879.7 1684$I 878.8 878.3 1685$I 877.8 877.3 1687$I 875.6 875.1 1689$I 875.5 875.6 1691$I 877.8 876.3 1692$I 877.2 876.1 1693$I 876.9 876.1 1694$I 876.3 876.0 1695$I 876.2 876.0 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event 1697$I 875.0 875.3 1702$I 875.4 875.4 1704$I 874.9 874.2 1705$I 874.4 873.1 1714$I 868.2 867.5 1718$I 879.6 879.6 1721$I 881.9 881.9 1722$I 884.2 883.9 1728$I 888.9 ¹ 887.9 1729$I 888.9 ¹ 887.9 1731$I 888.9 ¹ 887.8 1732$I 888.9 ¹ 887.7 1736$I 888.9 ¹ 887.7 1741$I 892.2 891.6 1744$I 888.9 ¹ 887.7 184$I 872.2 872.2 2235$I 871.6 870.0 2237$I 866.9 865.9 2385$I 872.6 872.6 2387$I 870.4 870.4 2390$I 874.0 872.3 2397$I 878.8 877.5 2398$I 876.7 876.1 2400$I 880.0 880.0 2401$I 879.4 878.5 2402$I 878.6 877.0 2403$I 878.4 876.9 2404$I 878.2 876.6 2412$I 875.5 875.5 ECC_1 byd 899.5 898.7 ECC_10 street 877.8 876.8 ECC_11 street/lot 885.4 884.9 ECC_12 cul-de-sac 877.7 870.9 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event ECC_13 cul-de-sac 869.1 869.0 ECC_14 street 894.0 893.8 ECC_15 street 874.6 874.3 ECC_2 pond 898.6** 899.5 0.9 899.3 0.7 ECC_3 pond 898.8** 904.4 ¹ 5.6 900.3 1.5 ECC_4 pond 899.9** 905.7 5.8 903.5 3.6 ECC_5 pond 888.9** 888.9 0.0 888.9 0.0 ECC_6 pond 909.0** 912.5 3.5 911.8 2.8 ECC_7 byd 887.1 ¹ 884.4 ECC_8 byd 886.3 885.3 ECC_9 pond 904.1** 905.8 1.7 905.5 1.4 FID1916 902.5 900.9 FID1917 893.2 890.4 FID1918 893.1 890.3 FID1921 893.0 890.1 FID1922 892.8 889.9 FID1923 892.3 888.9 FID1924 892.4 889.7 FID1934 873.5 872.6 FID1955 876.2 874.6 FID1956 876.4 874.6 FID2079 895.1 894.8 FID2079$I 889.3 889.3 FID2333 889.6 889.6 FID2333$I 888.9 ¹ 887.7 FID2335 894.6 894.6 FID2335$I 888.9 ¹ 887.7 FID2343 893.1 893.1 FID2343$I 888.9 ¹ 887.7 FID2344 893.5 893.5 FID2344$I 888.9 ¹ 887.7 FID2427 889.7 889.4 FID2427$I 878.7 878.7 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event FID3003 884.6 884.3 FID3003$I 877.8 877.8 FID36 895.3 895.0 FID36$I 888.9 ¹ 887.7 FID4142 895.1 894.8 FID4142$I 889.3 889.3 FID4537 883.2 ¹ 881.9 FID4545 902.3 902.3 FID4760 884.6 884.3 FID4760$I 877.8 877.8 FID4762 884.6 884.3 FID4762$I 878.6 878.6 FID57 892.7 889.8 FID58 896.3 893.9 FID6024 884.4 884.1 FID6024$I 882.0 882.0 FID6025 884.4 884.1 FID6025$I 882.0 882.0 FID6248 870.0 868.3 FID6467 872.5 871.5 FID6614 897.7 896.5 FID6618 901.6 899.7 FID6621 901.7 900.5 FID68 893.4 893.4 FID68$I 887.3 887.3 FID6840 891.1 891.1 FID6841 890.5 890.5 FID6842 888.9 ¹ 887.7 FID6846 888.9 ¹ 887.7 FID6869 909.8 909.6 FID6874 899.5 896.1 FID6880 902.6 898.7 FID6881 928.7 928.7 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event FID7169 903.3 902.4 LS7 882.1 880.9 LS7a 890.8 889.3 MH-2 868.5 866.2 MHC_100a hwy ditch 896.5 893.5 MHC_100b hwy ditch 891.9 890.3 MHC_100c hwy ditch 888.9 ¹ 887.7 MHN_1 pond 867.8** 878.3 ¹ 10.5 872.7 4.9 MHN_10 street 885.4 885.2 MHN_10$I 885.0 885.0 MHN_11 pond 870.2** 876.8 6.6 873.9 3.7 MHN_12 byd 880.5 880.4 MHN_13 street 885.8 885.7 MHN_13$I 884.8 884.5 MHN_14 street 884.4 884.1 MHN_14$I 882.6 882.5 MHN_15 street 889.2 888.9 MHN_15$I 880.9 880.9 MHN_16 street 889.7 889.4 MHN_16$I 878.1 878.1 MHN_17 street 892.1 891.6 MHN_17$I 885.0 885.0 MHN_18 byd 898.2 898.1 MHN_19 street 895.1 894.8 MHN_19$I 888.9 ¹ 887.7 MHN_2 street 878.3 878.0 MHN_2$I 875.4 875.3 MHN_20 street 895.1 894.8 MHN_20$I 890.6 890.6 MHN_21 street 895.2 895.0 MHN_21$I 892.4 892.4 MHN_22 street 894.5 894.4 MHN_22$I 893.0 892.5 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event MHN_23 street 895.1 894.7 MHN_23$I 895.1 894.7 MHN_24 street 895.1 894.8 MHN_24$I 888.9 ¹ 888.1 MHN_25 street 895.3 895.1 MHN_25$I 888.9 ¹ 887.7 MHN_26 street 889.7 889.6 MHN_27 creek 872.1 871.4 MHN_27$I 870.4 870.4 MHN_28 creek 872.9 872.2 MHN_28$I 868.3 868.3 MHN_29 892.2 892.1 MHN_3 street 878.5 878.2 MHN_3$I 875.7 874.3 MHN_30 street 888.9 ¹ 888.5 MHN_31 street 888.9 ¹ 888.3 MHN_32 street 897.2 897.1 MHN_32$I 897.2 897.1 MHN_33 street 889.7 889.5 MHN_33$I 888.9 ¹ 888.2 MHN_34 street 893.0 892.6 MHN_35 street 889.4 887.9 MHN_36 creek 890.0 889.0 MHN_37 street 891.1 891.0 MHN_38 yard 892.7 892.6 MHN_39 street 899.8 899.6 MHN_4 street 880.5 880.2 MHN_4$I 874.3 874.3 MHN_40 street/byd 890.2 888.7 MHN_41 byd 894.0 ¹ 892.0 MHN_42 street 867.0 866.9 MHN_42$I 867.0 866.4 MHN_43 street 892.2 892.1 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event MHN_43$I 888.7 888.7 MHN_44 street 894.5 894.2 MHN_44$I 888.8 ¹ 888.6 MHN_46 street 900.2 895.8 MHN_47 street 905.4 901.7 MHN_48 897.0 896.9 MHN_49 byd 887.8 885.2 MHN_5 street 872.5 872.2 MHN_5$I 869.9 867.3 MHN_50 street/byd 889.0 888.8 MHN_50$I 885.5 885.1 MHN_51 street 895.5 895.3 MHN_51$I 888.9 ¹ 887.7 MHN_52 street 895.1 894.8 MHN_52$I 888.9 ¹ 887.7 MHN_53 street 884.6 884.3 MHN_53$I 877.3 877.2 MHN_54 street 884.6 884.3 MHN_54$I 877.7 877.7 MHN_55 street/yd 878.4 878.1 MHN_55$I 873.9 872.1 MHN_56 street 880.3 879.3 MHN_56$I 880.1 878.4 MHN_57 street 887.3 887.1 MHN_57$I 879.5 879.0 MHN_58 street/lot 882.8 882.3 MHN_58$I 882.9 882.3 MHN_59 street 885.0 884.8 MHN_59$I 881.0 881.0 MHN_6 street/yd 884.6 884.3 MHN_6$I 877.1 877.1 MHN_60 creek 887.6 ¹ 886.7 MHN_60b street 894.2 894.1 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event MHN_61 byd 877.4 876.9 MHN_61R 879.8 879.7 MHN_61R$I 876.5 874.8 MHN_62 street 878.3 878.0 MHN_62$I 875.5 875.5 MHN_63 street 881.6 881.5 MHN_63$I 876.1 874.4 MHN_64 street 889.5 885.2 MHN_65 byd 878.1 ¹ 874.7 MHN_66 pond 869.4** 875.7 6.3 872.0 2.6 MHN_67 creek 889.1 882.1 MHN_68 byd 878.3 ¹ 874.0 MHN_69 street 892.3 889.6 MHN_69B byd 917.2 917.0 MHN_7 street 884.6 884.3 MHN_7$I 877.6 877.6 MHN_71 street 877.4 876.7 MHN_71$I 876.2 874.4 MHN_72 street/lot 884.6 884.3 MHN_72$I 879.4 879.4 MHN_73 street/lot 887.1 886.9 MHN_73$I 881.9 881.4 MHN_74 879.1 878.8 MHN_74$I 879.1 878.8 MHN_76 street/lot 880.4 877.5 MHN_76$I 876.0 875.9 MHN_77 street 880.2 880.0 MHN_77$I 878.1 876.6 MHN_78 street 896.8 896.5 MHN_79 byd 892.5 892.0 MHN_79a hwy ditch 910.7 910.3 MHN_8 creek 887.6 ¹ 885.7 MHN_80 street 891.0 890.5 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event MHN_81 street 901.1 900.6 MHN_82 street 880.6 880.5 MHN_82$I 877.0 876.4 MHN_83 893.3 892.7 MHN_84 street 880.3 877.5 MHN_84$I 875.2 875.2 MHN_85 street/yd 891.2 889.7 MHN_86 cul-de-sac 874.7 874.6 MHN_87 byd 878.3 877.5 MHN_88 byd 870.9 870.5 MHN_89 street/yd 878.4 878.1 MHN_89$I 872.8 870.9 MHN_9 street 879.9 879.5 MHN_9$I 879.9 879.9 MHN_90 street 878.3 877.9 MHN_90$I 875.8 875.7 MHN_91 byd 884.2 884.0 MS_1 street/yd 872.1 870.3 MS_10 byd 897.6 896.5 MS_11 parking lot 897.4 896.5 MS_13 872.5 870.1 MS_14 byd 903.1 902.1 MS_15 byd 871.7 869.8 MS_16 870.0 868.2 MS_17 byd 902.5 901.5 MS_18 871.0 868.4 MS_19 street/yd 880.6 880.5 MS_2 street 875.2 875.0 MS_20 byd 877.3 ¹ 874.8 MS_21 875.1 874.9 MS_22 byd 872.4 ¹ 870.9 MS_23 street 870.1 869.0 MS_24 byd 872.1 870.3 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event MS_25 street/yd 872.1 870.3 MS_26 pond 865.0 872.1 7.1 870.3 5.3 MS_27 byd 871.5 869.9 MS_28 byd 871.0 869.6 MS_29 street 870.1 869.0 MS_3 byd 902.2 900.0 MS_30 street 872.8 871.0 MS_31 street 870.0 869.2 MS_32 byd 872.9 871.0 MS_33 street/yd 870.0 868.2 MS_34 street 902.6 900.9 MS_35 street 904.6 903.6 MS_36 street 906.5 904.6 MS_37 street 906.1 905.9 MS_38 parking lot 870.0 868.2 MS_39a field 870.0 868.2 MS_39b field 870.0 865.9 MS_4 902.0 899.6 MS_40 pond 861.6** 870.0 8.4 868.2 6.6 MS_41 street 872.1 870.3 MS_42 street 872.1 870.7 MS_43 street/byd 903.2 902.5 MS_44 street/yd 872.1 870.3 MS_45 872.9 872.6 MS_46 byd 872.9 871.1 MS_47 898.4 896.9 MS_48 street 902.2 900.8 MS_49 street 870.0 868.2 MS_5 903.3 902.4 MS_50 byd 870.0 868.2 MS_51 street 875.8 873.3 MS_52 byd 870.1 868.2 MS_53 byd 871.7 870.2 Table 12.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1%-Annual-Chance (100-Year) Storm Event Results 24-Hour Precipitation Event MS_54 byd 870.0 868.2 MS_55 street 868.4 868.1 MS_56 byd 903.4 902.6 MS_57 byd 902.5 902.2 MS_58 byd 872.9 871.0 MS_59 byd 909.8 909.7 MS_6 street 902.2 901.5 MS_7 byd 902.2 900.6 MS_8 street 903.4 902.6 MS_9 byd 875.5 873.4 N131 868.7 868.1 N133 872.1 870.3 N134 872.1 870.5 N135 871.9 870.2 N136 883.5 873.0 N145 872.1 870.3 N146 872.1 870.3 N147 depression 870.0 868.4 N151 869.3 866.5 N152 872.9 871.0 N235 889.7 889.4 N235$I 878.4 878.4 To_SLP 867.9 865.4 100 456717 456721 W 44th St W 39th St Wooddale Ave Country Club Rd Mi n nehaha CreekMinneapolisMinneapolis Saint Louis ParkSaint Louis Park MHC_3 MHC_2 ECC_7 MHN_69 ECC_5 MHN_74 MHN_9 MHC_1 MHN_40 MS_40 MS_2 MHN_65 MHN_66 MS_48 MS_54 ECC_6 MHN_1 ECC_9 MHN_44 ECC_4 ECC_3 MHN_23 MHN_17 MHN_78 MHN_32 MS_39b MHN_80 MHN_20 MHN_72 MHN_5 MHN_16 MS_51 MHN_50 MHN_31 MHN_89 MHN_29 MS_31 MHN_13 MHN_19 MS_7 MHN_11 MHN_62 MS_46 MS_20 MS_33 MHN_71 ECC_1 MS_43 MS_21 MHN_42 MS_13 MHN_14 MS_22 MS_39a MHN_22MHN_24 MS_8 MHN_69B ECC_8 MS_52 MHN_21 MHN_15 MS_42 MS_4 MHN_58 MS_47 MHN_83 MS_26 MHN_33 ECC_15 MS_27 ECC_2 MS_3 MS_5 MHN_30 MS_35 MHN_84 MHN_64 MHN_6 MHN_34 MS_34 MHN_3 MS_50 MS_10 MHN_61 MHN_53 MS_9 MS_58 MHN_36 MHN_82 ECC_10 MS_18 MS_17 MS_37 MHN_41 MHN_73 ECC_13 MS_55MS_30 MS_49 MS_6 MHN_43 MHN_46 MHN_39 MS_16 MS_29 MS_32 MHN_7 MHN_87 MHC_100a MS_19 MHN_4 ECC_14 MHN_88 ECC_11 MHN_48 MHN_8 MHN_79 MHN_63 MHN_55 MHN_51 MHN_18 MS_45 MHN_90 MS_24 MHN_26 MHN_77 MS_59 MS_36 MHN_12 MS_57 MHN_56 MHN_67 MHN_76 MHC_100c MS_28 MHN_81 MHN_38 MHN_85 MS_11 MHN_25 MS_38 ECC_12 MHC_100b MHN_86 MS_23 MHN_2 MS_14 MHN_52 MHN_57 MS_15 MHN_60b MHN_49 MS_44 MHN_59MHN_10 MS_53 MHN_54 MHN_35 MS_25 MHN_47 MS_41 MS_56 MHN_91 MHN_68 MS_1 MHN_37 MHN_79a MHN_60 MHN_27MHN_28 Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:16 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_12_1_MC_Northeast_Drainage_Basins.mxd User: rcs2FIGURE 12.1 0 1,000 Feet !;N Northeast Minnehaha CreekDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NORTHEAST MINNEHAHA CREEKDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota 100 456717 456721 W 44th St W 39th St Wooddale Ave Country Club Rd Minnehaha C r e e kMinnehaha Creek North Morningside Edina Country Club MinneapolisMinneapolis Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:17 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_12_2_MC_Northeast_Major_Watersheds.mxd User: rcs2FIGURE 12.2 0 1,000 Feet !;N Northeast Minnehaha CreekDrainage Basin Major Watersheds Edina Country Club Minnehaha Creek North Morningside Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NORTHEAST MINNEHAHA CREEKMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota City of Edina 2018 Comprehensive Water Resources Management Plan 12-28 Reserved for: Figure 12.3 Northeast Minnehaha Creek Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. JP_40JP_26 MHN_1 MHN_66 MHN_11 ECC_6 ECC_5 ECC_9 ECC_4 ECC_3 ECC_2 JP_10 St.St. Louis ParkLouis Park MinneapolisMinneapolis Min nehahaC reek Barr Footer: ArcGIS 10.4.1, 2018-03-26 11:35 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_12_4_MC_Northeast_Water_Quality.mxd User: EMANORTHEAST MINNEHAHA CREEKWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 12.4 1,000 0 1,000Feet 300 0 300Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to Minnehaha Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 13-1 13.0 Southeast Minnehaha Creek 13.1 General Description of Drainage Area Figure 13.1 depicts the Southeast Minnehaha Creek drainage area and the individual subwatersheds within this area. The Southeast Minnehaha Creek drainage basin is located in east-central Edina and contains several ponds, Lake Harvey, Lake Pamela, and Melody Lake. 13.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ponding basins, wetlands, drainage ditches, and overland flow paths. The Southeast Minnehaha Creek basin has been divided into several major watersheds based on the drainage patterns. These major watersheds are depicted on Figure 13.2. Each major watershed has been further delineated into numerous subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located. Table 13.1 lists each major watershed and the associated subwatershed naming convention. Table 13.1 Major Watersheds within the Southeast Minnehaha Creek Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) Lake Pamela LP_## 28 279 Minnehaha Creek South MHS_## / MHC_## 90 589 Melody Lake ML_## 16 173 13.1.1.1 Lake Pamela The Lake Pamela watershed is located in the east central portion of Edina. The entire 279-acre watershed drains to Lake Pamela and then north to Minnehaha Creek. The land use in this watershed is primarily low-density residential, with Pamela Park surrounding Lake Pamela. Four stormwater management basins in this watershed, two on the south end of Lake Pamela and two on the north end, have recently been constructed to treat stormwater. The two ponds on the north end of the lake also receive runoff from about half of the Minnehaha Creek South watershed (described below). This runoff is routed through the ponds, over a weir, to the north bay of Lake Pamela, and finally, to Minnehaha Creek. These ponds were designed to treat runoff from the Minnehaha Creek South watershed before it is discharged to Minnehaha Creek. Lake Pamela has been excavated to increase the dead storage volume within the lake for water quality treatment. 13.1.1.2 Minnehaha Creek South The Minnehaha Creek South watershed extends from areas just south of the Edina Country Club at Lake Harvey, west to TH 100 and south to West 54th Street. The land use in this 589-acre watershed is predominantly low-density residential with some scattered areas of institutional land use. There are no ponds east of Minnehaha Creek and only a few wet and dry detention ponds in the western half of this City of Edina 2018 Comprehensive Water Resources Management Plan 13-2 watershed. However, stormwater from most of the western half of the watershed is routed through ponds and through the northern bay of Lake Pamela before discharging to Minnehaha Creek. Areas directly east and west of Minnehaha Creek are drained by short storm sewer systems or directly by overland flow. There is a stormwater control weir in a manhole just east of the intersection of West 58th Street and Concord Avenue. A pipe leading from the backyard area is part of this system and connects to the downstream end of the weir-manhole; a flap gate stops water from backing into the pipe. The weir, located at node 1849, forces water to back into a pipe that discharges to a ball field along Concord Avenue. This entire system was designed to store water in the ball park and slowly release it back into the storm sewer system to reduce flood elevations for the nearby principle structures during large storm events. 13.1.1.3 Melody Lake Land use in this 173-acre watershed is low-density residential, institutional, and TH 100. The outlet from Melody Lake is a pumped outlet to the TH 100 drainage system. This system flows north and ultimately discharges to Minnehaha Creek. The TH 100 storm sewer system was not modeled as part of this study. 13.2 Stormwater System Results 13.2.1 Hydrologic/Hydraulic Modeling Results The 10-percent-annual-chance and 1-percent-annual-chance flood analyses were performed for the Southeast Minnehaha Creek drainage basin. The 10-percent-annual-chance analysis was based on a ½ hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis. Table 13.2 presents the watershed information and the results for the 10- and 1-percent-annual-chance hydrologic analyses for the Southeast Minnehaha Creek basin. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analyses for the Southeast Minnehaha Creek drainage basin are summarized in Table 13.3. Figure 13.3 illustrates the results of the 10- and the 1-percent-annual-chance frequency hydraulic analyses. The figure depicts the Southeast Minnehaha Creek drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 13.3 illustrates that several XP-SWMM nodes within the Southeast Minnehaha Creek drainage basin are predicted to surcharge during both the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. City of Edina 2018 Comprehensive Water Resources Management Plan 13-3 To evaluate the level of protection of the stormwater system within the Southeast Minnehaha Creek drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 13.3. Discussion and recommended improvement considerations for these areas are included in Section 13.3. 13.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 13.4 depicts the results of the water quality modeling for the Southeast Minnehaha Creek drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 13.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 13.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Southeast Minnehaha Creek drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for problem areas. These preliminary corrective measures are also discussed below. As the City evaluates flooding issues and potential system modifications, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. City of Edina 2018 Comprehensive Water Resources Management Plan 13-4 The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Southeast Minnehaha Creek drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done since 2003. 13.3.1.1 East Golf Terrace Heights Neighborhood There are several low depression areas within the Golf Terrace Heights neighborhood, including (1) Tower Street between Fairfax Avenue and Wooddale Avenue and the backyard depressions of the homes along Tower Street (MHS_75, MHS_76, and MHS_86), (2) the backyard depression north of West 58th Street between Fairfax Avenue and Wooddale Avenue (MHS_16), and (3) the parking lot of Wooddale Church and the backyards of homes along West 56th Street (MHS_83). Along Tower Street there are 8 catch basin inlets with 24-inch pipe, and in the parking lot of Wooddale Church there are 3 catch basin inlets with 15- inch pipe—both leading to the 24-inch pipe under Wooddale Avenue. In the backyard depression of MHS_16, there are no inlets and, according to LiDAR data, the surface overflow is between 5712 and 5716 Wooddale Avenue at approximately 880.0 feet. Modeling results indicate that the 1-percent-annual-chance flood levels are 886.3 feet (MHS_83), 882.4 feet (MHS_75), 880.6 feet (MHS_86), 880.6 feet (MHS_76), and 880.0 feet (MHS_16). For all of these subwatersheds, except for MHS_16, the 24-hour precipitation event determines the 1-percent-annual- chance flood level. Based on LiDAR data and approximate building footprints, the 1-percent-annual- chance flood elevation in subwatershed MHS_83 may impact up to three principle structures (4516, 4520, and 4524 West 56th Street) in addition to inundating the Wooddale Church parking lot. The 1-percent- annual-chance flood elevation may impact up to nine principle structures in subwatersheds MHS_75, MHS_86, and MHS_76 (4519 West 56th Street, 4536–4516 Tower Street, and 4517 and 4513 Tower Street). Up to six principle structures in subwatershed MHS_16 may be impacted by the 1-percent-annual-chance flood elevation (5712–5720 Wooddale Avenue and 5709–5717 Fairfax Avenue). The flooding problem is primarily related to the capacity of the downstream storm sewer system that conveys stormwater east to Minnehaha Creek. The high flows passing through the single 48-inch pipe east to Minnehaha Creek result in high velocities, high friction head losses, and a higher surface water profile in this area. Several system modifications were evaluated to reduce flood elevations in the east portion of the Golf Terrace Heights neighborhood. The most effective improvement option is to increase the capacity of the storm sewer system between this area and Minnehaha Creek and install additional inlets to capture peak flows during large storm events. One drawback to this option is that it would convey more water downstream to areas with existing flooding issues. However, increasing the capacity of the storm sewer system is unlikely to affect the peak flood level of Minnehaha Creek due to very different timing of local flood levels and peak flows along the Minnehaha Creek system. Another option to provide additional discharge capacity from this area is connecting the existing storm sewer from West 56th Street and Wooddale Avenue to West 56th Street and Kellogg Avenue. Underground storage with sufficient inlet capacity under side streets such as West 56th Street, Tower Street, and West Woodland Road should also City of Edina 2018 Comprehensive Water Resources Management Plan 13-5 be considered to reduce flood risk. Planning-level soil maps show that the soils in this area are “B” soils with moderate potential for infiltration. 13.3.1.2 Concord and West 58th Street (MHS_59, MHS_26, MHS_58, MHS_42, MHS_53, and MHS_17) The intersection of Concord Avenue and West 58th Street and surrounding area has experienced flood problems historically. This low-lying area is drained by the existing storm sewer system. However, when stormwater flows exceed the capacity of the existing system, water will pool along the roadway and in adjacent yards until it rises high enough to flow eastward along West 58th Street toward Wooddale Avenue. In the early-1990s, a stormwater control weir was installed in a manhole just east of the intersection of West 58th Street and Concord Avenue to reduce the flood risk in this area. The control weir is designed to divert stormwater to the low area west of Concord Avenue (this area also serves as a ballfield) during large storm events, storing water and slowly releasing it back into the storm sewer system once the storm passes. Atlas 14 model results indicate that the intersection of Concord Avenue and West 58th Street is expected to be inundated during the 1-percent annual-chance 24-hour storm event, along with portions of West 58th Street east of Concord Avenue, and parts of Ashcroft Avenue and Fairfax Avenue. The 1-percent- annual-chance flood elevation (882.6 feet) may impact several principle structures between Concord Avenue and Wooddale Avenue, including 4 structures along Concord Avenue (addresses 5801-5817), 7 structures along Ashcroft Avenue (addresses 5800-5808, 5820, 5801-5809), 2 structures along St. Johns Avenue (addresses 5805-5809), 6 structures along Fairfax Avenue (5800, 5801, 5724, 5709-5717), and 5 structures along Wooddale Avenue (addresses 5800-5804, 5712-5720), based on LiDAR and approximate building footprint data. The flooding problem in this area is primarily related to the capacity of the existing storm sewer system, specifically in the portion that is between Wooddale Avenue and Minnehaha Creek. High flow velocity through the 48-inch pipe results in significant friction losses that limit outflow and back water up in the West 58th Street storm sewer system. Significant inflows are contributing to this one storm sewer line from Concord Avenue north and south of West 58th Street, from Wooddale Avenue north of West 58th Street, including the neighborhoods between West Woodland Road and Golf Terrace. Potential improvements to reduce the flood risk in this area include increasing flow capacity in the storm sewer system between Wooddale Avenue and Minnehaha Creek or creating additional paths for water to flow to the creek. Detailed modeling of proposed solutions was performed and the results are described below. Increased flow capacity: The impact of increasing the flow capacity of the storm sewer pipes under West 58th Street was evaluated. Tripling the flow capacity from West 58th Street all the way to Minnehaha Creek reduced the number of potentially impacted principle structures by half, from 24 to 12, with the most substantial improvements occurring in MHS_42, MHS_53, and MHS_14. Diverting storm flows: Several diversion scenarios were evaluated. Diverting runoff from MHS_53 (intersection of West 58th Street and Ashcroft Avenue) southward along Ashcroft Avenue City of Edina 2018 Comprehensive Water Resources Management Plan 13-6 to the existing storm sewer system at West 60th Street has similar benefits to the increased flow capacity improvement option described above with regards to the flood level and number of potentially impacted structures in the area of Concord Avenue and West 58th Street. Re-routing storm sewer from West 58th Street and Wooddale Avenue (MHS_65) south to Pamela Park also has similar benefits to the increased flow capacity improvement option described above with regards to the flood level and number of potentially impacted structures in the area of Concord Avenue and West 58th Street. Diverting runoff from MHS_61 (intersection of West 56th Street and Wooddale Avenue) eastward along West 56th Street to connect to the existing storm sewer at Kellogg Avenue, instead of routing it south along Wooddale Avenue, has marginal benefits to the flood level in the area of Concord Avenue and West 58th Street, but did not protect any principle structures. The potential improvement alternatives discussed above rely on sending water to Minnehaha Creek more quickly and using or creating available storage area in Pamela Park. Because the local event in these subwatersheds peaks much earlier than the regional flood event in Minnehaha Creek, timing may allow for additional water to be added to the creek and passed downstream before the regional peak comes through without creating additional impacts to the peak flood level or the number of potentially impacted structures along the creek. If an alternative is selected that diverts water to Pamela Park, additional available storage volume may be necessary because there are potentially impacted structures already adjacent to Pamela Park along West 62nd Street and along Halifax Avenue South. 13.3.2 Construction/Upgrade of Water Quality Basins When considered individually, the ponds MHS_13, LP_5, and LP_13, and the two bays of Lake Pamela (LP_14 and LP_26) are removing less that 60 percent of the total phosphorus in stormwater inflows. Because water from a watershed greater than 500 acres in size is routed through the ponds and the two bays of Lake Pamela before being discharged to Minnehaha Creek, the cumulative phosphorus removal by the ponds should be considered. In addition, ponds MHS_13, LP 5, and LP_13 were recently constructed and designed to function as a treatment train and not individually. On a cumulative basis, the ponds and Lake Pamela are removing 63 percent of the total phosphorus load from this entire watershed; as such, it is not necessary to upgrade these ponds. Because over 60 percent of the total phosphorus in stormwater runoff is being removed by all other ponds and wetlands in the Southeast Minnehaha Creek watershed, no recommendations are given for the construction or upgrade of water quality basins in this watershed. Many techniques are available to reduce pollutant loading from stormwater runoff, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and further improve the quality of stormwater runoff from this drainage area. City of Edina 2018 Comprehensive Water Resources Management Plan 13-7 13.3.3 Stream Improvement Projects 13.3.3.1 Minnehaha Creek Reach 14 Stream Restoration The MCWD’s 2007 Comprehensive Water Resources Management Plan identified a potential capital improvement project in Edina to implement a stream restoration project on Reach 14 of Minnehaha Creek. This reach extends from France Avenue to West 54th Street. This project, which incorporated streambank stabilization, in-stream habitat enhancement, and buffer enhancement, has been completed. Table 13.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Southeast Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) LP_1 6.5 25 35 2.8 1.2 3.9 14 1.3 LP_10 5.5 25 39 2.5 1.0 3.3 17 1.2 LP_11 11.7 25 81 5.2 2.2 7.0 35 2.5 LP_12 3.6 22 34 1.9 0.7 2.1 18 1.0 LP_13 12.4 25 100 5.6 2.4 7.4 47 2.7 LP_14 26.6 35 178 14.6 5.0 15.9 87 7.8 LP_15 3.8 25 23 1.7 0.7 2.3 10 0.8 LP_16 6.3 25 47 2.8 1.2 3.8 21 1.3 LP_17 16.3 25 114 7.2 3.1 9.8 51 3.4 LP_18 3.9 25 34 1.8 0.7 2.4 16 0.8 LP_19 13.7 25 96 6.1 2.6 8.2 42 2.9 LP_2 6.3 24 58 2.9 1.2 3.8 29 1.4 LP_20 15.6 25 109 6.9 3.0 9.4 48 3.3 LP_21 3.7 25 27 1.7 0.7 2.2 12 0.8 LP_22 9.1 25 70 4.0 1.7 5.4 32 1.9 LP_23 6.0 25 35 2.7 1.1 3.6 15 1.3 LP_24 3.0 25 27 1.5 0.6 1.8 14 0.8 LP_25 4.0 21 34 2.0 0.8 2.4 17 1.0 LP_26 41.3 39 254 22.3 7.8 24.8 121 11.8 LP_27 19.8 25 106 9.6 3.7 11.8 47 4.8 LP_28 1.0 25 6 0.5 0.2 0.6 2 0.2 LP_3 3.2 25 30 1.5 0.6 1.9 15 0.7 LP_4 2.2 25 22 1.0 0.4 1.3 11 0.5 LP_5 8.1 28 71 3.7 1.5 4.8 34 1.8 LP_6 23.0 25 104 10.0 4.3 13.8 43 4.7 LP_7 5.8 25 40 2.6 1.1 3.5 18 1.2 LP_8 9.4 25 74 4.2 1.8 5.6 34 2.0 LP_9 7.0 25 52 3.1 1.3 4.2 24 1.5 MHS_1 1.9 25 7 0.9 0.3 1.1 3 0.5 MHS_10 3.0 25 28 1.6 0.6 1.8 14 0.9 MHS_11 8.2 25 73 3.7 1.6 4.9 35 1.8 MHS_12 10.0 25 63 4.7 1.9 6.0 29 2.3 MHS_13 8.1 25 49 3.6 1.5 4.9 20 1.7 MHS_14 2.2 25 19 1.0 0.4 1.3 9 0.5 MHS_15 4.7 25 39 2.1 0.9 2.8 18 1.0 MHS_16 1.9 25 19 0.8 0.4 1.1 9 0.4 MHS_17 10.2 25 60 4.5 1.9 6.1 25 2.1 MHS_18 1.9 25 14 1.0 0.4 1.1 7 0.5 MHS_19 3.2 35 30 1.5 0.6 1.9 15 0.7 MHS_2 1.6 25 10 0.7 0.3 0.9 4 0.3 MHS_20a 4.0 25 36 1.8 0.8 2.4 17 0.8 MHS_20b 7.0 25 62 3.1 1.3 4.2 30 1.5 MHS_21a 1.5 25 16 0.7 0.3 0.9 8 0.3 MHS_21b 5.2 25 53 2.3 1.0 3.1 28 1.1 MHS_22 23.2 41 122 11.3 4.3 13.9 54 5.7 MHS_23 4.8 50 48 2.4 0.9 2.9 24 1.2 MHS_24 7.0 25 44 3.1 1.3 4.2 19 1.5 MHS_25 6.1 25 35 2.7 1.2 3.7 15 1.3 MHS_26 10.2 27 50 5.0 1.9 6.1 22 2.5 MHS_27 4.3 30 35 2.0 0.8 2.6 16 1.0 MHS_28 4.6 30 32 2.1 0.9 2.8 14 1.0 MHS_29 1.6 25 12 0.7 0.3 1.0 5 0.3 MHS_3 1.5 24 14 0.7 0.3 0.9 7 0.3 MHS_30 1.4 30 12 0.6 0.3 0.8 6 0.3 MHS_31 3.6 25 29 1.6 0.7 2.1 14 0.8 MHS_32 13.4 25 80 6.0 2.5 8.0 34 2.9 MHS_33 2.8 25 14 1.2 0.5 1.7 6 0.6 MHS_34 4.9 25 35 2.2 0.9 2.9 16 1.0 MHS_35 8.2 9 51 3.4 1.6 4.9 21 1.5 MHS_37 1.2 13 6 0.5 0.2 0.7 3 0.2 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 13.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Southeast Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event MHS_38 0.2 25 3 0.1 0.0 0.1 2 0.1 MHS_39 7.0 25 66 3.4 1.3 4.2 34 1.7 MHS_4 1.8 25 14 0.8 0.3 1.0 6 0.4 MHS_41 3.3 49 36 1.9 0.6 2.0 19 1.0 MHS_42 1.7 25 11 0.9 0.3 1.0 5 0.4 MHS_43 4.3 25 25 1.9 0.8 2.6 11 0.9 MHS_44 2.2 26 15 1.0 0.4 1.3 7 0.5 MHS_45 33.0 25 107 13.9 5.9 19.8 43 6.2 MHS_46 5.6 25 19 2.3 1.0 3.3 8 1.1 MHS_47 7.2 25 64 3.2 1.4 4.3 32 1.5 MHS_47B 3.3 25 31 1.5 0.6 2.0 16 0.7 MHS_48 20.2 26 74 8.7 3.7 12.1 30 4.0 MHS_49 1.8 24 17 0.8 0.3 1.1 9 0.4 MHS_5 6.5 29 59 3.0 1.2 3.9 29 1.4 MHS_50 21.6 25 112 9.5 4.0 12.9 47 4.5 MHS_52 13.3 25 50 5.7 2.4 8.0 20 2.6 MHS_53 13.9 25 66 6.2 2.6 8.4 27 2.9 MHS_55 1.4 25 11 0.7 0.3 0.9 5 0.3 MHS_56 6.0 25 30 2.6 1.1 3.6 13 1.2 MHS_57 24.6 26 127 10.9 4.6 14.8 53 5.1 MHS_57a 2.1 30 21 1.0 0.4 1.3 11 0.5 MHS_58 3.3 30 23 1.6 0.6 2.0 11 0.8 MHS_59 16.0 30 104 7.7 3.0 9.6 47 3.8 MHS_59a 0.6 30 5 0.3 0.1 0.4 3 0.1 MHS_6 2.5 27 21 1.1 0.5 1.5 10 0.5 MHS_60 3.8 25 40 1.7 0.7 2.3 21 0.8 MHS_61 9.4 26 36 4.1 1.7 5.6 15 1.9 MHS_62 10.0 25 34 4.2 1.8 6.0 14 1.9 MHS_63 12.2 31 57 5.5 2.3 7.3 24 2.6 MHS_64 6.7 24 51 3.0 1.3 4.0 24 1.5 MHS_65 5.8 25 44 2.6 1.1 3.5 20 1.2 MHS_66 2.5 25 18 1.2 0.5 1.5 8 0.6 MHS_67 4.4 24 36 2.0 0.8 2.7 17 1.0 MHS_68 4.9 25 44 2.2 0.9 2.9 22 1.1 MHS_69 3.4 25 39 1.5 0.6 2.0 21 0.7 MHS_7 6.5 26 32 2.9 1.2 3.9 13 1.4 MHS_70 1.8 24 13 0.8 0.3 1.1 6 0.4 MHS_71 6.1 25 18 2.5 1.1 3.6 7 1.1 MHS_72 3.4 27 29 1.6 0.6 2.0 14 0.8 MHS_73 2.5 25 22 1.2 0.5 1.5 11 0.6 MHS_74 1.4 25 16 0.7 0.3 0.9 8 0.4 MHS_75 2.0 25 14 0.9 0.4 1.2 6 0.4 MHS_76 2.5 25 22 1.1 0.5 1.5 10 0.5 MHS_77 3.1 25 17 1.3 0.6 1.8 7 0.6 MHS_79 2.1 25 16 1.1 0.4 1.3 8 0.5 MHS_8 5.7 25 59 2.8 1.1 3.4 31 1.4 MHS_80 3.9 25 33 1.7 0.7 2.3 15 0.8 MHS_81 4.8 12 25 2.4 0.9 2.9 11 1.2 MHS_82 2.0 25 13 0.9 0.4 1.2 6 0.5 MHS_83 4.3 27 34 2.0 0.8 2.6 16 1.0 MHS_84 2.4 25 13 1.1 0.5 1.5 5 0.5 MHS_86 2.1 25 14 0.9 0.4 1.3 6 0.4 MHS_87 2.6 25 20 1.1 0.5 1.5 9 0.5 MHS_88 1.8 25 18 0.8 0.3 1.1 9 0.4 MHS_89 0.5 25 5 0.2 0.1 0.3 3 0.1 MHS_9 3.1 25 24 1.5 0.6 1.9 12 0.8 ML_1 3.9 48 34 2.0 0.7 2.4 16 1.0 ML_10 4.0 27 40 1.8 0.8 2.4 20 0.9 ML_11 4.9 25 30 2.2 0.9 3.0 13 1.0 ML_12 9.5 25 55 4.2 1.8 5.7 23 2.0 Table 13.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Southeast Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event ML_13 42.6 47 146 20.3 7.4 25.5 62 10.0 ML_14 0.4 65 5 0.2 0.1 0.2 3 0.1 ML_15 1.6 30 16 0.7 0.3 1.0 8 0.4 ML_2 7.2 25 64 3.2 1.4 4.3 31 1.5 ML_3 28.2 25 204 12.6 5.3 16.9 91 6.0 ML_3B 8.2 24 81 3.7 1.6 4.9 42 1.8 ML_4 10.8 25 55 4.7 2.0 6.4 22 2.2 ML_5 5.8 25 44 2.6 1.1 3.5 20 1.2 ML_6 4.1 25 30 1.8 0.8 2.4 14 0.9 ML_8 27.8 46 260 13.8 5.3 16.7 129 7.0 ML_9 9.5 23 63 4.2 1.8 5.7 27 2.0 HL_51 3.0 24 23 1.3 0.6 1.8 10 0.6 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 102 920.1 919.9 103 913.8 913.7 104 910.7 910.5 109 897.4 897.4 110 896.2 896.2 112 899.8 899.5 113 896.2 894.3 118 910.9 910.9 1219 881.7 878.4 1754 872.6 865.8 1766 862.3 862.3 1767 855.2 ¹ 854.1 1769 874.9 874.9 1775 881.4 881.1 1776 879.6 879.6 1780 882.2 881.9 1784 870.7 870.4 1786 871.0 869.5 1791 864.0 863.2 1793 864.0 863.8 1794 862.9 862.7 1796 862.5 860.5 1808 894.4 894.2 1809 894.4 894.1 1810 894.1 893.8 1811 892.8 892.6 1812 892.0 891.9 1813 891.6 891.4 1814 889.9 889.7 1815 889.1 888.9 1820 891.0 890.0 1822 887.2 887.0 1823 887.3 886.6 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 1824 884.8 884.5 1826 888.0 887.1 1828 886.8 886.7 1830 881.5 880.5 1833 878.5 877.0 1834 878.4 876.4 1835 881.0 879.9 1836 880.7 877.7 1838 865.0 864.5 1839 862.3 860.1 1840 871.1 869.8 1844 882.6 879.0 1845 882.6 879.3 1846 882.6 879.5 1848 882.6 879.7 1849 882.5 879.9 1854 883.4 883.1 1856 883.0 882.5 1858 882.6 882.0 1859 882.6 880.9 1860 883.9 883.3 1861 884.1 883.8 1862 884.6 884.5 1865 890.6 887.8 1868 894.7 889.5 1993 862.4 860.3 1996 874.6 874.6 2000 862.3 860.1 2003 865.0 864.6 2007 876.4 876.4 2008 879.1 878.7 2009 881.6 880.9 2011 884.4 883.3 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2012 884.4 883.3 2111 866.6 866.3 2112 863.8 863.7 2114 863.6 862.9 2116 863.4 862.4 2118 863.2 861.8 2119 862.3 860.3 2123 862.3 860.1 2125 862.3 860.2 2127 862.3 861.0 2130 865.3 865.0 2131 865.6 865.2 2132 871.0 870.9 2134 867.0 866.8 2136 879.2 879.2 2240 868.1 861.6 2336 871.5 864.6 2338 880.0 879.3 2340 881.7 880.8 2342 882.1 882.1 2374 912.1 911.8 2375 911.1 910.9 2376 907.1 907.0 2425 890.1 889.7 2444 907.9 907.8 2501 901.0 900.9 2502 898.2 898.0 2503 895.7 895.1 2504 895.7 894.9 2512 896.4 896.2 2514 895.7 894.5 2515 895.7 894.5 2516 895.7 895.5 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2517 895.7 895.2 2525 884.4 883.3 2526 884.4 883.3 2527 884.4 883.3 2529 884.4 883.3 2530 884.4 883.3 2531 884.4 883.3 2532 884.4 883.3 2533 884.4 883.3 2534 884.4 883.3 2539 875.1 874.9 2540 875.1 874.9 2541 875.1 874.9 2542 879.1 878.7 2543 879.1 878.7 1769$I 872.9 871.5 1775$I 876.9 876.9 1776$I 874.6 874.6 1780$I 882.2 881.9 2342$I 876.3 876.3 F6561 895.3 894.0 FID1929 893.4 893.2 FID1930 893.1 892.8 FID1931 891.4 891.0 FID1960 883.1 883.1 FID1960$I 877.4 877.3 FID2122 909.4 909.4 FID2124 906.5 906.5 FID2132 881.7 881.4 FID2132$I 877.8 877.7 FID2134 895.0 890.4 FID2471 898.2 896.9 FID-2547 889.3 889.2 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 FID2578 913.8 913.6 FID3036 862.1 860.1 FID3037 862.1 860.1 FID325 909.8 909.6 FID326 910.6 909.7 FID396 913.3 913.0 FID4283 868.3 865.3 FID4284 868.3 865.3 FID4300 910.2 910.2 FID4473 907.5 907.5 FID4479 902.0 902.0 FID4481 895.6 895.6 FID4482 896.2 896.2 FID5255 876.7 876.7 FID5256 877.0 877.0 FID5642 895.4 892.1 FID5643 895.2 891.5 FID5644 895.0 891.6 FID6084 906.0 906.0 FID6440 896.2 896.2 FID6560 895.5 892.8 FID6562 895.5 892.1 FID6709 916.7 913.3 FID6710 913.0 911.9 FID6729 912.3 912.3 FID6730 912.0 912.0 FID6731 911.3 911.3 FID6735 915.4 915.4 FID6737 894.4 892.6 FID6738 897.2 897.0 FID6739 908.4 908.4 FID7018 904.8 903.8 FID7027 901.9 900.8 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 FID7031 900.7 899.5 FID7032 898.8 898.1 FID7038 897.1 892.5 FID7052 896.9 890.7 FID7054 909.9 909.2 FID7069 897.0 890.7 FID7073 897.0 891.0 FID7075 909.0 908.7 FID7076 906.5 906.4 FID7086 897.0 890.7 FID7088 908.1 907.9 FID7089 908.6 908.4 FID7094 897.1 896.2 FID7095 899.5 899.5 FID7100 909.0 909.0 FID7101 909.3 909.3 FID7102 909.6 909.6 FID7116 903.7 903.7 FID83 868.3 865.3 FIS7122 912.2 912.0 Forebay 862.3 860.1 HL_51 byd 928.9 ¹ 926.9 LP_1 882.4 882.2 LP_10 street 864.7 864.3 LP_11 street 875.1 874.9 LP_12 street 862.3 860.8 LP_13 street 884.4 883.3 LP_14 pond 855.0 862.3 7.3 860.1 5.1 LP_15 street 884.4 883.5 LP_16 street 879.2 879.0 LP_17 street 862.3 860.1 LP_18 street 865.3 865.1 LP_19 street 864.9 864.3 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 LP_2 street 862.3 860.1 LP_27 street 884.4 883.2 LP_20 street/yd 891.8 891.6 LP_21 byd 863.9 ¹ 861.3 LP_22 street 863.3 863.1 LP_23 street/byd 884.4 883.3 LP_24 byd 884.4 883.5 LP_25 pond 856.5 862.3 5.8 860.1 3.6 LP_26 pond 856.5 862.3 5.8 860.1 3.6 LP_28 byd 884.4 883.8 LP_3 street 863.2 861.8 LP_4 street 865.7 865.6 LP_5 street 881.2 880.9 LP_6 street 869.7 869.2 LP_7 street 864.1 863.8 LP_8 street 879.5 879.4 LP_9 street 864.7 864.3 MHS_1 868.4 865.9 MHS_10 street 862.5 861.1 MHS_11 street 862.8 862.3 MHS_12 street 864.0 863.3 MHS_13 street 873.0 872.3 MHS_14 byd 881.9 881.0 MHS_15 street/byd 877.9 875.9 MHS_16 byd 880.0 ¹ 878.8 MHS_17 street 882.6 881.3 MHS_17_ori 882.5 878.9 MHS_18 byd 892.1 891.8 MHS_19 pond 884.5 887.7 3.2 886.4 1.9 MHS_2 street 872.4 869.8 MHS_20a street 896.4 896.2 MHS_20b street 894.7 889.4 MHS_21a street 903.9 903.8 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 MHS_21b street 897.2 897.1 MHS_22 pond 893.5 895.7 2.2 894.5 1.0 MHS_23 street 887.8 887.7 MHS_24 street 894.3 894.1 MHS_25 depression 895.8 895.7 MHS_26 street/lot 882.6 880.5 MHS_27 byd 882.6 881.7 MHS_28 parking lot 902.0 901.4 MHS_29 byd 895.5 895.4 MHS_3 street 861.1 861.0 MHS_30 889.2 889.0 MHS_31 870.3 870.2 MHS_32 street 881.5 881.2 MHS_32$I 877.6 877.5 MHS_33 street 871.7 871.6 MHS_33$I 871.5 871.5 MHS_34 street 881.4 881.3 MHS_35 pond 894.0** 898.4 4.4 898.2 4.2 MHS_37 street 872.5 872.2 MHS_38 street 862.5 860.5 MHS_39 street 862.5 862.0 MHS_4 byd 875.7 875.3 MHS_41 pond 857.0 862.1 5.1 860.1 3.1 MHS_42 byd 882.6 879.8 MHS_43 street 895.2 895.0 MHS_44 street 884.8 884.5 MHS_45 street 872.6 872.4 MHS_46 street 878.6 878.2 MHS_47 street 880.7 880.3 MHS_47B 894.9 894.9 MHS_48 street 885.4 885.2 MHS_49 street 887.9 887.4 MHS_5 882.8 882.7 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 MHS_50 885.0 884.7 MHS_50$I 885.0 884.7 MHS_52 street 876.3 876.1 MHS_53 street 882.7 879.8 MHS_53_orf 882.7 879.7 MHS_55 street 874.6 874.4 MHS_55$I 873.3 872.6 MHS_56 street 877.2 876.4 MHS_56$I 875.2 875.2 MHS_57 street 883.6 883.2 MHS_57a street 898.9 898.9 MHS_58 ditch 882.6 882.0 MHS_59 byd 882.6 880.5 MHS_59a ball field 882.6 880.5 MHS_6 street 888.0 888.0 MHS_60 creek 859.8 859.8 MHS_61 street 884.6 884.4 MHS_62 street 882.1 882.0 MHS_63 858.0 857.7 MHS_64 creek 855.9 855.5 MHS_65 street 885.9 885.7 MHS_66 byd 894.1 892.7 MHS_67 street 867.4 867.2 MHS_68 street 896.1 895.9 MHS_69 street 875.5 873.3 MHS_7 street 868.1 867.8 MHS_70 street 888.5 888.4 MHS_71 street 892.8 892.6 MHS_72 street 875.7 875.3 MHS_73 street 877.3 874.1 MHS_74 byd 872.5 872.3 MHS_75 byd 882.4 881.9 MHS_76 byd 880.6 879.8 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 MHS_77 street 882.5 881.5 MHS_79 street 880.9 880.8 MHS_79$I 878.2 878.2 MHS_8 street/yd 862.5 860.5 MHS_80 street 893.9 893.7 MHS_81 pond 856.0 862.3 6.3 860.1 4.1 MHS_82 street 891.0 889.8 MHS_83 street 886.3 886.2 MHS_84 street 888.3 887.6 MHS_86 street/yd 880.6 880.3 MHS_87 880.2 879.7 MHS_88 byd 896.0 895.4 MHS_89 byd 883.4 883.4 MHS_9 street/yd 862.5 860.5 ML_1 street 895.3 894.9 ML_10 byd 915.4 914.4 ML_11 street 935.9 934.4 ML_12 street 936.2 935.5 ML_13 street 896.9 890.7 ML_14 street 911.3 910.9 ML_15 street 911.7 910.5 ML_2 street 906.3 906.1 ML_3 street 899.4 898.7 ML_3B street 918.9 918.8 ML_4 street 916.1 915.9 ML_5 904.9 904.9 ML_6 street 916.7 916.3 ML_8 pond 887.4 894.0 6.6 890.7 3.3 ML_8a 894.5 890.7 ML_9 street 916.4 916.3 N207 882.6 879.7 N30 880.5 877.8 SouthEastP 862.3 860.1 Table 13.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Southeast Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 To_NC_55 882.7 879.8 Weirnode 862.4 860.2 100 4567158 456717 456721 456731 France Ave Valleyview Rd Normandale Blvd W 53rd St W 60th St Mi n nehaha C r e e kNorthBranchNineMile Cre e kMinneapolisMinneapolis RichfieldRichfield LP_26 MHC_4 ML_13 MHC_5 ML_3 ML_8 LP_6 LP_14 MHS_45 LP_27 MHS_57 MHS_22 MHS_50 LP_17 LP_20 MHS_48 LP_19 MHS_59 LP_13 ML_4 LP_11 LP_8 ML_9 MHS_53 MHS_32 MHS_52 LP_5 MHS_63 LP_22 ML_12 LP_9 ML_2 MHS_26 MHS_17 LP_1 MHS_62 MHS_12 LP_2 ML_3B MHS_61 LP_7 ML_1 ML_5 MHS_11 LP_16 MHS_35 MHS_13 LP_23 MHS_7 MHS_5 LP_10 MHS_47 MHS_39MHS_24 MHS_64 MHS_8 ML_11 MHS_20b MHS_25 MHS_71 ML_6 MHS_56 MHS_65 MHS_46 LP_25 LP_18 LP_3 ML_10 LP_15 MHS_34 LP_21 MHS_68 MHS_15 LP_12 MHS_28 MHS_21b MHS_67 MHS_27 MHS_43 MHS_83 MHS_80 HL_51 MHS_60 MHS_9 MHS_31 LP_4 MHS_58 MHS_41 MHS_19 MHS_10 MHS_47B MHS_76 MHS_84 MHS_81 MHS_44 MHS_86 MHS_4 MHS_75 MHS_18 MHS_88 MHS_55 MHS_23 LP_24 MHS_20a MHS_72 MHS_69 MHS_77 MHS_6 MHS_33MHS_87 MHS_66 MHS_73 MHS_14 MHS_1 MHS_79 MHS_82 ML_15 MHS_57a MHS_16 MHS_70 MHS_49 MHS_2 MHS_3 MHS_42 MHS_29 MHS_74 LP_28 MHS_21a MHS_37 MHS_30 MHS_59a MHS_89ML_14 MHS_38 Melody Lake Lake Pamela Lake Harvey Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:17 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_13_1_MC_Southeast_Drainage_Basins.mxd User: rcs2FIGURE 13.1 0 1,000 Feet !;N Southeast Minnehaha CreekDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 SOUTHEAST MINNEHAHA CREEKDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota 100 4567158 456717 456721 456731 France Ave Valleyview Rd Normandale Blvd W 53rd St W 60th St Mi n nehaha C reekNineMi l eCre e k Minnehaha Creek South Lake Pamela Melody Lake MinneapolisMinneapolis RichfieldRichfield Melody Lake Lake Pamela Lake Harvey Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:18 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_13_2_MC_Southeast_Major_Watersheds.mxd User: rcs2FIGURE 13.2 0 1,000 Feet !;N Southeast Minnehaha CreekDrainage Basin Major Watershed Lake Pamela Melody Lake Minnehaha Creek South Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 SOUTHEAST MINNEHAHA CREEKMAJOR WATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota NorthBranch City of Edina 2018 Comprehensive Water Resources Management Plan 13-24 Figure 13.3 Southeast Minnehaha Creek Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. MHS_35 MHS_22 MHS_19 MHS_41 ML_8 LP_13LP_5 MHS_13 MHS_13 LP_14 LP_26 RichfieldRichfield MinneapolisMinneapolis Minnehaha Creek Barr Footer: ArcGIS 10.4.1, 2018-03-26 11:36 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_13_4_MC_Southeast_Water_Quality.mxd User: EMASOUTHEAST MINNEHAHA CREEKWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 13.4 1,000 0 1,000Feet 300 0 300Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to Minnehaha Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 14-1 14.0 Northwest Minnehaha Creek 14.1 General Description of Drainage Area Figure 14.1 depicts the Northwest Minnehaha Creek drainage basin and the individual subwatersheds within this area. The Northwest Minnehaha Creek drainage basin is located in the far northwest corner of Edina, east of the TH 169 North drainage area. This watershed is the smallest of the Minnehaha Creek watersheds and extends from TH 100 to areas west of the Interlachen Golf Course. 14.1.1 Drainage Patterns The stormwater system within this drainage area comprises storm sewers, ponding basins, wetlands, drainage ditches, and overland flow paths. The Northwest Minnehaha Creek basin has been divided into several major watersheds based on the drainage patterns. These major watersheds are depicted on Figure 14.2. Each major watershed has been further delineated into numerous subwatersheds. The naming convention for each subwatershed is based on the major watershed where it is located. Table 14.1 lists each major watershed and the associated subwatershed naming convention. Table 14.1 Major Watersheds within the Northwest Minnehaha Creek Drainage Basin Major Watershed Subwatershed Naming Convention Number of Subwatersheds Drainage Area (acres) TH 100 H100_## 32 150 Hopkins HO_## 25 94 Interlachen EI_## 38 360 14.1.1.1 TH 100 The land use in this 150-acre watershed is primarily commercial and most of the runoff drains to a trunk storm sewer system along TH 100 that flows north to Minnehaha Creek. The pipe system and ponds within the Grandview Square development were also incorporated in the hydraulic and water quality models. 14.1.1.2 Hopkins The Hopkins watershed is located just south of the City of Hopkins and west of the Interlachen Country Club. This is a small watershed and consists of 94 acres of total land area. All of the water in this watershed is routed north by a lift station to a Hopkins storm sewer system. The land use is primarily low- density residential with several ponds and wetlands. 14.1.1.3 Interlachen The 360-acre Interlachen watershed consists of the Interlachen Country Club and residential areas adjacent to the golf course. There are several ponds and wetlands that provide storage and treatment for City of Edina 2018 Comprehensive Water Resources Management Plan 14-2 runoff in this watershed, but few storm sewer pipes. Water conveyed by the storm sewer system drains north to Minnehaha Creek. Modeling of the culverts and storm sewer within the Interlachen Country Club is based on historical reference maps showing proposed pipes connecting the ponds. A survey of actual field conditions may be warranted in the future to improve the accuracy of model results within this watershed. 14.2 Stormwater System Results 14.2.1 Hydrologic/Hydraulic Modeling Results The 10- and 1-percent-annual-chance flood analyses were performed for the Northwest Minnehaha Creek drainage basin. For the Northwest Minnehaha Creek watersheds, the storm sewers were evaluated using 10- and 1-percent-annual-chance storm events. The 10-percent-annual-chance analysis was based on a ½-hour storm with 1.65 inches of rain. The 1-percent-annual-chance analysis was based on a 24-hour storm event with 7.47 inches of rain and on a 10-day snowmelt event with 7.2 inches of runoff; the higher resulting flood level of the two events was chosen for the 1-percent-annual-chance analysis. The storm sewers in Table 14.2 present the watershed information and the results for the 10- and 1-percent-annual- chance hydrologic analyses for the Northwest Minnehaha Creek basin. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. The results of the 10- and 1-percent-annual-chance hydraulic analysis for the Northwest Minnehaha Creek drainage basin are summarized in Table 14.3. Figure 14.3 illustrates the results of the 10- and the 1-percent-annual-chance hydraulic analyses. The figure depicts the Northwest Minnehaha Creek drainage basin boundary, subwatershed boundaries, the modeled storm sewer network, surcharge conditions for the XP-SWMM nodes (typically manholes), and the flood-prone areas identified in the modeling analyses. Figure 14.3 illustrates that several XP-SWMM nodes within the Northwest Minnehaha Creek drainage basin are predicted to surcharge during both the 10- and 1-percent-annual-chance events. This means that in any year there is a greater than 10 percent probability that the system will be overburdened and unable to meet the desired level of service at these locations. These manholes and catch basins are more likely to become inundated during the smaller, more frequent storm events of various durations. To evaluate the level of protection of the stormwater system within the Northwest Minnehaha Creek drainage area, the 1-percent-annual-chance flood elevations for the ponding basins and depressed areas were compared to the low elevations of structures surrounding each basin. The areas predicted to potentially flood and threaten structures during the 1-percent-annual-chance storm event are shown on Figure 14.3. Discussion and recommended improvement considerations for these areas are included in Section 14.3. City of Edina 2018 Comprehensive Water Resources Management Plan 14-3 14.2.2 Water Quality Modeling Results The effectiveness of the stormwater system in removing stormwater pollutants such as phosphorus was analyzed using the P8 water quality model. The P8 model simulates the hydrology and phosphorus loads introduced from each pond’s watershed and the transport of phosphorus throughout the stormwater system. A more detailed description of the stormwater system analysis is provided in Section 4.1.3. Figure 14.4 depicts the results of the water quality modeling for the Northwest Minnehaha Creek drainage basin. The figure shows the fraction of total phosphorus removal for each water body as well as the cumulative total phosphorus removal in the watershed. 14.3 Implementation Considerations The 2017 XP-SWMM hydrologic and hydraulic modeling analyses and 2003 P8 water quality analysis helped identify locations throughout the watershed where improvements to the City’s stormwater management system may be warranted. The following sections discuss potential improvement options identified as part of the modeling analyses. As opportunities to address identified flooding issues and improve water quality arise (e.g., street reconstruction projects or public facilities improvements), the City will use a comprehensive approach to stormwater management. This approach will include consideration of infiltration or volume retention practices to address flooding and/or improve water quality, reduction of impervious surfaces, increased storm sewer capacity where necessary to alleviate flooding, construction and/or expansion of water quality basins, and implementation of other stormwater BMPs to reduce pollutant loading to downstream waterbodies. 14.3.1 Flood Protection Projects The 2017 hydrologic and hydraulic modeling analyses identified several locations within the Northwest Minnehaha Creek drainage basin where the 1-percent-annual-chance level of protection is not provided by the current stormwater system. The problem areas identified in 2017 are discussed below. As part of the 2017 modeling analyses, potential corrective measures were identified for problem areas. These preliminary corrective measures are also discussed below. As the City evaluates flooding issues and potential system modifications in these areas, other potential modifications, including (but not limited to) implementation of volume-retention practices, increases in conveyance capacity, and/or stormwater infiltration (where soils are conducive) will be given consideration. The 2003 hydrologic and hydraulic modeling analyses also identified several locations within the Northwest Minnehaha Creek drainage basin where the 1-percent-annual-chance level of protection was not provided by the stormwater system, based on TP-40 precipitation frequency estimates. The discussions related to those areas have been carried over to Appendix C of this plan, along with a short summary of what has been done since 2003. City of Edina 2018 Comprehensive Water Resources Management Plan 14-4 14.3.1.1 Blake Road South and Spruce Road (HO_4) At the southeast corner of Blake Road South and Spruce Road, there is a local depression in the backyard area with one inlet draining to a 21-inch pipe and a surface overflow at approximately 922.5 feet. The 21-inch pipe draining this area connects to the storm sewer on Spruce Road that eventually discharges to a wet pond south of Belmore Lane (HO_8) and just west of the Interlachen golf course. The 1-percent- annual-chance flood elevation of HO_4 (921.9 feet) may impact five principle structures (300–308 John Street and 301 and 309 Blake Road South), based on LiDAR and approximate building footprint information. Further downstream, an 18-inch pipe drains HO_8 to another pond (HO_19) which significantly restricts the outflow from HO_8 and raises the water level in HO_8. This creates a tailwater effect on the pipes between HO_4 and HO_8 and limits the outflow from HO_4. The most likely option to reduce flooding impacts in the backyard depression area is to increase the downstream pipe capacity. This may also require upsizing the existing lift station in HO_19 (currently about 500 gpm capacity). There are multiple options to achieve this goal: (1) increase the size of the pipe connecting the two wet ponds (HO_8 and HO_19), (2) add an additional outlet pipe from the wet pond to the Interlachen Golf Course where storage is available and no structures can be impacted, or (3) install a new pipe connecting the existing storm sewer under Spruce Road to the Interlachen Golf Course. Additional storage could also be created around several small depressions within the golf course. The feasibility of conveying additional water to the golf course and/or adding storage volume in the golf course may be low because it is private property. 14.3.2 Construction/Upgrade of Water Quality Basins Several ponds in this watershed are removing less than 60 percent of the average annual phosphorus load from stormwater inflows. The light blue ponds on Figure 14.4 are achieving less than 60 percent total phosphorus removal; however, the cumulative phosphorus removal was greater than 60 percent for all the subwatersheds. Additional analysis was performed to identify which ponds were functioning properly and which were functioning poorly. In the P8 model, phosphorus particles are grouped into several fractions. The unsettleable (dissolved) fraction is called P0. From the mass balance output of the P8 model, the percent of total phosphorus removal for the other settleable phosphorus fractions was evaluated for the apparently “non-performing” ponds to determine if the ponds were removing greater than 60 percent of the settleable phosphorus fractions. From this analysis it was determined that these ponds were removing greater than 60 percent of the settleable phosphorus and performing adequately. As a result, no ponds in this watershed require upgrades. Many techniques are available to reduce pollutant loading from stormwater runoff, including impervious surface reduction or disconnection, implementation of infiltration or volume-retention BMPs, installation of underground stormwater treatment structures and sump manholes, and other good housekeeping practices such as street sweeping. As opportunities arise, the City will consider all of these options to reduce the volume and further improve the quality of stormwater runoff from this drainage area. Table 14.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Northwest Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) EI_1 10.2 45 92 5.3 1.9 6.1 47 2.8 EI_10 12.7 44 105 6.2 2.4 7.6 50 3.1 EI_11 1.5 25 11 0.7 0.3 0.9 5 0.3 EI_12 5.1 34 49 2.4 1.0 3.1 25 1.2 EI_13 8.1 30 79 3.7 1.5 4.9 40 1.8 EI_14 11.1 25 65 4.9 2.1 6.7 27 2.3 EI_15 13.3 37 120 6.3 2.5 8.0 59 3.1 EI_16 15.9 26 85 7.0 3.0 9.5 35 3.3 EI_17 3.0 30 27 1.4 0.6 1.8 13 0.7 EI_18 10.5 25 80 4.7 2.0 6.3 36 2.2 EI_19 16.2 55 139 8.8 3.1 9.7 70 4.7 EI_2 17.0 25 138 8.8 3.2 10.2 69 4.5 EI_20 23.5 25 151 10.7 4.4 14.1 67 5.2 EI_21 4.3 38 41 2.2 0.8 2.6 21 1.2 EI_22 3.2 25 26 1.5 0.6 1.9 12 0.7 EI_23 3.7 25 27 1.7 0.7 2.2 12 0.8 EI_24 22.6 31 185 10.7 4.3 13.6 89 5.3 EI_25 7.8 17 72 4.1 1.5 4.7 38 2.1 EI_25a 2.9 6 25 1.0 0.5 1.7 10 0.4 EI_26 5.2 18 39 2.4 1.0 3.1 19 1.1 EI_27 2.7 5 17 1.4 0.5 1.6 8 0.7 EI_28 5.9 10 36 3.1 1.1 3.5 18 1.7 EI_29 9.8 11 67 5.3 1.9 5.9 33 2.8 EI_3 20.6 22 79 10.5 3.7 12.4 35 5.4 EI_30 3.6 5 28 2.0 0.7 2.2 14 1.0 EI_31 6.0 23 52 3.3 1.1 3.6 27 1.8 EI_32 11.9 19 62 6.0 2.2 7.1 28 3.0 EI_33 8.3 2 41 4.1 1.6 5.0 19 2.0 EI_34 15.7 11 64 7.5 2.9 9.4 27 3.6 EI_35 25.2 25 149 11.4 4.8 15.1 64 5.5 EI_36 2.9 25 26 1.3 0.5 1.7 13 0.6 EI_37 1.5 25 14 0.7 0.3 0.9 7 0.3 EI_4 14.6 25 115 6.7 2.8 8.8 54 3.3 EI_5 7.3 25 68 3.3 1.4 4.4 34 1.6 EI_6 1.9 25 16 0.8 0.4 1.1 7 0.3 EI_7 7.8 25 52 3.5 1.5 4.7 23 1.6 EI_8 18.6 25 121 8.2 3.5 11.1 53 3.9 EI_9 3.9 25 30 1.7 0.7 2.3 14 0.8 HO_1 4.7 25 34 2.1 0.9 2.8 15 1.0 HO_10 1.6 25 11 0.7 0.3 0.9 5 0.3 HO_11 1.8 25 16 0.8 0.3 1.1 8 0.4 HO_12 2.0 25 16 0.9 0.4 1.2 7 0.4 HO_13 1.3 25 13 0.6 0.2 0.8 6 0.3 HO_14 2.2 25 17 1.0 0.4 1.3 8 0.5 HO_15 3.3 25 31 1.5 0.6 2.0 15 0.7 HO_15a 1.4 25 15 0.6 0.3 0.8 8 0.3 HO_16 2.7 46 28 1.3 0.5 1.6 15 0.7 HO_17 15.4 25 92 6.8 2.9 9.2 39 3.2 HO_18 2.0 25 14 0.9 0.4 1.2 6 0.4 HO_19 13.0 25 95 5.8 2.5 7.8 43 2.8 HO_2 1.1 21 10 0.5 0.2 0.6 5 0.2 HO_20 0.8 25 9 0.3 0.1 0.5 5 0.2 HO_20a 0.6 25 7 0.3 0.1 0.3 4 0.1 HO_21 0.7 25 8 0.3 0.1 0.4 4 0.2 HO_22 3.7 25 30 1.7 0.7 2.2 14 0.8 HO_3 6.5 25 29 2.8 1.2 3.9 12 1.3 HO_4 2.6 25 22 1.1 0.5 1.5 11 0.5 HO_5 8.2 25 55 3.7 1.6 4.9 24 1.7 HO_6 4.9 25 41 2.2 0.9 3.0 19 1.1 HO_7 1.5 25 13 0.7 0.3 0.9 6 0.3 Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event Table 14.2 Watershed Modeling Results for Subwatersheds in the Minnehaha Northwest Drainage Area 1 The 1%-Annual-Chance (100-Year) 10-day snowmelt event is defined as 7.2 inches of runoff Watershed ID Total Area (ac) % Impervious Area Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Peak Runoff Rate (cfs) Total Volume Runoff (ac-ft) Watershed Information 1%-Annual-Chance (100-Year)1%-Annual-Chance (100-Year)10%-Annual-Chance (10-Year) 24-Hour Precipitation Event 10-day Snowmelt Event1 24-Hour Precipitation Event HO_8 8.0 37 80 3.8 1.5 4.8 41 1.9 HO_8_19 0.8 3 8 0.3 0.1 0.5 4 0.1 HO_9 3.5 27 17 1.5 0.7 2.1 7 0.7 H100_1 9.2 25 56 4.1 1.7 5.5 24 1.9 H100_10 5.2 30 33 2.4 1.0 3.1 14 1.1 H100_11 0.5 25 4 0.2 0.1 0.3 2 0.1 H100_12 2.4 25 17 1.1 0.5 1.4 7 0.5 H100_13 2.6 50 31 1.4 0.5 1.6 17 0.7 H100_13a 0.8 64 9 0.4 0.1 0.5 5 0.2 H100_13b 1.1 42 12 0.5 0.2 0.6 7 0.3 H100_13c 0.2 65 2 0.1 0.0 0.1 1 0.1 H100_13d 0.6 42 7 0.3 0.1 0.3 4 0.2 H100_14 4.1 70 40 2.3 0.8 2.5 21 1.2 H100_15 5.9 72 66 3.3 1.1 3.6 36 1.8 H100_15a 0.8 77 10 0.5 0.2 0.5 5 0.3 H100_16 12.0 63 125 6.4 2.3 7.2 66 3.4 H100_17 1.8 67 21 0.9 0.3 1.0 11 0.5 H100_18 5.5 66 62 3.0 1.0 3.3 33 1.6 H100_19 10.8 48 107 5.5 2.1 6.5 55 2.9 H100_2 3.6 34 24 1.7 0.7 2.2 10 0.8 H100_20 2.9 65 34 1.6 0.6 1.8 18 0.9 H100_21 0.4 28 5 0.2 0.1 0.2 3 0.1 H100_22 4.0 60 47 2.1 0.8 2.4 26 1.1 H100_23 1.2 56 14 0.6 0.2 0.7 8 0.3 H100_24 5.1 74 57 2.8 1.0 3.1 31 1.5 H100_25 1.0 37 11 0.5 0.2 0.6 6 0.2 H100_26 0.5 25 5 0.2 0.1 0.3 3 0.1 H100_27 0.5 25 6 0.2 0.1 0.3 3 0.1 H100_3 12.4 48 69 6.1 2.3 7.4 31 3.1 H100_4 10.8 65 96 5.8 2.0 6.5 48 3.1 H100_5 14.1 75 83 7.9 2.6 8.5 40 4.3 H100_6 4.2 28 36 1.9 0.8 2.5 17 0.9 H100_7 21.3 34 143 10.9 4.0 12.8 68 5.6 H100_8 0.6 25 6 0.3 0.1 0.4 3 0.1 H100_9 4.5 25 29 2.0 0.9 2.7 12 0.9 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1885 914.4 914.0 1886 914.3 913.8 1889 950.9 949.5 1891 950.4 948.4 1892 949.4 947.7 1893 948.8 947.3 1894 947.6 946.5 1895 947.0 946.1 1896 946.4 945.7 1897 945.3 944.9 1898 943.6 943.3 1906 924.4 923.8 1907 917.8 917.4 1908 906.5 905.7 1911 905.9 905.4 1912 898.0 897.4 1913 894.3 893.3 2156 900.9 900.5 2159 929.5 929.1 2160 930.0 929.7 2161 931.1 930.9 2162 931.2 931.0 2163 942.9 942.8 2173 919.0 918.7 2175 918.2 916.3 2177 892.7 892.2 2183 922.7 919.5 2186 921.9 916.4 2187 919.8 916.2 2188 918.9 916.1 2189 917.3 915.8 2191 916.9 915.8 2200 921.9 921.7 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 2203 925.2 923.5 2204 925.2 923.5 2210 925.2 923.5 2214 931.3 931.3 2215 930.0 929.9 2217 925.2 924.7 2218 925.2 924.7 2268 910.8 909.5 2271 912.2 912.1 2344 892.5 892.0 2346 891.8 891.5 2347 891.8 891.5 2348 890.6 890.4 2349 890.4 890.1 2350 890.3 889.9 2351 890.3 ¹ 889.6 2352 890.3 ¹ 889.4 2353 890.3 ¹ 889.3 2356 893.9 892.9 2357 893.9 892.9 2358 893.9 892.9 2364 927.5 927.4 2365 924.1 923.9 2366 920.8 920.5 2367 920.4 920.2 2368 919.5 918.8 2370 919.5 918.1 2372 919.2 917.7 2421 900.6 900.0 2442 923.4 921.9 2443 923.1 920.9 2456 897.4 897.2 2457 895.7 895.6 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 EI_1 pond 887.2 892.4 5.3 891.2 4.1 EI_10 pond 887.9** 890.5 2.6 889.9 2.0 EI_11 cul-de-sac 922.6 917.4 EI_12 pond 912.1** 916.4 4.3 914.5 2.4 EI_13 pond 896.0** 903.0 ¹ 7.0 900.3 4.3 EI_14 street 891.5 889.8 EI_15 street 908.7 908.5 EI_16 902.6 902.1 EI_17 937.0 928.4 EI_18 street 891.7 890.9 EI_19 pond 879.5** 890.3 ¹ 10.8 889.2 9.7 EI_2 street 895.7 895.5 EI_20 field 890.3 ¹ 889.2 EI_21 pond 884.6 890.3 ¹ 5.7 889.2 4.6 EI_22 street 890.2 ¹ 889.2 EI_23 street 892.9 892.7 EI_24 pond 883.5** 890.3 ¹ 6.8 889.2 5.7 EI_25 pond 889.0 893.9 4.9 892.9 3.9 EI_25a byd 893.9 892.9 EI_26 pond 905.8** 910.4 4.6 910.3 4.5 EI_27 pond 901.8** 905.2 3.4 905.0 3.2 EI_28 byd 897.3 896.9 EI_29 pond 898.1 902.1 4.0 901.5 3.4 EI_3 street 893.9 892.9 EI_30 depression 906.1 904.9 EI_31 pond 896.3 898.7 2.4 898.4 2.1 EI_32 pond 906.6 907.1 0.5 906.8 0.2 EI_33 byd 903.9 903.2 EI_34 pond 887.1** 893.9 6.8 892.9 5.8 EI_35 byd 897.3 897.0 EI_36 byd 952.4 952.3 EI_37 byd 948.8 947.0 EI_4 street 892.7 892.5 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 EI_5 street/yd 892.5 892.0 EI_6 street 892.7 892.5 EI_7 street 946.1 945.9 EI_8 street 929.2 928.8 EI_9 921.3 920.7 FID-6920 910.4 909.4 FID2551 915.6 914.8 FID2933 906.9 904.6 FID2934 906.9 904.6 FID2950 906.9 904.6 FID320 918.5 917.5 FID322 912.4 912.1 FID4130 908.2 908.0 FID4404 890.3 889.3 FID5827 925.2 924.5 FID5828 924.6 924.2 FID5864 925.5 924.9 FID6889 907.5 907.2 FID6890 907.7 907.4 FID6892 905.9 902.3 FID6899 906.3 903.1 FID6921 906.7 904.1 FID6926 906.6 904.2 FID6927 909.4 908.2 FID6932 906.6 904.3 FID6940 907.1 904.6 FID6950 908.0 905.7 FID6963 907.1 905.0 FID6969 907.1 905.1 FID6970 907.1 905.1 FID6971 907.1 905.1 FID6979 907.1 905.8 FID6988 910.5 908.5 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 FID6989 907.1 905.4 FID6990 907.1 905.3 FID6992 904.9 904.6 FID7001 908.4 906.5 FID7002 910.6 910.6 FID7005 915.1 914.3 FID7006 909.7 907.4 FID7008 909.8 908.1 FID7011 911.3 908.8 FID7062 912.6 908.8 FID7063 908.0 906.7 H100_1 hwy ditch 950.8 950.6 H100_10 910.9 910.7 H100_11 street 920.9 920.2 H100_12 street 918.5 918.0 H100_13 street 908.0 905.7 H100_13a basin 911.8 910.7 H100_13b street 908.8 908.5 H100_13c 909.6 909.3 H100_13d street 911.4 909.5 H100_14 pond 917.0 919.5 2.5 918.4 1.4 H100_15 street 912.2 910.7 H100_15a 926.2 923.6 H100_16 hwy ditch 905.2 900.9 H100_17 basin 910.4 909.6 H100_18 hwy ditch 906.6 903.7 H100_19 basin/lot 907.0 904.7 H100_2 ditch 951.1 949.9 H100_20 hwy ditch 907.1 905.0 H100_21 907.7 906.3 H100_22 hwy ditch 907.1 905.1 H100_23 hwy ditch 910.9 908.1 H100_24 934.4 934.3 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 H100_25 903.8 903.7 H100_26 915.0 914.9 H100_27 916.6 914.1 H100_3 938.4 938.2 H100_4 pond 928.8 929.3 0.5 929.0 0.2 H100_5 street 914.4 914.0 H100_6 street 915.9 913.7 H100_7 street 908.0 905.7 H100_8 street 919.5 918.2 H100_9 street/byd 913.9 913.7 HO_1 byd 918.4 918.1 HO_10 byd 923.8 923.4 HO_11 street 925.2 923.5 HO_12 street 922.9 922.7 HO_13 921.7 921.6 HO_14 byd 927.8 927.6 HO_15 street 920.0 919.8 HO_15a byd 918.3 918.0 HO_16 pond 917.5 925.2 7.7 923.5 6.0 HO_17 street 925.2 924.2 HO_18 street/yd 925.2 924.1 HO_19 pond 910.6 915.4 4.8 915.0 4.4 HO_2 byd 919.4 917.1 HO_20 street 931.9 931.8 HO_20a street 929.4 929.1 HO_21 byd 945.1 945.0 HO_22 byd 927.0 926.8 HO_3 street 918.0 915.9 HO_4 byd 921.9 916.5 HO_5 street/yd 916.5 915.7 HO_6 street 921.9 921.7 HO_7 street 925.2 923.5 HO_8 pond 912.0 916.5 4.5 915.7 3.7 Table 14.3 Hydraulic Modeling Results for XP-SWMM Subwatersheds/Nodes in the Northwest Minnehaha Creek Drainage Basin Flood Elevation (ft) Flood Bounce (ft) Flood Elevation (ft) Flood Bounce (ft) 1%-Annual-Chance (100-Year) Storm Event Results 10%-Annual-Chance (10-Year) Storm Event Results 24-Hour Precipitation Event 24-Hour Precipitation EventSubwatershed or Node3 Type of Storage2 Outlet Elevation (ft)4 HO_8_19 field 916.4 915.3 HO_9 street 933.9 932.9 N64 919.7 919.7 Node81 892.4 891.3 Node82 892.5 891.8 Node83 street 892.5 891.9 Node84 892.5 891.9 Node85 892.5 892.0 100 4567158 Interlachen Blvd Eden Ave EI_1 EI_2 EI_4 EI_5 EI_6 EI_7 EI_9 EI_10 EI_11 EI_12 EI_14 EI_15 EI_16 EI_17 EI_18EI_20 EI_23EI_24 EI_22EI_21 EI_13 EI_19 EI_26 EI_27 EI_33 EI_29 EI_3 EI_25EI_34 EI_28 EI_35 EI_8 EI_36 EI_37 H100_1 H100_2 H100_3 H100_6 H100_4 H100_14 H100_5 H100_15 HO_5 HO_9 HO_2 HO_19 HO_12HO_10 HO_4 HO_16 HO_17 HO_7 HO_18HO_21 HO_22 HO_1 HO_6 HO_15 HO_8HO_14 HO_13 HO_20 HO_3 HO_11 EI_25a H100_15a EI_32 HO_20a EI_30 EI_31 HO_8_19 HO_15a H100_8 H100_12 H100_9 H100_10 H100_13 H100_13b H100_18 H100_13a H100_24 H100_13c H100_19 H100_27 H100_26 H100_25 H100_17 H100_16 H100_23 H100_22 H100_20 H100_7 H100_13d H100_21 North Branch Nine Mile Creek Saint LouisSaint Louis ParkPark Saint LouisSaint Louis ParkParkHopkinsHopkins M innehahaCreek Barr Footer: ArcGIS 10.4.1, 2017-09-14 15:19 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_14_1_MC_Northwest_Drainage_Basins.mxd User: EMAFIGURE 14.1 0 1,000 Feet !;N Northwest Minnehaha CreekDrainage Basin Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NORTHWEST MINNEHAHA CREEKDRAINAGE BASINComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota North Branch Nine Mile Creek Saint LouisSaint Louis ParkPark Saint LouisSaint Louis ParkParkHopkinsHopkins M innehahaCreek Hopkins Interlachen TH 100 Barr Footer: ArcGIS 10.4.1, 2017-09-21 12:27 File: \\barr.com\gis\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_14_2_MC_Northwest_Major Subwatersheds.mxd User: rcs2FIGURE 14.2 0 1,000 Feet !;N Northwest Minnehaha CreekDrainage Basin Major Watershed Hopkins Interlachen T.H. 100 Subwatershed Streets and Highways Creek/Stream City of Edina Boundary Lake/Wetland Imagery Source: MnGeo; 2016 NORTHWEST MINNEHAHA CREEKMAJOR SUBWATERSHEDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota City of Edina 2018 Comprehensive Water Resources Management Plan 14-16 Reserved for: Figure 14.3 Northwest Minnehaha Creek Hydraulic Model Results This is a large drawing (34x44). Due to the paper and size and file size, this figure is included as a stand-alone PDF. HO_16 HO_8 HO_19 EI_32 EI_29 EI_31 EI_30 EI_27 EI_26 EI_25 EI_25 EI_1 EI_13 EI_19 EI_24 EI_21 EI_10 EI_12 EI_6 EI_20 H100_4 H100_14 HopkinsHopkins St. LouisSt. Louis ParkPark Minn ehahaCre e k Barr Footer: ArcGIS 10.4.1, 2018-03-26 11:36 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_14_4_MC_Northwest_Water_Quality.mxd User: EMANORTHWEST MINNEHAHA CREEKWATER QUALITY MODELING RESULTSComprehensive Water ResourceManagement PlanCity of Edina, Minnesota FIGURE 14.4 1,000 0 1,000Feet 300 0 300Meters Percent TP Removal in Water Body*This number represents the percent of the total annual massof phosphorus entering the water body that is removed. Cumulative TP Removal in Watershed*This number represents the percent of the total annual massof phosphorus entering the watershed and upstream watershedsthat is removed in the pond and all upstream ponds. *Data based on results of 2003 P8 modeling. 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) 0 - 25% (Poor/No Treatment) 25 - 40% (Moderate Removal) 40 - 60% (Good Removal) 60 - 100% (Excellent Removal) Imagery Source: USDA 2016 NAIP via MnGeo Area Draining Directly to Minnehaha Creek Flow Direction City of Edina 2018 Comprehensive Water Resources Management Plan 15-1 15.0 Issues and Implementation Program The City of Edina provides three core services through its water resources program; runoff management, flood control, and clean water services. The provision of these services takes place using two primary strategies, the lifecycle delivery of physical infrastructure, and programmatic activities. The City also provides a variety of additional water resource services that support the core services, protect natural resources, and improve recreational opportunities, including lake and pond management, and wetland and natural resource protection. The provision of these services is provided primarily with programmatic activities. This chapter describes the programs and activities that support each of the three core services and some of the policy issues around the provision and growth of service. This chapter also discusses resources, financial considerations, and implementation priorities. Table 15.1 summarizes details of the City’s implementation program activities, including a project description, cost estimate, potential funding sources, and proposed years of implementation. Table 15.2 summarizes the potential implementation activities to be undertaken in the next ten years, including capital improvements. Funding for capital improvements comes primarily from the City’s Stormwater Utility, as described in Section 15.4.5 Financial Considerations. At the time of this plan’s writing, the priority area for the Flood Risk Reduction Strategy is the Morningside neighborhood in the Minnehaha Creek Watershed District and the priority area for the Clean Water Strategy is Lake Cornelia in the Nine Mile Creek Watershed District. Programmatic activities and capital improvements will be evaluated in conjunction with strategy development. The City’s Capital Improvement Program will set forth, by year, details including schedule, estimated cost, and funding source. The Capital Improvement Program is described further in Section 15.4.3 Prioritization. 15.1 Flood Protection and Runoff Management Flooding is a concern for the city and its residents due to the threat to public safety and potential for significant property damages and economic losses. Flooding can cause other damages that are harder to quantify, including the following: • Flooding of roads so they are impassable to emergency vehicles and residents • Reduced redevelopment potential • Shoreline erosion • Increased pollutants in stormwater discharges • Destruction of riparian habitats and vegetation such as grass, shrubs, trees, etc. City of Edina 2018 Comprehensive Water Resources Management Plan 15-2 • Unavailability of recreational facilities for use by the public (e.g., inundation of shoreline) and/or restricted recreational use of waterbodies • Increased demand for emergency services and risk to emergency responders during flood events • More strain on budgets and personnel for repairing flood-damaged facilities and controlling public use of facilities during flooding events • Alterations to the mix and diversity of wildlife species as a result of inundation of habitats In 2016-2017, the City of Edina updated their hydrologic and hydraulic models to reflect the increased precipitation frequency estimates for the region based on NOAA’s 2013 Atlas 14 publication. The updated precipitation frequency depths result in increased flood risk throughout the city. The Atlas 14 hydrologic and hydraulic modeling and flood risk mapping analysis identified numerous flood-prone locations throughout the city, including some areas along the creeks, near lakes or wetlands, and areas adjacent to or within low areas where stormwater pools during large storm events. While many of the flood-prone areas are localized, some of the flooding problems are more regional in nature. Beyond Atlas 14, climatologists indicate that large, intense rainfall events are occurring more frequently and climate change predictions indicate large rainfall events will become more extreme in the future in this region. These changing rainfall patterns will result in additional flood risk for the city and its residents and businesses. The increasing imperviousness trend in urban areas, combined with the increased precipitation due to climate change and reflected in the NOAA Atlas 14 publication, translates to increased flood risk throughout the community. 15.1.1 Flood protection and runoff management infrastructure Municipal stormwater systems provide multiple functions, including runoff management (removal of stormwater) and flood protection. Design of stormwater infrastructure is guided by the criteria set forth in Section 3.1 including level of service and the level of protection criteria. Level of service is defined as the capacity provided by municipal drainage systems to remove runoff and prevent significant interference with normal daily transportation, commerce, or access that might result from a rainstorm. For example, gutters might run full, but when the runoff arrives at a catch basin it would enter the catch basin and be carried away by the storm sewer. Intersections would not be inundated to an extent that adversely impacts driving conditions, right-of-way would be undamaged, and public infrastructure would operate normally. Level of protection is defined as the capacity provided by a municipal drainage system to prevent property damage and assure a reasonable degree of public safety following a rainstorm. For example, runoff might bypass a catch basin and collect in low-lying areas such as intersections, but would not cause flood damage to structures. The City applies these design criteria, where feasible, as part of street reconstruction and other improvement projects. The City also seeks to apply these design criteria as development or redevelopment occurs. However, some existing stormwater City of Edina 2018 Comprehensive Water Resources Management Plan 15-3 conveyance systems throughout the city have capacity limitations and cannot be guaranteed to provide the desired discharge capacity where private storm sewer systems tie into the trunk system. In these cases, the City will work with private property owners during the redevelopment process to help them understand capacity limitations of the trunk storm sewer system and associated implications for site stormwater management. The City of Edina operates and maintains all of the City’s stormwater facilities, and permits and accepts connections from private systems. The operation and maintenance of stormwater facilities is an important part of stormwater management. The City’s stormwater system includes not only pipes and constructed ponds, but also lakes, wetlands, ditches, swales, and other drainage ways. In addition to more typical maintenance measures, maintenance of the stormwater system may also mean maintaining or restoring the ecological characteristics of the natural portions of the stormwater system. Operation and maintenance of the City’s stormwater system is discussed further in Section 15.3. 15.1.2 Flood protection and runoff management programs 15.1.2.1 Assessing Risk The City regularly reviews this plan when improvement projects are proposed to evaluate risks and opportunities for addressing flood issues. The hydrologic and hydraulic models are also continually updated and consulted as private and public entities other than the City propose projects. Risk assessments in problem areas based on the models are used to define applicable development and redevelopment standards, help project owners to understand their risk, and mitigate risk to adjacent areas. 15.1.2.2 Communicating Risk Building an understanding of the flooding and drainage risks in the community, both among agencies and community members, is important for working toward resiliency. When a community understands its risks, it can take actions to mitigate risk before, during, and after a flood event. The City maintains detailed maps regarding flooding and drainage issues, both regionally and locally, and intends to share this information via the City website. 15.1.2.3 Land Use Controls The Floodplain Districts Overlay Ordinance (City Code Chapter 36) governs some land use decisions related to floodplain and flood-prone areas for the regional and local flood. The standards are intended to mitigate flood risk over time as properties redevelop. Chapter 10 of City Code enables staff to require stormwater management plans on qualifying residential and commercial sites. The code is intended to protect neighboring lots so that conditions do not get worse, however, this often means that the already overtaxed public system takes on more volume (see Policy Issues Section 15.4.7. City of Edina 2018 Comprehensive Water Resources Management Plan 15-4 15.1.2.4 Technical Assistance The City has a Certified Floodplain Manager (CFM) to act as the local liaison for FEMA floodplain issues. The CFM provides technical assistance for Letter of Map Amendments, maintains elevation certificates, and interprets requirements for development and redevelopment that intersect with the FEMA regulated floodplain areas. 15.1.3 Flood Risk Reduction Strategy As part of this 10-year plan, the City of Edina will develop a Flood Risk Reduction Strategy that outlines a plan for working toward reducing flood risk, where appropriate, and meeting its stormwater management goals for providing a 1-percent-annual-chance (100-year) level of protection. The strategy will identify and characterize flood problems throughout the city and identify strategies and infrastructure improvements to address flood-prone areas. The strategy will include preparation of planning-level cost estimates to help understand the potential financial investment required to meet the City’s flood protection goals and the anticipated timeframe for implementation. When completed, the Flood Risk Reduction Strategy will be included as an amendment to this CWRMP. At the time of this plan’s writing, the focus area for the Flood Risk Reduction Strategy is the Morningside neighborhood in the Minnehaha Creek Watershed District. 15.1.3.1 Implementation Approaches The Flood Risk Reduction Strategy will detail the City’s approach to addressing the flood-prone areas identified based on Atlas 14 precipitation frequency estimates, which include the following implementation categories: • Engineered Improvements- flood risk reduction strategies will be implemented through engineered capital improvement projects, such as increasing stormwater discharge capacity, creating additional upstream stormwater storage, diverting stormwater, and/or grading and landscape modifications. These may occur as standalone flood and drainage projects or in conjunction with other projects such as neighborhood roadway reconstruction or parks improvements. • Anticipated Redevelopment- flood risk reduction strategies will be implemented as redevelopment occurs, through stormwater infrastructure improvements, grading and landscape modifications, and/or raising structures above flood elevations. • Residential Redevelopment- flood risk reduction strategies will be implemented as homes are remodeled or reconstructed, through private stormwater infrastructure improvements, grading and landscape modifications, and/or raising structures above flood elevations. • Incentivized Retrofits- where engineered improvements are cost prohibitive or not feasible due to site constraints and redevelopment is not anticipated the City may provide incentives to property owners to conduct grading and landscape modifications or modify structures to reduce flood risk. City of Edina 2018 Comprehensive Water Resources Management Plan 15-5 • Risk Acceptance- where engineered improvements to reduce flood risk are cost prohibitive or not feasible due to site constraints, and redevelopment is not anticipated, it may be necessary to accept a lower level of protection. Making incremental improvements to address flooding issues throughout the city will require a mix of capital infrastructure investments, programmatic approaches (development/redevelopment review), and regular operation and maintenance. Along with the approaches described here, Table 3.2. Strategies and Potential Actions for Addressing Local and Regional Flood Issues provides a variety of tools for working towards flood resiliency. 15.1.3.2 Opportunity Identification/Prioritization The Flood Risk Reduction Strategy will focus on identification and prioritization of flood reduction efforts. The City will seek to maximize cost effectiveness and capitalize on coinciding opportunities, such as planned street reconstruction, redevelopment, availability of land, and other planned infrastructure improvement projects. Consideration will also be given to achieving additional “co-benefits”, such as water quality improvements, open space expansion, and wildlife habitat improvement. Development of the Flood Risk Reduction Strategy is identified as an action item in Table 15.1. Potential flood risk reduction implementation activities are identified in Table 15.2. _______________________________________________ 1 To be determined City of Edina 2018 Comprehensive Water Resource Management Plan 15-6 Table 15.1 Water Resources Implementation Program Project Name / Location Description Proposed Improvement Cost Estimate ($) Proposed Year Funding Source Plan Amendments This Water Resources Management Plan may need to be amended periodically. This plan will be amended as required. As Required As Required SW Utility Plan Update/Revision This Water Resources Management Plan will expire in 2028 and will need to be updated/revised to be consistent with WMO plans and policies and state and federal rules. This Plan will be updated to maintain compliance with state and federal rules and WMO policies. 100,000 2027-2029 SW Utility City-wide education and resident involvement Create and implement City’s Education Plan including educational and outreach tasks called out in the City’s SWPPP. Maintain level of activity to involve and educate residents with various water related issues. 10,000/yr Annual SW Utility Illicit discharge detection and elimination Continue implementation of the SWPPP Illicit discharge detection and elimination tasks. Inventory, mapping, inspection, enforcement and education. City Staff Annual SW Utility Interactive GIS water resources web mapping tool Annual updates and maintenance activities for interactive GIS web mapping tool, as needed. Web mapping tool will have continued functionality and reflect most up-to-date information available. 2,000 Annual SW Utility Construction site stormwater runoff control Maintain construction site stormwater runoff control program and SWPPP tasks. Plan review, inspection, enforcement and education. City Staff Annual SW Utility Post construction stormwater management Maintain the post construction stormwater management and SWPPP tasks. Design standards and review, education. City Staff Annual SW Utility Street Sweeping Pollution prevention through regular street sweeping. Strategic street sweeping in target areas and at optimal times to minimize pollution to surface waters. City Staff (3000 hours annually) Annual SW Utility _______________________________________________ 1 To be determined City of Edina 2018 Comprehensive Water Resource Management Plan 15-7 Project Name / Location Description Proposed Improvement Cost Estimate ($) Proposed Year Funding Source Storm Drainage System Maintenance Maintain the storm drainage system. Structure clean-out, outlet sedimentation removal, maintenance and training, inspections and recording with concentration of efforts in target areas. City Staff (1400 hours annually) Annual SW Utility City facility operations and maintenance Manage city facilities to prevent pollution Regularly inspect facilities and adjust practices to prevent pollution City Staff Annual SW Utility Storm Drainage System Inventory Manage inventory of storm sewers, manholes, catch basins, etc. Actively manage database. Continue to incorporate private infrastructure and stormwater BMPs into inventory. Share stormwater network on interactive map. City Staff Ongoing SW Utility Updates to Hydrologic and Hydraulic Modeling Annual updates to City’s stormwater management system modeling to reflect infrastructure improvements. Current, up-to-date modeling results. 28,000/year Annual SW Utility Impaired Waters Tracking and Review Monitor impaired waters list and respond with review and implementation as needed per the SWPPP. The City will remain informed and responsive to impaired waters issues. City Staff Ongoing SW Utility Annual SWPPP update and meeting Make any needed updates to the City’s SWPPP and hold an annual public meeting to receive public input. Involve residents in water resource issue development and implementation tasks. City Staff Annual SW Utility Flooding and drainage improvements Opportunistic flooding and drainage improvements to be addressed in street reconstruction projects, development / redevelopment, and other capital projects. 200,000/yr plus opportunistic Capital Improvement Projects Ongoing SW Utility _______________________________________________ 1 To be determined City of Edina 2018 Comprehensive Water Resource Management Plan 15-8 Project Name / Location Description Proposed Improvement Cost Estimate ($) Proposed Year Funding Source Water Conservation Policy Review Review and adapt as necessary an ordinance that is protective of groundwater quality and quantity. To be determined. City Staff 2018 - 2019 SW Utility Implementation of Stormwater Management Ordinance Adopt and implement a stormwater management ordinance reflecting the policies and design standards detailed in this plan. To be determined. Related to Flood Risk Reduction Strategy and Clean Water Strategy outcomes. City Staff TBD1 SW Utility Wellhead Protection Plan Implement wellhead protection plan and provide plan updates to MCWD and NMCWD. Effectively manage and reduce where possible the number of potential contamination sources, namely private wells, through outreach and development review. City Staff Ongoing SW Utility Water Reuse Potential Investigate water reuse potential as opportunities arise. To be determined. City Staff Ongoing SW Utility Infiltration and Inflow reduction Reduce the amount of infiltration and inflow to the sanitary sewer system. Reduce the amount of infiltration and inflow to the sanitary sewer system. 600,000/year Ongoing SW Utility Implementation of Nine Mile Creek Chloride TMDL Implement the requirements of the Nine Mile Creek Chloride TMDL. BMPs per the Nine Mile Creek Watershed Chloride TMDL Report, to be incorporated into Clean Water Strategy. City Staff Ongoing SW Utility/ NMCWD/ Grant Funding Participation in the NMCWD Lake Cornelia Use Attainability Analysis (UAA) update Partner with the NMCWD to evaluate potential remedial measures for improving the water quality of Lake Cornelia. To be determined. City Staff 2018 SW Utility _______________________________________________ 1 To be determined City of Edina 2018 Comprehensive Water Resource Management Plan 15-9 Project Name / Location Description Proposed Improvement Cost Estimate ($) Proposed Year Funding Source Participation in the NMCWD Lake Edina Use Attainability Analysis (UAA) development Partner with the NMCWD to evaluate potential remedial measures for improving the water quality of Lake Edina. To be determined. City Staff 2018 SW Utility/NMCWD/ Grant Funding Participation in Lower Minnesota River WRAPS Participate in stakeholder process for Lower MN River WRAPS including Lake Cornelia, Lake Edina, and Nine Mile Creek. To be determined. City Staff 2017-2019 SW Utility Implementation of recommendations from the Lower Minnesota River WRAPS and NMCWD UAAs Partner with the NMCWD to implement the recommended remedial measures to improve the water quality of Lake Cornelia, Lake Edina, Nine Mile Creek. To be determined and addressed in Clean Water Strategy. TBD1 2018-2028 SW Utility/ NMCWD/ Grant Funding Participation in the NMCWD Mirror Lake Use Attainability Analysis (UAA) update and implement recommendations Partner with the NMCWD to update UAA and implement recommended remedial measures to improve the water quality of Mirror Lake. To be determined. TBD1 2022 SW Utility/ NMCWD/ Grant Funding Participation in the NMCWD Arrowhead and Indianhead Lakes Use Attainability Analysis (UAA) update and implement recommendations Partner with the NMCWD to update UAA and implement recommended remedial measures to improve the water quality of Arrowhead and Indianhead Lakes. To be determined. TBD1 2021 SW Utility/ NMCWD/ Grant Funding Evaluate Zoning Ordinance Revisions Evaluate zoning ordinance revisions needed to incorporate shoreland management. Revise zoning ordinance as needed. City Staff 2018 SW Utility _______________________________________________ 1 To be determined City of Edina 2018 Comprehensive Water Resource Management Plan 15-10 Project Name / Location Description Proposed Improvement Cost Estimate ($) Proposed Year Funding Source Engineering Standards Development Continue to develop and implement stormwater management design standards. Consider ordinance changes as needed. City Staff 2018-2019 SW Utility Lake and Pond Management – aquatic vegetation Implement lake and pond management policy to manage requests for aquatic vegetation destruction. 45,000/yr Annual SW Utility Stormwater pond evaluation Accessory to Clean Water Strategy. Review of stormwater ponds to determine pollutant removal and develop maintenance schedule. 10,000 2018 SW Utility Flood Risk Reduction Strategy Develop a strategy and plan for working toward reducing flood risk, where appropriate, and meeting stormwater management goals for providing a 1-percent-annual-chance (100-year) level of protection. The strategy will identify and characterize flood problems throughout the city and identify strategies and infrastructure improvements to address flood-prone areas. The strategy will include preparation of planning-level cost estimates to help understand the potential financial investment required to meet the City’s flood protection goals and the anticipated timeframe for implementation. 190,000 2018 SW Utility/Grant Funding _______________________________________________ 1 To be determined City of Edina 2018 Comprehensive Water Resource Management Plan 15-11 Project Name / Location Description Proposed Improvement Cost Estimate ($) Proposed Year Funding Source Clean Water Strategy Develop a water quality implementation program which outlines a plan for working toward meeting water quality goals. A tool to gain feedback from City Council and set the pace, location, and ultimate goal for clean water. 5-year implementation strategy to be reviewed annually. Identifies water quality CIP and regular housekeeping practices, quantifies pollution removal, provides cost estimates. Determine pollutant load reduction necessary for nondegradation of water bodies. Coordinated with street reconstruction projects, redevelopment, park improvements, and other opportunity areas. Incorporates various TMDLs/WRAPS/UAAs/CWRMP items and various BMPs. Has annual or biannual reporting to quantify movement toward goal – can also be used for annual SWPPP and MS4 reporting. 200,000 2019 - 2020 SW Utility/Grant Funding Arden Park Restoration Enhancements to the park to improve fish passage, wildlife habitat, and water quality. Removing 54th Street dam, re-meandering the creek, adding fishing and recreation accesses, and managing stormater. 4,000,000 2018-2019 SW Utility/ MCWD/Grant Funding _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-12 Table 15.2 Potential Implementation Activities (including Capital Improvements) ID 2018 CWRMP Section Project Name/Location Proposed Improvement Nine Mile Creek—North S1 5.3.1.1 Maloney Avenue and Tyler Court (ML_35 and ML_19) Upgrade the downstream 18” pipe to a larger pipe. Create an upstream pipe restriction to limit inflow and use upstream storage. S2 5.3.1.2 Between Leslee Lane and Kaymar Drive (MD_22) Upgrade the outlet pipes to larger pipes. Lower, or at least maintain, the surface overflow to Jeffrey Lane. S3 5.3.1.3 Parkwood Road and Schaefer Road (MD_28, MD_29, and MD_35) Underground storage combined with infiltration (B soils) under Parkwood Road. Lower, or at least maintain, the surface overflows between homes. S4 5.3.1.4 Schaefer Road and View Lane (MD_38) Install a pipe to the east to Bredesen Park. S5 5.3.1.5 Nine Mile Village Townhomes (MD_49) Construct a berm on the west side of Villa Lane. Redirect overflow from Bredesen Park slightly to the south. S6 5.3.1.6 Hawkes Lake and Upstream Surrounding Area (HL_1, HL_11c, HL_11w, HL_49, and HL_12) Increase the capacity of the pumped outlet and the downstream gravity drain. Add storage in the city- owned parcel in MD_15. R1 5.2.1 Colonial Church Parking Lot and Colonial Way (CO_3, CO_4, and CO_10) N/A; to be studied. R2 5.2.1 Nine Mile Creek, Malibu Drive (NMN_60) N/A; to be studied. R3 5.2.1 Blake Road South and South Knoll Drive (MD_24 and MD_25) N/A; to be studied. R4 5.2.1 Nine Mile Creek, south of Londonderry Drive, west of Walnut Drive (EdCrk3) N/A; to be studied. R5 5.2.1 Nine Mile Creek, northwest of Vernon Avenue South and View Lane (EdCrk5) N/A; to be studied. R6 5.2.1 Olinger Boulevard and Sun Road (MD_15) N/A; to be studied. Appendix C Hawkes Drive (HL_2) Construction of overflow swale between homes. Appendix C 5711 and 5717 Grove St (HL_18) Upgrade to larger pipes. Appendix C 5516 and 5520 Dundee Rd (HL_25) Perform detailed field survey. Additional pumping capacity may be required at lift station. _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-13 ID 2018 CWRMP Section Project Name/Location Proposed Improvement Appendix C Fountain Woods Apartments (NMN_90 and NMN_23) Privately owned drainage system. Notify owners of flood potential. Nine Mile Creek—Central S7 6.3.1.1 Antrim Road and Chapel Drive (NMC_41) Survey homes to confirm flooding problem. Individual flood-proofing. Lower, or at least maintain, the surface overflow between homes. S8 6.3.1.2 Ridgeview Drive (NMC_106 and NMC_107) Survey homes to confirm flooding problem. Install a gravity system, with a backflow preventer, to Nine Mile Creek on the other side of the railroad tracks. Install a pipe to connect to existing storm sewer at Tifton Drive and Ridgeview Drive. S9 6.3.1.3 West 66th Street and Naomi Drive (NMC_71, NMC_74, and NMC_103) Pumped outlet to Normandale Park, with additional storage added in the park, or a gravity system to Nine Mile Creek. Could connect to Nine Mile Creek through NMC_106 if that proposed improvement is constructed. R7 6.2.1 Cherokee Trail (IP_2 and IP_4) N/A; to be studied. R8 6.2.1 Nine Mile Creek, north of the West 70th Street crossing (NMC_1) N/A; to be studied. R9 6.2.1 Valley View Road and Hillside Road (NMC_84, NMC_86, and NMC_120) Street Reconstruction Project for Edina in 2017. R10 6.2.1 TH 62 at Nine Mile Creek crossing (NMC_104) N/A; to be studied. R11 6.2.1 TH 62 at Tracy Avenue (NMC_28, NMC_94, NMC_93, NMC_92, and NMC_87) N/A; to be studied. Appendix C 6005 and 6009 Crescent Dr (manhole 457) Construction of a positive overflow channel. Appendix C Cherokee Trail and Gleason Backyard Depression Area (IP_4) Work with homeowners to evaluate construction of a low level outlet from landlocked depression. Appendix C 5339 West 64th Street (NMC_80) Upgrade to larger pipes at Ridgeview Drive and Valley Lane. Appendix C Valley View Road and Hillside Road (NMC_86 and NMC_120) Upgrade to larger pipe. Lake Cornelia/Lake Edina/Adam’s Hill D1 7.3.1.1 Southdale Road Neighborhood (LE_34, LE_36, and LE_43)2 Increase the pipe size and the weir size north to Lake Cornelia. Prevent flow from Valley View Road _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-14 ID 2018 CWRMP Section Project Name/Location Proposed Improvement with berms and/or floodwalls. Increase pipe capacity south to Lake Edina. D2 7.3.1.2 Southwest Corner of TH 62 and TH 100 (NC_7, NC_8, NC_13, NC_11, NC_12, NC_14, NC_15, NC_16, and NC_20)2 Increase the pipe capacity of the downstream 30- inch pipe and adding inlets in the West 64th Street area. Underground storage under streets north of West 64th Street. Increase the pipe capacity from North Cornelia all the way into NC_9. R12 7.2.1 Garrison Lane and St. Johns Avenue, northeast (NC_5 and NC_49) N/A; to be studied. R13 7.2.1 Garrison Lane and St. Johns Avenue, southeast (NC_2) N/A; to be studied. R14 7.2.1 South Cornelia, east side (SC_1) N/A; to be studied. R15 7.2.1 Lake Edina (LE_1, LE_10, and LE_7) N/A; to be studied. R16 7.2.1 Heatherton Trail (LE_29) N/A; to be studied. R17 7.2.1 York Avenue South, north of Parklawn Avenue (AHR_15) N/A; to be studied. R18 7.2.1 6124 Wilryan Avenue (NC_46 and NC_45) N/A; to be studied. R19 7.2.1 Hazelton Road and Lynmar Lane (LE_19, LE_24, and LE_21) N/A; to be studied. R20 7.2.1 Dunberry Lane and Oaklawn Avenue (LE_31 and LE_28) N/A; to be studied. Appendix C Swimming Pool Pond (NC_3)/North Lake Cornelia (NC_62) Upgrade pipe and outlet structure. Appendix C Hibiscus Avenue (LE_53, LE_7, and LE_10) Construct positive overflow swale. Appendix C 6312, 6316, 6321, 6329 Tingdale Ave (NC_11) No recommendation at this time. Further analysis required. Appendix C St. Johns/Ashcroft and West 64th Street (NC_40 and NC_26) Installation of additional pipe to drain TH 62 median ditch and prevent upstream flooding. Appendix C Barrie Road and Heritage Drive (NC_86, NC_97, and NC_99_ No recommendation at this time. Reevaluation of TH 62 system will be required. Appendix C York Avenue and West 64th Street (NC_88) Increase pump capacity. Adjust pump on/off elevations. _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-15 ID 2018 CWRMP Section Project Name/Location Proposed Improvement Appendix C TH 62 at France Avenue (NC_132) No recommendation at this time. Reevaluation of TH 62 system will be required. Appendix C Parnell Avenue and Valley View Road (NC_135) No recommendation at this time. Further analysis required. Nine Mile Creek—South S10 8.3.1.1 West 70th Street and West Shore Drive (NMS_38) Increase pipe capacity under West 70th Street. Regrade/lower the surface overflow along West 70th Street to the west. Add storage in Arnesan Park (LE_54) and install connecting pipe. S11 8.3.1.2 Centennial Lakes (CL_1) Flood proof individual low entries. A floodwall (~3 feet) around the lake at the southern end. R21 8.2.1 City of Edina Building, Metro Boulevard (NMS_51) N/A; to be studied. R22 8.2.1 West 73rd Street, west of TH 100 (NMS_28, NMS_53, NMS_3, NMS_57, NMS_30, NMS_62, NMS_27, NMS_56, NMS_58, and NMS_65) N/A; to be studied. R23 8.2.1 Parklawn Avenue (NMS_77, NMS_70, and NMS_93) N/A; to be studied. R24 8.2.1 Oaklawn Avenue and Gilford Drive (NMS_94 and LE_13) N/A; to be studied. R25 8.2.1 France Avenue South and West 72nd Street (CL_58, CL_56, and CL_57) N/A; to be studied. Appendix C 7001 and 7025 France Avenue (CL_51) No recommendation at this time. Nine Mile South Fork S12 9.3.1.1 McCauley Trail West (AH_6) Increase pump and pipe capacity to Aarowhead Lake. Raise the control elevation upstream in AH_3 to store water upstream. Create additional connected storage in AH_9 and/or AH_13. S13 9.3.1.2 Sally Lane and Valley View Road (NMSB_52, NMSB_69, and NMSB_77) Increase the size of the culvert under Valley View Road. Work with the NMCWD to store water upstream west of TH 169. _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-16 ID 2018 CWRMP Section Project Name/Location Proposed Improvement R26 9.2.1 Between Gleason Road and Mark Terrace Circle (NMSB_27) N/A; to be studied. R27 9.2.1 7122 Tupa Drive, 7117 Gleason Road, and 7116 Gleason Road (NMSB_13 and NMSB_30) N/A; to be studied. Appendix C 6309 Post Lane (AH_31) Construction of two control structures to restrict flow through the existing storm sewer system. Appendix C Braemar Golf Course (NMSB_62) No recommendation at this time. Further analysis required. Appendix C 7009 and 7013 Sally Lane Backyard Depression Area (NMSB_70) None. Analyzed in STS-406. Southwest Ponds S14 10.3.1.1 Gleason Road and Bonnie Brae Drive (SWP_24) Survey homes to confirm flooding problem. Individual flood-proofing of potentially impacted homes. Create additional storage in the city-owned parcels south of Bonnie Brae Drive. R28 10.2.1 Kemrich Drive and Shannon Drive (SWP_53 and SWP_66) N/A; to be studied. R29 10.2.1 Dewey Hill Road, west of Cahill Road (SWP_21, SWP_48, SWP_5, SWP_34, SWP_35, SWP_15, SWP_14, and SWP_4) N/A; to be studied. Appendix C 7411 Coventry Way (SWP_14) Installation of flap gate. Appendix C 7317 Cahill Road (SWP_46) No recommendation at this time. Further analysis required. Appendix C 7709 Stonewood Court (NM494_4) Upgrade to larger pipes. Northeast Minnehaha Creek D3 12.3.1.2 Halifax Avenue South (MHN_84, MHN_3, MHN_4, MHN_56, MHN_89, MHN_55, MHN_61, MHN_62, MHN_87, MHN_90, and MHN_2)2 Regrade Halifax to remove the depressions and pooling areas; allow positive drainage north and west to Minnehaha Creek. Add additional outlets from backyard depressions (MHN_87, MHN_61, and MHN_62), potentially south to 54th Street. D4 12.3.1.3 Weber Park (MS_26, MS_25, MS_41, MS_32, MS_44, MS_24, MS_15, MS_53, MS_2, MS_38, MS_40, MS_54, MS_31, MS_33, MS_39a, and MS_39b)2 Add capacity out of Weber Park to Lake Calhoun. Increase capacity in the south storm sewer area to Weber Park. Add substantial storage in Weber Park, ballfields, and potentially in Weber Woods. _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-17 ID 2018 CWRMP Section Project Name/Location Proposed Improvement S15 12.3.1.1 Indianola Avenue South of West 50th Street (MHN_72) Underground storage and infiltration (A soils) with sufficient inlet capacity. Enlarge downstream pipes to Minnehaha Creek, while not creating downstream impacts. S16 12.3.1.4 Edinbrook Lane and Westbrook Lane (MHN_79) Reroute flow from MHN_78. Improve, and possibly lower, the surface overflow to the north. Purchase the homes to create storage and infiltration (B soils). S17 12.3.1.5 North of Morningside Road between Lynn Avenue and Crocker Avenue (MS_22) Survey homes to confirm flooding problem. Add an inlet in the backyard area and connect to existing storm sewer under Crocker Avenue or Lynn Avenue. S18 12.3.1.6 Branson Street between West 44th Street and Morningside Road (MS_3, MS_48, and MS_7) Add inlets and connecting pipes in the backyard depression areas. Increase pipe sizes under Morningside Road. Add storage in MS_7. Add underground storage under Branson Street and Oakdale Avenue. R30 12.2.1 West 50th Street and Arden Avenue (MHN_6, MHN_7, MHN_72, MHN_53, and MHN_54) N/A; to be studied. R31 12.2.1 Country Club Road and Casco Avenue (MHN_16) N/A; to be studied. R32 12.2.1 Minnehaha Creek, southeast of Wooddale Avenue and West 50th Street (MHC_3 and MHN_27) N/A; to be studied. R33 12.2.1 Minnehaha Creek, southwest of TH 100 and West 44th Street (MHC_1) N/A; to be studied. R34 12.2.1 Minnehaha Creek, southeast of TH 100 and West 44th Street (MHC_2) N/A; to be studied. R35 12.2.1 Scott Terrace and West 42nd Street (MS_52) May be addressed with the Weber Park proposed improvements. R36 12.2.1 Townes Road and West 48th Street (White Oaks) White Oaks Area, studied in 2013-2014, STS-406. _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-18 ID 2018 CWRMP Section Project Name/Location Proposed Improvement R37 12.2.1 TH 100 near Harvey Lake (H100_20 and H100_22) N/A; to be studied. R38 12.2.1 Bridge Street and Moorland Avenue and Edina Boulevard (MHN_25, MHN_52, MHN_51, MHN_19, MHN_24, MHN_23, and MHN_22) N/A; to be studied. Appendix C 4000 West 42nd Street and 4100, 4104, and 4108 France Ave (MS_40) Implement recommendations of the 2006 Weber Park Pond Feasibility Study. Appendix C 4308 France Ave (MS_17) Work with homeowners to evaluate installation of gravity system to drain backyard depression area. Appendix C Arden Avenue (MHN_14) No recommendations at this time. Southeast Minnehaha Creek D5 13.3.1.2 Concord and West 58th Street (MHS_59, MHS_26, MHS_58, MHS_42, MHS_53, and MHS_17)2 Add capacity east of Wooddale Avenue or reroute some areas directly to the creek. Additional storage in Pamela Park. S19 13.3.1.1 Tower Street (MHS_75, MHS_86, and MHS_76), between Fairfax Avenue and Wooddale Avenue (MHS_16), and North of 56th Street (MHS_83) Add inlets in these areas and increase downstream capacity to Minnehaha Creek. Add parallel pipe network from West 56th Street and Wooddale Avenue to West 56th Street and Kellogg Avenue. Underground storage and infiltration under side streets. R39 13.2.1 Minnehaha Creek, north of Pamela Park (MHC_4, MHS_8, and MHS_9) N/A; to be studied. R40 13.2.1 Woodcrest Drive and Backyard Pond (MHC_4, MHS_10, MHS_12, and MHS_41) N/A; to be studied. R41 13.2.1 South end of Pamela Park, West 62nd Street (LP_26, LP_17, and LP_22) N/A; to be studied. R42 13.2.1 East side of Pamela Park, Halifax Avenue South (LP_14, LP_10, LP_9, and LP_7) N/A; to be studied. R43 13.2.1 West 61st Street, between Xerxes Avenue South and York Avenue South (MPLS_130) N/A; to be studied. Appendix C 6213 Ewing Ave (LP_15) Upgrade to larger pipes. Appendix C 3600 West Fuller Street (MHS_4) Installation of a catch basin in backyard depression and storm sewer along Beard Avenue. _______________________________________________ In the ID column, D = detailed analysis conducted for flood-prone area (pink) In the ID column, S = screening level analysis conducted for flood-prone area (yellow) In the ID column, R = registered flood-prone area: identified as a flood-prone area but not studied further for this CWRMP (blue) City of Edina 2018 Comprehensive Water Resource Management Plan 15-19 ID 2018 CWRMP Section Project Name/Location Proposed Improvement Appendix C 5605, 5609, 5613, 5617, 5621, 5625, and 5629 South Beard Avenue (MHS_79) Upgrade to larger pipes. Install catch basin in alley. Appendix C 5837, 5833, 5829, and 5825 South Chowen Ave (LP_24) Installation of a catch basin in backyard depression area. Appendix C Chowen Avenue and West 60th Street (LP_27) Perform detailed survey/verification of storm sewer to verify pipe sizes, inverts, and low point of entry. Appendix C 5912, 5916, 5920, 5924, 5928 Ashcroft Avenue and 5925 Concord Avenue (MHS_51) Pumped or gravity outlet of 3 cfs capacity. Appendix C 5840 and 5836 Ashcroft Avenue (MHS_89) Work with homeowners to evaluate installation of catch basin from backyard depression. Appendix C 5609 and 5605 Dalrymple Road (MHS_24), and 5610 and 5612 St. Andrews Avenue (MHS_66) Construct surface overflow swale (1) or upgrade to larger pipes (2). Appendix C 5701 Dale Avenue (ML_12) Upgrade to larger pipes. Appendix C 5213 and 5217 Richwood Drive (ML_7) Perform detailed field survey of wetland storage. Further analysis required. Northwest Minnehaha Creek S20 14.3.1.1 Blake Road South and Spruce Road (HO_4) Increase downstream pipe capacity: (1) increase pipe connecting HO_8 and HO_19, or (2) add additional outlet to the Interlachen Golf Course from the wet pond (HO_8) or from the existing storm sewer under Spruce Road. Add depressions/storage in the golf course to offset additional water. R44 14.2.1 Annaway Drive and Interlachen Country Club (EI_3, EI_25, EI_25a, and EI_34) N/A; to be studied. R45 14.2.1 Annaway Drive, Merilane Avenue, and Mait Lane (EI_1, EI_2, EI_4, and EI_5) N/A; to be studied. Appendix C Interlachen Landlocked Area Construct/raise embankment between landlocked wetland and Meadowbrook Golf Course. Develop management plan for pumped outlet. City of Edina 2018 Comprehensive Water Resources Management Plan 15-20 15.2 Clean Water The streams, ponds, lakes, and wetlands in the City of Edina are an important community asset. These resources supply aesthetic and recreational benefits, in addition to providing wildlife habitat and refuge. The City recognizes the need to protect and improve these resources and strives to manage the City’s water resources so that the beneficial uses of its lakes, streams, ponds and wetlands remain available to the community. Protection and improvement of these resources encompasses operating and maintaining the City’s existing clean water infrastructure, implementing programs to educate and engage the community, developing and implementing pollution reduction strategies, and completing capital improvements. 15.2.1 Clean Water Infrastructure Municipal stormwater systems provide multiple functions, including water quality protection. Ponds and other water quality treatment facilities remove pollutants such as sediment and phosphorus from stormwater prior to the stormwater being discharged to downstream water resources. Much of the city of Edina was developed prior to significant focus on protecting the quality of surface waters. As a result, stormwater from large portions of the city discharges directly to wetlands, lakes, or the creeks. In fact, many of the natural wetlands within the city serve a stormwater management function, providing rate control and pollutant removal benefits to waters downstream. The City’s stormwater system also includes many constructed stormwater ponds and water quality treatment facilities that provide pollutant removal to protect the downstream waterbodies. While the majority of the existing water quality treatment facilities are stormwater ponds, the City also owns and operates numerous underground hydrodynamic separators (also termed grit chambers), sump manholes, surface bioretention basins, and underground storage and infiltration facilities. The City is responsible for operation and maintenance of the public stormwater system, including water quality treatment facilities. Stormwater facilities constructed on private property are generally the responsibility of the private property owner, which includes operating and maintaining the facilities in proper condition, consistent with the original performance design standards. The City of Edina periodically inspects public water quality treatment facilities to ensure they are functioning properly and providing the desired benefits, and will begin inspecting private facilities. Additional information regarding operation and maintenance of public and private stormwater infrastructure is provided in Section 15.3. 15.2.2 Clean Water Programs The City of Edina seeks to protect and improve its water resources through implementation of several clean water programs, including promoting community engagement, pollution prevention through site reviews and implementation of city ordinances, policies, and design standards during and after construction, pollution source control, lake and pond management, and implementing stormwater best management practices. These programs accomplish minimum regulatory standards and, in many areas, move beyond the minimum standard. Details regarding the measurable goals, implementation schedule, and responsible parties for the minimum standards as required by the MS4 permit can be found in the City of Edina’s SWPPP. City of Edina 2018 Comprehensive Water Resources Management Plan 15-21 15.2.2.1 Community Engagement Community engagement is a key component in a successful stormwater management program. The City recognizes that an informed residency is necessary to make progress toward meeting water resources goals. Programmatic activities are designed to build a culture of water resources stewardship necessary to influence change on the landscape. Residents value water resources and City staff seek to involve them in addressing issues through informing, educating, and promoting participation. The City has developed and is implementing a public education and engagement plan to distribute information and conduct outreach activities regarding the impacts of stormwater discharges on water bodies. The City’s education and engagement plan identifies the audience involved, educational goals, activities used to reach goals, activity implementation plans, and available performance measures that can be used to determine success in reaching educational goals. The community engagement plan also includes working collaboratively with the local watershed districts in distributing educational materials and promoting/supporting outreach programs. Annually, the City hosts an opportunity for the public to comment on the SWPPP and water resource programs, although comments may be submitted at any time of the year. This has been done as a standalone meeting or in addition to another engagement event. Notice of the meeting date, time, location, and materials is distributed through various communication channels including the local newspaper. Oral and written input from the public regarding water resources programs will be sincerely considered and adjustments will be made where appropriate. The City also hosts a booth at the annual Open Streets on 50th event with the help of Master Water Steward volunteers to engage the public in water resources topics. A presentation of issues, future activities, and completed projects is also brought to the Edina Energy and Environment Commission with the Annual Water Resources Coordinator’s report. 15.2.2.2 Pollution Prevention Site Plan Review and Design Standards The City of Edina has adopted the control policies discussed in the Runoff Management and Flood Protection—Section 3.1; Water Quality—Section 3.3; and the Erosion and Sediment Control—Section 3.4 sections to promote pollutant prevention and/or reduction from new development and redevelopment areas. These policies are enforced through the site plan review process and through permits issued by the City or respective watershed district. The City of Edina also addresses runoff problems with sound planning procedures. Land use and zoning ordinances promote improved water quality by guiding the growth and redevelopment of the community away from sensitive areas and by restricting certain types of growth to areas that can support it without compromising water quality. City of Edina 2018 Comprehensive Water Resources Management Plan 15-22 Pollution Prevention Practices Pollution prevention and good housekeeping practices can ensure a reduction in the amount and type of pollution that is discharged to downstream water resources from streets, parking lots, open spaces, and storage and vehicle maintenance areas. Many pollution prevention practices are incorporated into the City’s infrastructure operation and maintenance program (see Section 15.3). Other practices that the City implements are more programmatic in nature, including the following: 1. Employee training on incorporation of pollution prevention techniques into municipal operations such as park and open space maintenance, fleet and building maintenance, road salt application, new construction and land disturbances, and stormwater system maintenance. 2. Periodically evaluating city landscaping and lawn-care practices, which may include the use of fertilizers, pesticides, herbicides, lawn mowing, grass clipping collection, mulching and composting, and developing or modifying practices to reduce stormwater pollution. 3. Periodically reviewing practices and policies related to road salt applications, including consideration of alternative products, calibration of equipment, inspection of vehicles and staff training to reduce pollutants from road deicing activities. 4. Evaluating, annually inspecting, and modifying (if necessary) current management practices for all exposed stockpiles, storage, and materials located within City-owned property. 5. Continuing the City’s street sweeping program, including evaluation and identification of potential program improvements, and implementation of changes, as necessary, to reduce stormwater pollutants. 15.2.2.3 Pollution Source Controls Illicit Discharge Detection and Elimination Identification of stormwater pollutant sources includes identification of illicit pollutant discharges and nonpoint sources throughout the city. An illicit pollutant discharge is defined as a non-permitted point source of pollutants that is discharged to the storm sewer system at a specific location. Illicit discharges can enter a storm sewer system directly (through wastewater piping mistakenly or deliberately connected to the storm drains) or indirectly (through infiltration from cracked/leaking sanitary systems, spills collected by drain outlets, or other contaminants such as paint or oil dumped directly into a storm drain). To prevent the harmful effects of illicit discharges, a number of management practices have been developed to implement and enforce a program to detect and eliminate illicit discharges into the City’s stormwater system. The City’s illicit discharge detection and elimination program includes the following components: City of Edina 2018 Comprehensive Water Resources Management Plan 15-23 1. An annually-updated storm sewer system map showing the location of all City-owned storm sewer pipes (24-inch diameter or greater), outfalls, locations where discharge leaves the City, and water bodies. 2. Periodic review of existing City ordinances relating to illicit discharges and develop/adopt an illicit discharge ordinance as necessary. 3. Expansion of the City’s program to detect and reduce all forms of non-stormwater discharges and continuation of inspection for illicit discharge during the outfall and pond inspections. 4. Distribution of educational materials to residents and providing illicit discharge educational information or annual training for City staff. Construction Site Stormwater Runoff Control Runoff management from construction sites minimizes the amount of sediment and other pollutants entering the water bodies within the city. The City implements the erosion control policies identified in Section 3.4, including the following activities: 1. Permits for land disturbing activities consider erosion and sediment control. 2. Construction site operators must provide a phone number, website, and point of contact for the public to report stormwater pollution issues. 3. Construction site operators must conform to MPCA, watershed district, and City ordinances pertaining to erosion and sediment controls and waste controls. The City enforces erosion and sediment control and stormwater management on lots >1 acre in size, and has limited stormwater, erosion and sediment control standards for sites under 1 acre associated with grading or demolition permits. The City also requires that project applicants or owners contact the NMCWD or MCWD to determine if watershed district permits are required. 15.2.2.4 Lake and Pond Management The City has established policies to guide its management of lakes and other water resources within the city (Section 3.3 and Section 3.5) and works closely with the watershed districts to protect and improve the quality of these resources. This generally includes participating in water quality studies and planning activities within the watershed districts and other agencies and implementing stormwater management practices and programs to reduce pollutant contributions. In 2014, the City established a lake and pond management policy to manage residents’ requests for lake management activities, which tend to focus on aquatic vegetation management. The policy establishes a system to prioritize the waterbodies, defines management service levels, and lays out a process to involve shoreline owners in waterbody management. The City encourages residents to form Lake Associations and lake groups to advocate for management of waterbodies. An association is a voluntary organization made up of people who own land on or near a body of water. Land owners often form an association when they are concerned about issues regarding City of Edina 2018 Comprehensive Water Resources Management Plan 15-24 the quality or use of the body of water and want to deal with them in an organized manner. Lake groups are less formal and may be more appropriate for some smaller waterbodies. In some cases, a formal or informal group is required for a waterbody to be eligible for services under the lake and pond management policy, which is mostly centered around aquatic vegetation management. Forming an association has several benefits, including: • At a minimum of once per year, a meeting is held to discuss topics related to the waterbody. This approach encourages representation of all stakeholders and decisions that are based on the majority. Grant opportunities and petitions have more merit when brought forth by a coordinated group that represents the majority. • Recommendations for treatment come from local residents instead of city staff. An association meets with members to gather feedback and recommend annual treatment. The association Board of Directors would then request that the city coordinate treatment and special assess costs back to the special assessment district. Alternatively, the group could operate independently of the city to coordinate and pay for services on their own. Local ordinances and DNR permit requirements would still apply. • Information can be shared between the city and the association more effectively. • Organizing around the shared resource can build a culture of water stewardship. Associations may opt to organize a block party or lead an education campaign. The organization can potentially organize and fund additional elective activities. Examples might include a social event or special study. Aquatic Vegetation Aquatic vegetation has an important place in the ecosystem of lakes and ponds. It provides food and shelter to fish and wildlife, and uses phosphorus for its growth, isolating it from the water column and limiting algae growth. While aquatic vegetation is beneficial to aquatic life and water quality, it can also be a detriment to recreation and sometimes aesthetics, especially when excess nutrients cause overgrowth. Aquatic Vegetation Treatment Request Process The City manages requests for aquatic vegetation treatment using the following system established to prioritize the waterbodies, define management service levels, and lay out a process to involve shoreline owners in waterbody management: City of Edina 2018 Comprehensive Water Resources Management Plan 15-25 Step 1: Use the following classification to determine the points awarded based on waterbody size. Size Points Awarded • Large (10+ acres) 4 • Medium (5-9.9 acres) 3 • Small (2.5-4.9 acres) 2 • Tiny (1-2.4 acres) 1 • <1 acre Not eligible for management by City Step 2: Use the following classification to determine the points awarded based on water quality of the water body. Water Quality Points Awarded • 303(d) Impaired Waters List 4 • Drains directly to impaired water or a waterbody which meets water quality goals and is in protection mode 3 • Data shows that waterbody does not meet applicable state or watershed water quality goals 2 • No data 0 Step 3: Sum points awarded from Steps 1 and 2. Step 4: Use the following classification to determine initial service level based on points awarded. Service Level Points Required • High 7-8 • Medium 5-6 • Low 3-4 • None 0-2 Step 5: If any of the following apply, the service level can be raised*: • forming an informal lake group or formalized lake association with 50% plus one of the shoreline properties represented , or • providing significant public access and use *Water bodies may only move up one service level, even if they have both an association and public access. City of Edina 2018 Comprehensive Water Resources Management Plan 15-26 The system described above is used to define the City’s management service level for a given lake. The service level for many waterbodies have already been determined and can be accessed online via the City’s Water Resources Library and is also provided in Appendix E. Contact the City for the most up-to- date list. Table 15.3 identifies the level of potential lake management activity, depending on the established service levels. Table 15.3 Level of Potential Lake Management Activity by Service Level City-Funded Activities Additional Elective Services* Service Level Whole lake algae treatment (as permitted/ required) Invasive aquatic plant treatment** Lake study (up to 2 lakes per year) City staff support (see Table 15.4 below) DNR Permits and Facilitation Aquatic vegetation management Alternative methods (see Table 15.4 below) DNR permits and facilitation High Yes Yes Yes Yes Yes Yes Yes Yes Medium Yes Yes Yes Yes Yes No No No Low Yes Yes No Yes Yes No No No None At City’s discretion, lowest priority No No No *Cost of elective services are special assessed to property tax bill. This option requires a formalized lake association, registered as a nonprofit organization in the state of Minnesota, as described in the policy. **Invasive aquatic plant treatment will be pursued to the extent that it limits the spread, fits within budget, cost/benefit analysis supports it, and has a clean water benefit. Invasive aquatic plant treatment will not be completed solely to accomplish a recreation or aesthetic goal. Table 15.4 City staff support activities and alternative methods related to Table 15.3 City staff support activities (related to Table 15.3 above): Alternative methods (related to Table 15.3 above) Association/group formation All alternative methods (such as barley straw, floating treatment wetlands, etc.) are elective services. Education There may be some cost share available from the city. Facilitate data collection Facilitate group projects Technical resource Duckweed Management The City will not participate in destruction or removal of duckweed for recreational or aesthetic purposes. City of Edina 2018 Comprehensive Water Resources Management Plan 15-27 Cattail Management The City will only manage cattails such that they don’t obstruct water flow. The City will not participate in destruction or removal of cattails for recreational or aesthetic purposes. Requesting a Lake Study Requests for lake studies must be submitted in writing to the City’s Water Resources Coordinator. The request must meet the following criteria: • Come from a formal or informal group, representing the majority of residents. Where there is a formal group, the board may submit a request on behalf of the group. Where there is an informal group, signatures from representatives of 50% plus one properties surrounding the resource must provide a signature in support of the request. • Identify what the group hopes to accomplish with a lake study, specifically indicating what questions they hope to have answered. • Waterbodies will be eligible for lake studies once every 5-year period. • Requests for lake studies will expire after 9 months. • Requests will be received on a first come, first served basis with new applicants receiving preference. • Lake study scope will be limited by annual budget. • Up to two lake studies will be funded per year, contingent upon annual budget. 15.2.3 Clean Water Strategy As part of this 10-year plan, the City of Edina will develop a clean water implementation strategy that outlines a plan for working toward meeting its clean water goals. The strategy will address the City’s approach to meeting the pollutant reduction targets identified through the TMDL and WRAPS process. The strategy will also determine pollutant load reduction targets for nondegradation of water bodies that are not impaired and identify an approach for achieving these stormwater management targets. The clean water implementation strategy will be a 5-year strategy that identifies regular “good housekeeping” stormwater practices and clean water capital improvement projects (CIP) to achieve the goals, including quantification of pollutant removals and preparation of planning-level cost estimates. This information will be used for planning, as well as assessment of cost-benefit for project prioritization. The implementation strategy will be developed in coordination with street reconstruction projects, redevelopment, and other opportunities. Annual or biennial reporting will be included in the strategy to quantify movement toward the City’s goals and track activities for the City’s annual SWPPP and MS4 reporting. When completed, the Clean Water Strategy will be included as an amendment to this CWRMP. At the time of this plan’s writing, the focus area for the Clean Water Strategy is Lake Cornelia in the Nine Mile Creek Watershed District. City of Edina 2018 Comprehensive Water Resources Management Plan 15-28 15.2.3.1 Implementation Approach The Clean Water Strategy will define clean water goals, the cost and pace of achievement, and plan implementation opportunities including the following categories: • Redevelopment- implementation of stormwater management rules as part of redevelopment • Redevelopment- expansion of site or regional stormwater management beyond compliance with stormwater management rules • Retrofit- implementation of stormwater management as part of City street reconstruction projects on public land • Retrofit- targeted implementation of stormwater management BMPs for improving water quality of an impaired water body. These BMPs may require land acquisition. • Retrofit- implementation of stormwater management BMPs in partnership with other public- or non-profit land owners • Re-design/re-purpose- implementation of stormwater management BMPs as part of city improvement projects (e.g., park improvements, city facility improvements) Each of the clean water improvement opportunity categories identified above have opportunities for partnership with other entities, such as private land owners, watershed districts, non-profit organizations, or other local governmental entities. 15.2.3.2 Opportunity Identification and Prioritization The City will pursue clean water improvements that maximize cost effectiveness and capitalize on coinciding opportunities, such as planned street reconstruction, redevelopment efforts, availability of land, or other planned infrastructure improvement projects. Consideration will also be given to achieving additional “co-benefits”, such as flood risk reduction, recharge of shallow groundwater aquifers, wildlife habitat improvement, and groundwater conservation. BMP Cost Effectiveness Stormwater best management practices (BMPs) have a wide range of cost effectiveness, depending on factors such as the suitability of soils for infiltration of stormwater and the availability and cost of land. Soil Suitability for Infiltration Infiltration-based stormwater BMPS are often most effective in reducing stormwater volume and pollutant loading to downstream water bodies. Infiltration describes a process where stormwater runoff seeps into the soil. Because the water stays near to where it lands, the volume of runoff (and associated pollutants) delivered downstream is reduced. Infiltration also recharges groundwater and treats stormwater through natural filtration. This is particularly valuable when lakes, wetlands, or trout resources are downstream. City of Edina 2018 Comprehensive Water Resources Management Plan 15-29 Infiltration-based stormwater BMPs are not very practical in soils with low infiltration capacity, such as tight silts or clays, where the infiltration rate is severely limited. Infiltration is also not recommended in locations where soils are contaminated, within sensitive drinking water recharge areas, where groundwater is shallow (less than three feet below the surface) or where karst features or bedrock are prominent. As part of its Clean Water Strategy, the City will conduct a desktop analysis to identify and prioritize locations where implementation of infiltration-based stormwater BMPs is feasible. Favorable locations would include areas where soil conditions are conducive and negative impacts are unlikely. The analysis may also include identification of areas where the potential for flood-risk can be reduced. These locations would then be prioritized based on an analysis of total construction and maintenance costs, availability of land, and infiltration benefits, including consideration of downstream water body. Prioritized locations could become part of the City’s future BMP implementation program. Land Availability Given that the City of Edina is essentially fully developed, the availability of land for implementation of stormwater management practices is limited. Installing stormwater BMPs in city-owned right-of-way is often challenging due to limited space and conflicts with existing utilities and infrastructure. Beyond the right-of-way, the primary city-owned land consists of parkland. While implementation of stormwater BMPs in the City’s parks can be cost effective, the parkland within the City is in high demand, with an ever increasing demand for programmed athletic fields, which severely limits the availability of land for stormwater management practices. There may be opportunities to retrofit stormwater BMPs on existing privately-owned sites; however, parking requirements or demand can severely restrict the available land for stormwater BMPs. As redevelopment occurs throughout the city, there is significant opportunity to implement site-based or regional stormwater management practices. However, development densities appear to be generally increasing, and parking requirements and other site constraints are limiting the feasibility of implementing above-ground stormwater management practices. Given the limited availability of land for installing conventional, above-ground stormwater BMPs, many private landowners and water managers are pursuing underground BMPs that can be installed within right-of-way and/or parking areas. While these BMPs are desirable to many because they allow for co- exist with other site uses, the cost for underground stormwater practices is higher than above ground. There is also concern about the maintenance costs and feasibility of the underground systems. Co-benefits of BMPs The City’s Clean Water Strategy will also consider achievement of additional “co-benefits”, such as flood risk reduction, recharge of shallow groundwater aquifers, wildlife habitat improvement, and groundwater conservation. City of Edina 2018 Comprehensive Water Resources Management Plan 15-30 Reuse Studies can evaluate effective ways of reusing rainwater, stormwater, greywater, wastewater, and industrial water. Reuse is important because it helps the City achieve its stormwater management goals, conserve water, meet permit requirements, develop sustainable water supplies, reduce costs, and improves the City’s triple bottom line. Identifying water reuse opportunities often begins by asking the following questions: • Who uses water? • Where is there a lot of water? • Where is there a high water demand? • What is the quality of available water? • What level of water quality is needed to meet the end user’s needs? • Is reuse technically feasible? Qualitatively feasible? The City will conduct a desktop analysis to identify and prioritize locations where stormwater reuse systems could be implemented Table 15.1. A geographic information system (GIS) screening-level analysis could be performed to identify potential reuse opportunities within the City—matching water sources to water needs. For example, both water sources and water users can be identified by mapping publicly available data (e.g., NPDES discharge permit data and appropriations permit data, respectively). GIS can also help identify potential sources of water in close proximity to potential users (including parks and golf courses that need water for irrigation). Other potentially useful data includes soils data (permeability, salinity), topography, storm sewer and sanitary sewer data, utilities data (gas/communication/power utilities), groundwater data, water supply well data, and water sales data. 15.3 Stormwater Infrastructure Infrastructure for flooding and drainage as well as for clean water are discussed in this section together because of the overlapping services that some components of the system provide. Components of these systems may be publicly or privately owned. Runoff management and flood protection infrastructure generally includes pipes, inlets, ponds, lift stations, natural water bodies and outlet controls, temporary inundation areas, and local and regional flood storage areas, among others. Runoff management and flood protection infrastructure also includes sump drains (providing a dual purpose with the sanitary sewer infiltration and inflow program), and curb and gutter (providing dual purpose with erosion sediment control and road maintenance),, among others. Clean water infrastructure generally includes underground hydrodynamic separators (also termed grit chambers), sump manholes, ponds, underground storage and infiltration facilities, and bioretention basins, among others. City of Edina 2018 Comprehensive Water Resources Management Plan 15-31 15.3.1 Operation and Maintenance of Stormwater Systems The stormwater system includes not only pipes and constructed ponds, but also lakes, wetlands, ditches, swales, and other drainage ways. In addition to more typical maintenance measures, maintenance of the stormwater system may also mean maintaining or restoring the ecological characteristics of the natural portions of the stormwater system. The City of Edina recognizes that maintenance of all of the City’s stormwater facilities is an important part of stormwater management. Proper maintenance will ensure that the stormwater system provides the necessary flood control and water quality treatment. 15.3.1.1 Private Stormwater Facilities Owners of private stormwater facilities are responsible for maintaining the facilities in proper condition, consistent with the original performance design standards. Responsibilities include removal and proper disposal of all settled materials from ponds, sumps, grit chambers, and other devices, including settled solids. There is a need for a program to ensure private stormwater facilities are properly maintained so that they continue to provide the intended level of flooding, drainage, and clean water services. This policy gap is described further in Section 15.4.7. 15.3.1.2 Publicly Owned Stormwater Facilities The City of Edina is responsible for performing the maintenance of the stormwater facilities under City ownership. Average facility condition and performance is currently unknown, and there is an unknown liability of deferred maintenance. The City will also notify the owners of other publicly owned stormwater facilities if scheduled maintenance is needed according to periodic site inspections or maintenance plans on file. The Minnesota Department of Transportation is responsible for maintaining road ditches, storm sewer, and culverts along U.S. Highway 169, State Highway 100, and State Highway 62. Hennepin County is responsible for maintaining right-of-way, storm sewer, and culverts along CR 17 (France Avenue), CR 31 (York Avenue), CR 158 (Vernon Avenue), and CR 20 (Interlachen Boulevard). The City will develop an inventory and maintain a database for all private and public stormwater facilities within the City of Edina to assist in determining maintenance requirements. The City will regularly inspect and maintain key components of the public system, including storm sewer and culvert inlets, overflow drainage swales, stormwater ponding and water quality treatment basins, and riprap-protected banks, storm sewer, and culvert outlets. 15.3.1.3 Maintenance of Storm Sewer and Culvert Inlets For safety reasons and to prevent pipe plugging, trash racks are typically installed on storm sewer and culvert inlets. These trash racks prevent people from entering the pipes and keep large debris from becoming lodged in the pipes. If not inspected and maintained, the trash racks will become plugged with debris such as branches, leaves, and other materials carried by storm flows. Even if partially plugged, additional flooding can occur. The City recognizes the importance of, and performs, periodic removal of collected debris from system trash racks, catchbasins, and inlets. City of Edina 2018 Comprehensive Water Resources Management Plan 15-32 15.3.1.4 Maintenance of Ponding Facilities Stormwater ponding and water quality treatment facilities perform a desirable function by settling sediment out of the stormwater. However, if accumulated sediments are not periodically removed, such basins can experience a significant loss in necessary stormwater detention capacity and sediment storage volume. Also, if left unattended, these facilities can become overgrown with unwanted vegetation that could reduce their effectiveness and hinder access for periodic maintenance. The City of Edina periodically inspects stormwater storage basins and water quality treatment facilities to look for excessive sediment build-up, collected debris, and unwanted vegetation. If problems are noted, maintenance is then warranted. For sedimentation basins, if 25% of the sediment storage volume is filled with sediment, the basin should be dredged to provide its originally designed sediment storage volume. Overflow swales can turn into steep eroding channels if an ongoing erosion problem is not stabilized and the area restored. Typical stabilization materials could include permanent geotextile erosion-control material or riprap accompanied by a properly designed filter material. Erosion problems are identified and addressed by the City’s maintenance program. In general, vegetation in existing ponding facilities should be allowed to grow naturally on the side slopes of the basin and should not be mowed. This practice will allow ponding facilities to act like natural wetland areas by providing nearby upland wildlife habitat. 15.3.1.5 Riprap and Filter Areas Riprap and filter areas along banks, in overflow swales, or around storm sewer or culvert outlets, need periodic maintenance. Riprap is placed in those locations to prevent damage that would result from highly erosive flow velocities. If not periodically maintained, significant erosion will occur resulting in pipe damage, downstream sediment problems, and potential safety issues. The City will annually inspect riprap areas and perform the necessary maintenance. 15.3.1.6 Adequacy of the Maintenance Program The City of Edina is responsible for maintaining its stormwater system including storm sewer pipes, ponds, pond inlets and outlets, and channels. The City will continue and expand upon its operation and maintenance activities to ensure its systems function as designed. The City’s operation and maintenance program is closely tied with the City’s implementation of its NPDES Phase II MS4 Permit. The City’s operation and maintenance program is incorporated in the implementation program. 15.4 Management Approach The City will actively apply the water resources management policies and implement the programs and projects identified in this Comprehensive Water Resources Management Plan by: • Applying the policies and Plan to all clean water and flood improvements, including those involving operations, maintenance, improvements, and qualifying private development/redevelopment. City of Edina 2018 Comprehensive Water Resources Management Plan 15-33 • Leveraging all sources of clean water funding and actively pursuing grants, cost-sharing opportunities, project partnerships and other new or special funding sources as applicable. • Drawing on technical support and feedback from partner agencies, organizations, and groups. • Embracing a systems approach to solve water resources problems; considering multiple uses, sources, and waste streams of water. • Advocating for water resources strategies consistent with this plan when a local land use decision is under the jurisdiction of another agency. • Adapting to new knowledge and challenges, using the best science to guide decision-making. • Coordinating efforts with supporting plans and programs; o Current Edina Comprehensive Plan o Living Streets Plan o Source Water Protection Plan o Wellhead Protection Plan o Stormwater Pollution Prevention Plan and Municipal Separate Storm Sewer System (MS4) permit o Nine Mile Creek Watershed District Water Management Plan o Minnehaha Creek Watershed District Water Management Plan o Minnehaha Creek Watershed District’s ‘Guide: Community Adaptation Planning for Changing Landscapes and Climate’ o Hennepin County’s Natural Resources Strategic Plan o Residential and commercial permitting Beyond prioritizing and allocating resources to accomplish the minimum standard as required by the City’s MS4 permit and SWPPP, this plan aims to prioritize projects and budgets to meet defined levels of service, where achievable. The Clean Water Strategy and Flood Risk Reduction Strategy identified in this plan will set out specific goals, priorities, and associated costs to better describe the investment needed for the City to achieve its defined level of service. The rate of progress in meeting the desired level of service will be determined by resources, funding, opportunities, and policy alignment. 15.4.1 Coordination with Watershed Districts 15.4.1.1 Regulation The City of Edina manages stormwater to protect life, property, waterbodies within the city, and receiving waters outside the city. However, the City relies heavily on the NMCWD and MCWD for implementation of water resource protection rules and requirements. The City defers LGU authority to the NMCWD and MCWD for floodplain management and drainage alterations, wetlands management, stormwater management, erosion and sediment control, waterbody crossings and structures, shoreline and streambank improvements, and sediment removal. The City of Edina also defers LGU authority for the WCA to the NMCWD and MCWD. This includes requiring and verifying that all projects impacting wetlands meet the requirements of the Minnesota WCA. City of Edina 2018 Comprehensive Water Resources Management Plan 15-34 The Board of Water and Soil Resources serves as both a state administrator of the programs associated with the WCA, as well as providing technical assistance to LGUs administering the WCA. 15.4.1.2 Data and Information The MCWD and NMCWD collect and maintain numerous regional data collections and models that are made available for use by the City of Edina. Below is a list of data and models available from one or both of the watershed districts and a brief description of how the City has or will utilize these resources. Hydrology and hydraulics (H&H) model – provides information on regional flood elevations and hydraulics. The City has used the NMCWD Atlas 14 H&H model to evaluate impacts from proposed drainage modifications and as a base for the 2017 Atlas 14 model updates completed to support this CWRMP. The City used the MCWD H&H model for estimating Atlas 14 tailwater conditions in Minnehaha Creek for the City’s 2017 Atlas 14 model updates conducted to support this CWRMP (see Appendix B). Atlas 14 Flood Elevations– provide information on base flood elevations for development and redevelopment. The City relies on the NMCWD and MCWD to provide 1-percent-annual-chance flood elevations for Regional Flood Areas throughout the city. While the MCWD has not yet published Atlas 14 flood elevations for Minnehaha Creek, the City of Edina looks forward to utilizing these values when available to consistently provide flood protection based on Atlas 14 precipitation frequency estimates citywide. MCWD Functional Assessment of Wetlands (FAW) – provides data on wetland functions and values, establishes management classifications based on quality and sensitivity, and identifies restoration opportunities for wetlands within the Minnehaha Creek watershed (Hennepin Conservation District, 2003). The City incorporated the results of the FAW into its 2011 and 2018 CWRMP (see Section 16.2). Stream Assessments – provide data on biological and physical condition of streams. The NMCWD collects benthic macroinvertebrate and fish samples annually from the North Fork of Nine Mile Creek near Metro Boulevard in Edina and conducts periodic physical condition assessments. This information has been used to identify changes in stream water quality that may be caused by nonpoint source pollution and provide a more complete understanding of overall stream health. Specifically, the data was used to complete the Nine Mile Creek biological stressor identification study (MPCA, 2010) and design the Edina Streambank Restoration project being constructed by NMCWD in 2017-2018. The MCWD has conducted limited periodic biological monitoring of Minnehaha Creek (e.g., Zebra Mussel monitoring, fishery survey) and project-specific physical condition assessments within Edina. Hydrologic and Water Quality Data Reports – provide data on water quality, water quantity, and ecological integrity conditions and trends for District resources. The NMCWD and MCWD collect and analyze hydrologic (stream flows, lake levels) and water quality data at numerous locations within Edina, including Minnehaha Creek (downstream of the Browndale Dam), North Fork of Nine Mile Creek (at Metro Boulevard), and numerous lakes. This information is used by the City to track water quality conditions and trends and identify the need for additional lake and watershed management. City of Edina 2018 Comprehensive Water Resources Management Plan 15-35 Educational Resources – provide education and outreach information regarding water resources best management practices. The City has utilized the information and trainings offered by the MCWD and NMCWD to support and bolster their education program. 15.4.1.3 Land Use Planning Opportunities The MCWD Watershed Management Plan (2018) and NMCWD Water Management Plan (2017) both highlight the desire to more closely integrate land use planning and water resource management to capitalize on opportunities to improve water resources as development and redevelopment occurs. Given that land use planning lies primarily with the cities, achievement of this goal will require close coordination and partnership between the watershed districts (WDs) and cities. Coordination Plan To achieve the level of coordination and communication required to successfully capitalize on opportunities to improve water resources as part of land use planning, the city will strive to conduct the following activities: • Participate in an annual meeting to review water resource plan implementation, to be coordinated by the WDs. Parties will discuss how the WDs can receive notice of and consult on land use, infrastructure, park and recreation, and capital improvement planning efforts. • Transmit the annual NPDES MS4 report to WDs (mutual transmittal, if applicable) • Notify the WDs of the following: • Updates to road and infrastructure implementation programs. The City annually produces a map of anticipated road reconstruction and road maintenance projects for the next five years. • Updates to park and recreation plans. • Institution and completion of small area plans and other focused development or redevelopment actions. • Significant alterations within the City MS4 system (to maintain currency of the WD watershed-wide hydrology and hydraulics model). • Updates to the Capital Improvement Plan. • Partnership or coordination as to public communications and education. The WDs are asked to complete the following activities: • District notice to the City regarding watershed management plan amendments and annual capital improvement program updates. To capture CIP and budget planning, the annual meeting should occur early in the second quarter. The annual meeting will involve the City’s Community Development Director, Economic Development Manager, Engineering Director, Engineering Services Manager, and Water Resources Coordinator. The City welcomes and will accommodate requests from the WDs for additional meetings and communications that spur from the annual meeting. For elements the City and WDs identify for coordination, specific City of Edina 2018 Comprehensive Water Resources Management Plan 15-36 communication plans and schedules will be made. The Water Resources Coordinator will facilitate communication among appropriate parties based on the scope of the item. Conversations around water resources planning occur continuously throughout the year and are guided by this plan. It is common for various stakeholders across the community (public agencies, non-profit organizations, citizen groups, city departments, and private entities) to be involved in work that has prominent or nuanced water resources implications. Some of the challenges of coordinating water resources planning include the number of stakeholders involved, balancing funding priorities, community attitudes, and the fact that plans and projects are often owned by others (and may have different schedules, values, and service targets). Due to the dynamic nature of various concurrent activities and planning efforts, maps of anticipated road reconstruction, potential park improvements, capital infrastructure investment/reinvestment, priority water resources issues, and private development are not provided here, but will be prepared ahead of each annual meeting. Spatial analysis tools allow for these pieces of information to be integrated annually, efficiently incorporating the best available information. The City and WDs have a history of partnership. The past successes have largely been the result of strong working relationships that promote regular conversations. The City is eager to continue and expand cooperative work in the following areas: • CIP and budget planning: The City’s process for this is described in more detail in section 15.4.3. Internal review begins in second quarter, drafts are available for comment in third quarter, and City Council takes action in December of each year. • Private development and redevelopment: It’s common for large projects to go through a sketch plan review with City Council. The City will share known upcoming projects at the annual meeting. As WD staff develop relationships with the community and economic development staff at the City, they can regularly and informally check in with the City to stay abreast of private development and redevelopment activity. The City will facilitate a coordination meeting with private developers and the WDs at the request of the WDs. For projects that do not go through a sketch plan review, the City will inform permit applicants of the potential need for a WD permit and, when one is required, will not issue a City permit until the WD permit application has been made. • Public development and redevelopment: Described in more detail in section 15.4.1.4. Because of our strong working relationship with the WDs, the City is continually seeking opportunities for coordination. This occurs through informal conversations as opportunities arise. Any future efforts including small area plans or other planning activity will be shared at the annual meeting. • Operation and maintenance: The City will inform the WDs of illicit discharges in a timely manner and share a summary of the illicit discharge detection and elimination program at each annual meeting. Additionally, the City will share its MS4 inspection results at each annual meeting. • Regulatory enforcement: As described in 15.4.1.1. • Education and engagement: As described in 15.4.1.2., the City will share its education and engagement calendar at each annual meeting. The City asks the WDs to continue to cross- promote and partner on events. City of Edina 2018 Comprehensive Water Resources Management Plan 15-37 In 2014, the City and Minnehaha Creek Watershed District initiated a Memorandum of Understanding (MOU) to describe the common goal of clean water among the agencies and outline spheres of collaboration in a number of areas including public education and outreach, development oversight, integrated capital improvements, and planning coordination. A copy of the MOU is available in the City’s Water Resources Library. 15.4.1.4 Implementation Partnership Opportunities The City will work closely with the NMCWD and MCWD to identify and implement water resource protection or improvement partnership projects. While some opportunities may be associated with development and redevelopment, other opportunities will be focused on land owned by the City. Figure 15.1 shows the city-owned parcels throughout the city. Upcoming opportunities for water resource management or improvement partnerships associated with City-owned park and property redevelopment include: Minnehaha Creek Watershed • Arden Park: Clean water and drainage issues, civic engagement • Weber Park: Flooding issues (and clean water co-benefits opportunity), civic engagement • Grandview Green: Stormwater management, regional planning, permitting, civic engagement Nine Mile Creek Watershed • Pentagon Park: Flooding issues (and clean water co-benefits opportunity), rule administration planning, civic engagement • Lake Cornelia: Clean water and flooding issues, civic engagement • Lake Edina: Clean water and flooding issues, civic engagement This CWRMP lays out a framework for working toward incremental improvement in water resource issues through the Flood Risk Reduction Strategy and Clean Water Strategy. At the time of this plan’s writing, the focus area for the Flood Risk Reduction Strategy is the Morningside neighborhood in the Minnehaha Creek Watershed District and the focus area for the Clean Water Strategy is Lake Cornelia in the Nine Mile Creek Watershed District. The City invites the watershed districts to be involved in the development of these strategies for each of these focus areas. 15.4.2 Development Review Process and Land Use Planning The City utilizes its Development Review process to address stormwater management and ensure water resource protection within the City. Engineering staff review development and redevelopment proposals to ensure that the stormwater management policies and standards detailed in Section 3.0 of this plan are met. Engineering staff also consult the City’s Wellhead Protection Plan to ensure that development and redevelopment proposals are in line with the protective measures established for the City’s sensitive groundwater resources. City of Edina 2018 Comprehensive Water Resources Management Plan 15-38 Staff from the City’s planning department review development and redevelopment proposals with the guidance of the City's long-range Comprehensive Plan and Zoning Ordinance. In addition to incorporating the policies and design standards of this CWRMP, the Edina Comprehensive Plan (City of Edina, 2008) includes policies, principles, and guidelines that integrate water resources protection and management with land use planning. Among these include the City’s land use policy to “grow and develop in a sustainable manner that will protect its high quality natural environment, promote energy efficiency and conservation of natural resources” and to “maintain the current open space and wetlands acreage and seek to expand it whenever possible”. The Comprehensive Plan encourages reductions in impervious surfaces and associated stormwater runoff from redevelopment sites and parking lot design that promotes stormwater infiltration, and also encourages protection and improvement of urban forests, which provides stormwater management benefits, among others. Additionally, the Edina Comprehensive Plan includes procedures for planning, programming, and implementing transportation infrastructure, sewer and water infrastructure, and park, recreation, and natural area management. These plans coincide with the timing of the local comprehensive planning timeline and support the Transportation, Water Resources, and Parks & Trails elements of the comprehensive plan. The City’s zoning ordinance is used by staff in the planning department to guide development and redevelopment within the city. The zoning ordinance establishes required setbacks from naturally occurring lakes, ponds, and streams. In some cases, the buffer requirements of the watershed districts may be more stringent, upon which the watershed district requirements supersede. The City’s zoning ordinance also addresses development within the floodplain districts of the city. Small Area Plans outline a long-range vision for land use and development in a very specific area of the City based on input from residents and business representatives. A list of completed and upcoming Small Area Plans is available on the City’s website, www.EdinaMN.gov/657/Small-Area-Plans. The city of Edina is basically fully developed; thus land alteration activities are primarily of a redevelopment nature. As the city redevelops, the City utilizes the policies of the Edina Comprehensive Plan, the zoning ordinance, and this CWRMP to encourage low-impact site design. The City also relies on implementation of the rules and regulations of the NMCWD and MCWD. 15.4.3 Prioritization Prioritization of projects occurs within the City’s Capital Improvement Program and budget and is determined by the City Council with guidance from Staff and the Comprehensive Water Resources Management Plan policies and implementation activities. Top priority projects will be those that: • Have measurable, long term improvements to water quality, especially for waterbodies that are on the 303(d) Federal List of Impaired Waters or have data suggesting that the resource is not meeting clean water goals. City of Edina 2018 Comprehensive Water Resources Management Plan 15-39 • Measurably reduce risks of flooding. • Combine clean water and flood resiliency benefits. • Solve drainage problems and reduce risk or consequence of flood, while maintaining or improving water quality. • Provide the most service for the least cost. The City’s Capital Improvement Program is a five-year plan for capital improvements that is updated annually. The CIP process includes analyzing projects contributing to public health and welfare, projects helping to maintain and improve the efficiency of the existing systems, and projects that define a future need within the community. The City implemented a two-year budget cycle process which takes an alternating year approach to the operating budget and CIP processes. While both the operating budget and CIP are reviewed every year, the majority of the planning, focus and effort will alternate between the two. During even-numbered years, the City’s focus will be on the CIP. Extra efforts are dedicated to reviewing the projects in the CIP and prioritizing them based on information available at the time. The operating budget is reviewed but only updated if necessary. During odd-numbered years, the City’s focus will be on the operating budget. Extra efforts are dedicated to citizen engagement processes and a two-year operating budget. The CIP is reviewed but only updated if necessary. During 2018, the City will develop the 2019-2023 CIP, with opportunities for public review and comment. City Council formally adopts a CIP near the end of every even-numbered year. A copy of the most current Capital Improvement Plan is available on the City’s website at http://www.edinamn.gov/273/Finance. 15.4.4 Resources The resources available to implement the Comprehensive Water Resources Management Plan include: • City staff and equipment. • Partnerships that leverage technical assistance, funding, and accomplish multiple overlapping goals. • Coordination of project planning and implementation across City departments and with private development and redevelopment. • Investments in stormwater management by others, driven by regulatory demand. 15.4.5 Financial Considerations Implementation of the proposed regulatory controls, programs and improvements that are identified in the plan will have a financial impact on the City. To establish how significant this impact will be, a review of the means and ability of the City to fund these controls, programs, and improvements is necessary. Table 15.5 lists potential sources of revenue for implementation of the water resources management efforts outlined in this plan. City of Edina 2018 Comprehensive Water Resources Management Plan 15-40 Table 15.5 Potential Funding Sources for Plan Implementation Description of Funding Sources Revenue Generated 1. Revenue generated by City’s Stormwater Utility.$1,800,000/yr 2. Special assessments for local improvements made under the authority granted by Minnesota Statutes Chapter 429. Variable depending on activities undertaken 3.Revenue generated by the Watershed Management Special Tax Districts provided for under Minnesota Statutes Chapter 473.882. Variable depending on activities undertaken 4.For projects being completed by or in cooperation with NMCWD and MCWD, project funds could be obtained from watershed district levies associated with their administrative funds, construction funds, preliminary funds, repair and maintenance funds or survey and data acquisition funds, as provided for in Minnesota Statutes Chapter 103D.905. Variable depending on activities undertaken 5. Grant monies that may be secured from various local, regional, County, State, or Federal agencies. This would include MnDOT, MPCA, Metropolitan Council, the MnDNR, and others. Variable depending on activities undertaken 6.Other Sources: These may be other sources of funding for stormwater activities such as tax increment financing, state aid, etc. The City will continue to explore additional revenue sources as they become available. Variable 7. Tax abatement. 15.4.6 Utility funding The stormwater utility fund was created to manage storm water runoff quality in concert with the local watershed. City projects often include repair and maintenance of drainage systems, stormwater ponds, and outlets structures. Single family residential properties pay a fixed quarterly fee. Commercial property owners are charged based on the amount of impervious surface that does not allow rainwater to be absorbed into the ground. Over time, capital costs for the storm water system have increased to meet state standards intended to improve water quality. To date, the stormwater utility has been able to keep up with improvements mandated by the state; however, complying with the minimum standard hasn’t enabled the City to reach clean water goals and sets out a timeline for accomplishing the goals that is far from reach. In order to see measurable improvements in flood protection, drainage, and clean water services, the City will need to begin to plan financially for significant improvements to the system, beyond the minimum standard for annual operations and maintenance. As the City and Watershed Districts continue to evaluate and develop plans City of Edina 2018 Comprehensive Water Resources Management Plan 15-41 for polluted waterways, there will be pressure to generate more revenue to fund stormwater management systems. 15.4.7 Policy Issues Solving flooding, drainage, and clean water issues in the City will require a variety of tools, practices, and partners. Various agencies are involved with flooding and clean water services or constrain or are affected by the provision of these services. Coordinating policies among various stakeholders including watershed districts, MPCA, DNR, city departments, and others will make delivery of these services more achievable. Some remaining policy issues that have been identified include: •A need to understand the pace of progress and the investment needed to solve flooding, drainage, and clean water issues. Statewide there have been small moves in solving these problems. Technical obstacles (such as which practices are the most efficient, how to implement them, assurances that they are working as intended), as well as political obstacles (such as how much the city or other agencies are willing to invest and on what timeline) remains to be determined. •Alignment of the watershed district’s monitoring programs to include in-lake and BMP level monitoring necessary to confirm designed outcomes, set goals for pollution reduction, and prioritize future implementation. •A need to plan surface water outcomes in public infrastructure topics. Elevating the focus of flooding, drainage, and clean water issues in improvement projects as well as regular operation and maintenance. This should be driven by a defined service level. •Development of a program for inspection and maintenance of private stormwater BMPs. The City will engage with the watershed districts to determine if a cooperative framework where the City inspects private stormwater BMPS and the watershed districts enforce their maintenance agreements is feasible. •Aging infrastructure and deferred maintenance trends represent liability that stresses existing budgets. While much of the vast network of catchbasins, ponds, outlets, and other stormwater infrastructure on both the public and private side are made of durable materials and have long design lives, they do require maintenance and will require reinvestment to continue to provide service. •Land use policies are connected to local flood risk. Increasing impervious cover and an already overtaxed public system make it difficult to keep up with local flood issues. •Flooding, drainage, and clean water services often compete for resources. The public demand for each service varies greatly. Without defined service levels, resources are often allocated to solve drainage issues or small flood issues while larger flood issues and clean water issues remain City of Edina 2018 Comprehensive Water Resources Management Plan 15-42 unresolved. An example of this is the public demand for pumping of lakes and ponds to manage water levels. Defining the levels of each service is necessary to make progress toward goals. • A need to build an understanding of flooding, drainage, and clean water issues among city departments to better incorporate water resources planning into city operations (parks, neighborhood roadway reconstruction, planning, economic development, permitting and development review). City staff will continue to work with its decision-makers and partners to resolve these issues and/or conflicts, where possible. However, many of these remaining issues are challenging problems that may take significant time and effort to address. 15.5 Plan Update and Amendment Procedure It is the intention of the City to have this CWRMP reviewed and approved by the NMCWD and MCWD. Once approved, no significant changes to this plan can be made without the approval of the proposed revisions by the watershed districts within the City that are affected by the change. Significant changes to the local plan shall be made known to the following parties: • City Manager, Director of Public Works, and City Engineer • Affected Watershed District within the City • Metropolitan Council • City Council Following notification of the above parties, they shall have 60 days to comment on the proposed revisions. Failure to respond within 60 days constitutes approval. Upon receipt of approvals from the affected watershed districts within the City, any proposed amendments will be considered approved. Minor changes to the Plan shall be defined as changes that do not modify the goals, policies, or commitments expressly defined in this plan by the City. Adjustment to subwatershed boundaries will be considered minor changes provided that the change will have no significant impact on the rate or quality in which stormwater runoff is discharged from the City boundaries. Minor changes to this plan can be made by the staff at the City without outside review. This CWRMP will guide the City of Edina’s activities through 2028 or until superseded by adoption and approval of a subsequent CWRMP. Amendments to the CWRMP will be completed in accordance with MCWD and NMCWD watershed plans, consistent with 8410.0160. No rth B ranchNineMileCreek SouthBranc h N i ne Mile C r eekMud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes M inne h a h a Cre e k£¤169 100 62 100 456717 456731 4567158 456731 Braemar Park (Courtney Fields) Bredesen Park Rosland Park Lewis Park Pamela Park Highlands Park Walnut Ridge Park T. Lea Todd Park Open Space 1 Heights Park Garden Park Heights Park Lincoln Drive Floodplain Van Valkenburg Park Fred Richards Golf Course Arden Park Krahl Hill Creek Valley School Park Lake Edina Park Normandale Park Weber Field Park Arneson Acres Park Countryside Park Weber Woods Centennial Lakes Park Open Space 2 Open Space 3 Centennial Lakes Park Alden Park Utley Park Open Space 2 Moore Property Pamela Park Open Space 2 York Park Yorktown Park Centennial Lakes Park Cornelia School Park Wooddale Park Strachauer Park Garden Park Open Space 5 Fox Meadow Park Kojetin Park Edinborough Park Arden Park Garden Park McGuire Park Fox Meadow Park Birchcrest Park Sherwood Park Garden Park Addition Melody Lake Park Weber Field Park Chowen Park Open Space 2 Centennial Lakes Park St. John's Park Tingdale Park York Park Browndale Park York Park Frank Tupa Park Grandview Square Open Space 6 York Park MinneapolisMinneapolis HopkinsHopkins RichfieldRichfieldEden PrairieEden Prairie MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park BloomingtonBloomington Barr Footer: ArcGIS 10.6, 2018-05-22 11:14 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_15_1_City_Owned_Property.mxd User: smsCITY-OWNED PROPERTYComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 15.1 0 3,000 Feet !;N City-Owned Property Park/Recreational Area Streets and Highways Creek/Stream Lake/Pond City of Edina Boundary Imagery Source: MnGeo, 2016 City of Edina 2018 Comprehensive Water Resources Management Plan 16-1 16.0 Wetlands The wetlands in the City of Edina are an important community asset. These resources supply aesthetic and recreational benefits, in addition to providing wildlife habitat and refuge. To protect the wetlands in the City of Edina, a goal of no net loss of wetland functions and values has been adopted. To provide a basis for wetland protection efforts, a planning-level inventory and field assessment of all the wetlands within the City was completed in 1999. The wetland inventory identified wetland location, approximate size, type, wetland classification, dominant wetland vegetation, function, and value. In 2003, the MCWD developed a Functional Assessment of Wetlands (FAW) to provide a comprehensive inventory and assessment of existing wetland functions within the district. The City adopts the MCWD FAW for portions of the City within the Minnehaha Creek Watershed. Figure 16.1 depicts the wetlands that were identified and assessed as part of these two wetland inventories, which are discussed in further detail in subsequent sections. Note that the wetlands identified within the MCWD are based on the 2003 FAW, and the remainder are based on the City’s 1999 planning-level inventory. As projects that could impact wetlands arise, the City will complete updated assessments as needed and in cooperation with watershed districts, pursuant to Section 3.5.1 Wetlands Policies. 16.1 City of Edina Wetlands Inventory—1999 In order to compile detailed wetland data and assess the functions for hundreds of wetlands based on a short field visit to each wetland, a wetland assessment methodology was needed to allow for rapid assessment of wetlands while maximizing the integrity and value of the data. The most common wetland assessment methodology used in Minnesota has been the Minnesota Routine Assessment Method for Evaluating Wetland Functions commonly referred to as "MnRAM." A modified version of MnRAM 2.0 was used for the wetland inventory in the City of Edina, which was completed in 1999. A copy of the modified version of MnRAM 2.0 is included in Appendix F. Copies of the modified MnRAM field data sheets for each wetland have been compiled into a Wetlands Field Investigation document. The results of the wetlands inventory and assessment are provided in a GIS wetlands inventory database, included as Appendix G. 16.1.1 Delineation During the summer of 1999, a wetland inventory was conducted within the City of Edina. The inventory consisted of field inspecting each wetland in the City and mapping the approximate wetland boundary in general accordance with the routine determination method as specified in the U.S. Army Corps of Engineers Wetlands Delineation Manual, 1987. Existing wetland maps (MnDNR Protected Waters and Wetlands maps and National Wetland Inventory [NWI] maps), SCS soil survey maps, and aerial photographs were used as baseline information to assist in the identification of wetland areas. Additionally, USFWS Cowardin and Circular 39 classifications were assigned to each wetland during field inspections. City of Edina 2018 Comprehensive Water Resources Management Plan 16-2 16.1.2 Dominant Vegetation The dominant vegetation within each wetland was characterized during the field inspection process using the modified version of MnRAM 2.0. For each wetland, the percent of the site occupied by the various vegetation communities for each stratum (open water, floating leafed community, emergent community, herbaceous community, shrub community, and tree community) were recorded, along with the dominant species present for each stratum. Where invasive and exotic species were encountered, the species and the percent areal coverage were also recorded. In addition, the plant community types and quality level were noted for each wetland. 16.1.3 Wetland Functional Assessment The modified version of MnRAM 2.0 used for the wetland inventory in the City of Edina included a list of questions for a number of assessment categories. Those questions all measure some unique characteristic of the wetland. Each wetland functional rating was determined loosely based on the user guidance provided for each function in MnRAM 2.0. The modified version of MnRAM 2.0 assesses the wetland functions and values described below. 16.1.3.1 Hydrology A wetland’s hydrologic regime or hydroperiod is the seasonal pattern of the wetland water level which is like a hydrologic signature of each wetland type. It defines the rise and fall of a wetland’s surface and subsurface water. The constancy of the seasonal patterns from year to year ensures a reasonable stability for the wetland (Mitsch and Gosselink, 2000). The ability of the wetland to maintain a hydrologic regime characteristic of the wetland type is dependent upon wetland soil and vegetation characteristics, land use within the wetland, land use within the upland watershed contributing to the wetland, and wetland inlet/outlet configuration. Maintenance of the hydrologic regime is important for maintaining a characteristic vegetative community, and is closely associated with other functions including flood attenuation, water quality and groundwater interaction. The hydrology of each wetland was rated subjectively based on the extent of hydrologic alteration. This evaluation focused primarily on the presence or absence of directed stormwater, outlets, and ditching along with upland watershed characteristics. 16.1.3.2 Vegetative Diversity The vegetative diversity rating is based primarily on the diversity of vegetation within the wetland in comparison to an undisturbed condition for that wetland type. The vegetative diversity value of each wetland was assessed and rated based loosely on the ratings in MnRAM 2.0 with additional emphasis placed on invasive species and multiple communities and vegetative strata. The results of this assessment are included in the GIS wetlands inventory database. An exceptional rating typically reflects one of the following conditions: (1) highly diverse wetlands with virtually no non-native species, (2) rare or critically impaired wetland communities in the watershed, or (3) the presence or previous siting of rare, threatened, or endangered plant species. A high rating indicates the presence of diverse, native wetland species and a City of Edina 2018 Comprehensive Water Resources Management Plan 16-3 lack of non-native or invasive species. Wetlands that rate low are primarily dominated by non-native and/or invasive species. 16.1.3.3 Wildlife Habitat The ability of a wetland to support various wildlife species is difficult to determine due to the specific requirements of the many potential wildlife species that utilize wetlands. This function determines the value of a wetland for wildlife in a more general sense, and not based on any specific species. The characteristics evaluated to determine the wildlife habitat function include: surrounding land use conditions, the interspersion of wetlands in the area, barriers to wildlife movement, rare wetland types, special habitats, and the presence of rare or listed species. 16.1.3.4 Fishery Habitat The ability of the wetland to support fisheries is determined based on the hydrologic connectivity to a native game fishery. Wetlands without a direct hydrologic connection to a waterbody supporting fish are determined to not provide this function. Wetlands rated high are lacustrine or riverine and provide spawning/nursery habitat, or refuge for native game fish. Wetlands rated medium may support native minnow populations but not native gamefish. Low quality wetlands include those with an intermittent hydrologic connection to a waterbody with a native fishery. 16.1.3.5 Flood/Stormwater Attenuation A wetland’s ability to provide flood storage and/or flood wave attenuation is dependent on many characteristics of the wetland and contributing watershed. Characteristics of the subwatershed that affect the wetlands ability to provide flood storage and attenuation include: soil types, land use and resulting stormwater runoff volume, sediment delivery from the subwatershed, and the abundance of wetlands and waterbodies in the subwatershed. Parameters used to assess the ability of the wetlands to provide flood storage and/or flood wave attenuation included: flood/stormwater management levels; presence and connectivity of channels; and most importantly outlet configuration. 16.1.3.6 Water Quality Protection This assessment rates the wetland’s ability and opportunity to improve water quality. The level of functioning is determined based on runoff characteristics, wetland configuration, vegetation, sedimentation processes, and nutrient cycling. Runoff characteristics that are evaluated include: land use in the upstream watershed, the stormwater delivery system to the wetland, sediment delivery characteristics, and the extent, condition, and width of upland buffer. The ability of the wetland to remove sediment from stormwater is determined by wetland configuration, emergent vegetation, and overland flow characteristics. Indicators that a wetland has been affected by nutrient loading include the presence of monotypic vegetation and/or algal blooms. 16.1.3.7 Shoreline Protection Shoreline protection is typically evaluated only for those wetlands adjacent to lakes, streams, or deep water habitats. The function is rated based on the wetlands opportunity and ability to protect the City of Edina 2018 Comprehensive Water Resources Management Plan 16-4 shoreline; i.e., wetlands located in areas frequently experiencing large waves and high currents have the best opportunity to protect the shore. In addition, shore areas with sandy soils and little vegetation or shallow-rooted vegetation will benefit the most from shoreline wetlands. The wetland width, vegetative cover, and resistance of the vegetation to erosive forces determine the wetland’s ability to protect the shoreline. This function is rated based on the potential for bank erosion due to wave action and characteristics of the bank along with the wetland vegetation characteristics. 16.1.3.8 Aesthetics/Recreation/Education and Science The aesthetics/recreation/education and science function and value of a wetland could be evaluated based on the wetland’s visibility, accessibility, evidence of recreational uses, evidence of human influences (e.g. noise and air pollution) and any known educational or cultural purposes. Accessibility of the wetland is key to its aesthetic or educational appreciation. While dependent on accessibility, a wetland's functional level could be evaluated by the view it provides observers. Distinct contrast between the wetland and surrounding upland may increase its perceived importance. Also, diversity of wetland types or vegetation communities may increase its functional level as compared to monotypic open water or vegetation. This wetland value was rated using best professional judgment based primarily on observable recreational uses and potential educational benefits. 16.1.4 Wetland Sensitivity to Stormwater Input Stormwater runoff carries soil particles, nutrients, and contaminants which can change the ecological balance of the receiving water body. Changes in the volume or rate of stormwater entering or discharging from the water body can also change the ecological balance. Change in the ecological balance of a wetland often results in changes in the water quality, changes in animal and fish habitat, replacement of native vegetation with invasive and tolerant plant species, and/or other impacts to the wetland’s functions and values. The state guidance document (State of Minnesota, Stormwater Advisory Group, June 1997) developed a classification for determining the susceptibility of wetlands to degradation by stormwater input. This classification relates wetland type to a rating of susceptibility as shown in Table 16.1. Wetlands such as bogs and fens can be easily degraded by changes in the stormwater inflows and are designated as highly susceptible. On the other hand, floodplain forests can tolerate relatively significant changes in the chemical and physical characteristics of stormwater inflow without degradation and are therefore slightly susceptible. Commonly observed shallow marshes and wet meadows dominated by cattail and reed canary grass (respectively) have a moderate susceptibility to stormwater fluctuations. Field notes recorded during the wetland delineations were used to determine the wetland susceptibility classification for each wetland. The susceptibility of each wetland to degradation by stormwater input was assessed and categorized as high, moderate, or least susceptible. Table 16.2 lists management recommendations for wetlands within each sensitivity classification. The sensitivity rating of each wetland is included in the GIS wetland inventory data tables. City of Edina 2018 Comprehensive Water Resources Management Plan 16-5 Table 16.1 Susceptibility of Wetlands to Degradation by Stormwater Impacts Highly Susceptible Wetland Types:1 Moderately Susceptible Wetland Types:2 Slightly Susceptible Wetland Types:3 Least Susceptible Wetland Types:4 Sedge Meadows Shrub-carrsa Floodplain Forestsa Gravel Pits Open Bogs Alder Thicketsb Fresh (Wet) Meadowsb Cultivated Hydric Soils Coniferous Bogs Fresh (Wet) Meadowsc, e Shallow Marshesc Dredged Material/Fill Material Disposal Sites Calcareous Fens Shallow Marshesd, e Deep Marshesc Low Prairies Deep Marshesd, e Lowland Hardwood Swamps Seasonally Flooded Basins 1 Special consideration must be given to avoid altering these wetland types. Inundation must be avoided. Water chemistry changes due to alteration by stormwater impacts can also cause adverse impacts. Note: All scientific and natural areas and pristine wetland should be considered in this category regardless of wetland type. 2 a., b., c. Can tolerate inundation from 6 inches to 12 inches for short periods of time. May be completely dry in drought or late summer conditions. d. Can tolerate +12 inches inundation, but adversely impacted by sediment and/or nutrient loading and prolonged high water levels. e. Some exceptions. 3 a. Can tolerate annual inundation of 1 to 6 feet or more, possibly more than once/year. b. Fresh meadows which are dominated by reed canary grass. c. Shallow marshes dominated by reed canary grass, cattail, giant reed or purple loosestrife. 4 These wetlands are usually so degraded that input of urban stormwater may not have adverse impacts. Notes: Appendix F (the “source” of this table) contains a more complete description of wetland characteristics under each category. Pristine wetlands are those that show little disturbance from human activity. Source: “Stormwater and Wetlands: Planning and Evaluation Guidelines for Addressing Potential Impacts of Urban Stormwater and Snow Melt Runoff on Wetlands,” State of Minnesota. Stormwater Advisory Group, June 1997. City of Edina 2018 Comprehensive Water Resources Management Plan 16-6 Table 16.2 Management Recommendations for Each Wetland Sensitivity Classification High Moderate Least Special consideration must be given to avoid altering these wetland types. Inundation must be avoided. Water chemistry due to alteration by stormwater impacts can also cause adverse impacts. These wetlands can tolerate only moderate alterations in hydrology. They have very good wildlife habitat value and a relatively diverse plant community. They will tolerate an additional 6 inches of inundation, but will be adversely impacted by sediment and/or nutrient loading and prolonged high water levels. These wetlands are usually so degraded that input of urban stormwater may not have adverse impacts. Maintain the existing Stormwater Bounce or degree of water level fluctuation. Maintain the existing Stormwater Bounce or degree of water level fluctuation. Limit the maximum addition of water to 6 inches. No limit for Stormwater Bounce or degree of water level fluctuation. Maintain the existing Discharge Rate. Maintain the existing Discharge Rate. Maintain or decrease the existing Discharge Rate. For 1 and 2-year storm events, maintain existing inundation periods. For 1 and 2-year storm events, maintain existing inundation periods. Limit maximum inundation to 1 additional day. For 1 and 2-year storm events, maintain existing inundation periods. Limit maximum inundation to an additional 7 days. For 10-percent-annual-chance storm events and greater, maintain existing inundation periods. For 10-percent-annual-chance storm events and greater, maintain existing inundation periods. Limit maximum inundation to an additional 7 days. For 10-percent-annual-chance storm events and greater, maintain existing inundation periods. Limit maximum inundation to an additional 21 days. Do not change the outlet control elevation. Do not change the outlet control elevation. May raise outlet control elevation up to 4 feet above existing outlet elevation. For landlocked wetlands, keep the Run-out control elevations above the delineated wetland edge. For landlocked wetlands, keep the Run-out control elevations above the delineated wetland edge. For landlocked wetlands, keep the Run-out control elevations above the delineated wetland edge. Recommendation: If not already implemented, a preservation program should be initiated. Active protection from invasive plant species should begin. Purple Loosestrife, reed canary grass, and hybrid cattail should be eradicated from these wetlands. Recommendation: These wetlands have good potential to restore native plant communities. It is well worth the effort to control invasive species (especially purple loosestrife) in these wetlands. Recommendation: These wetlands could be altered to improve stormwater storage and to improve water quality and not severely impact the wetland quality. City of Edina 2018 Comprehensive Water Resources Management Plan 16-7 16.2 MCWD FAW—2003 In 2001-2003, the MCWD undertook an FAW within the entire MCWD, which covers the northeast portion of the City of Edina. This assessment included the evaluation of the majority of wetlands within the MCWD including the verification the presence of a wetland, the mapping of the approximate wetland boundary, and assessment of wetland functions. The following sections discuss the FAW in more detail. 16.2.1 Delineation and Inventory The 2003 wetland assessment evaluated the wetlands identified in the Hennepin Conservation District Comprehensive Wetland Inventory (HCWI) that were greater than one-quarter acre in size. Most of the wetlands greater than approximately one-quarter acre in size were inventoried and field evaluated, to determine if the area was actually a wetland. The inventory identified wetland vegetation, type, location and boundaries, size, groundwater interaction, function, restoration potential, as well as the presence of buffers, invasive or nuisance vegetation, and rare/unique features. Wetland functions were evaluated using a variant of the MnRAM. Restoration potential was estimated based on wetland size, property ownership, and ease of restoration. Additionally, USFWS Cowardin and Circular 39 classifications were assigned to each wetland during field inspections. Wetlands identified on the HCWI that are smaller than one-quarter acre in size were originally identified using historic aerial photos, infrared photos, soil types, NWI and PWI data, and Hennepin County Mosquito Control maps but were not field verified or assessed as part of the 2003 MCWD FAW. These wetlands have been included in the City’s updated wetland inventory for the portion of the City within the MCWD, but may not have complete information available. 16.2.2 Critical Wetland Resources Wetlands in the MCWD were evaluated for designation as critical resources based on several features defined in the Minnesota Statutes. These critical wetland resources are classified by the MCWD into the Preserve management classification. Criteria for designating wetlands as critical resources are as follows: • Outstanding Resource Value Waters (Minn. Rules 7050.0180) • Designated Scientific and Natural Areas (Minn. Rules 86A.05) • Wetlands with known occurrences of threatened or endangered species (Minn. Stat. 84.0895) • State Wildlife Management Areas (Minn. Stat. 86A.05) • State Aquatic Management Areas (Minn. Stat. 86A.05) • Calcareous Fens (Minn. Rules 8420.1010 through 8420.1060) • High priority areas for wetland preservation, enhancement, restoration, and establishment (Minn. Rules 8420.0350, subpart 2) • Designated historic or archaeological sites City of Edina 2018 Comprehensive Water Resources Management Plan 16-8 16.2.3 Wetland Susceptibility to Stormwater The state guidance document Stormwater and Wetlands: Planning and Evaluation Guidelines for Addressing Potential Impacts of Urban Stormwater and Snow-Melt Runoff on Wetlands (State of Minnesota, Stormwater Advisory Group, June 1997) developed a methodology for determining the susceptibility of wetlands to degradation by stormwater input. This methodology relates wetland type to a level of susceptibility as shown in Table 16.1. The MCWD used this methodology to identify those wetlands susceptible to degradation by stormwater. 16.2.4 Wetland Management Classification Based on the results of the field evaluation and its resource significance and susceptibility to stormwater input, each wetland within the MCWD was assigned to one of four categories: Preserve, Manage 1, Manage 2, or Manage 3. Preserve wetland are the highest quality wetlands or have been identified as important wetland resources. The MCWD management classification of each wetland is included in the GIS wetland inventory data tables. 16.3 Circular 39 Wetland Classification The Wetlands of the United States was published in 1959 by the USFWS and is commonly referred to as "Circular 39" (Shaw and Fredine, 1959). The Circular 39 Wetland Classification System was the first method that the USFWS used to classify wetland basins in the U.S. It is composed of 20 wetland types of which 7 are found in the City of Edina. A general description of each wetland type is provided below. As part of the City of Edina’s 1999 wetland inventory and the 2003 MCWD FAW, Circular 39 classifications were assigned to each wetland during field inspections. Figure 16.2 shows the wetlands classification within the City. The Circular 39 classification for each wetland within the City is included in the GIS wetlands inventory database. 16.3.1 Type 1: Seasonally Flooded Basin, Floodplain Forest Soil is covered with water or is waterlogged during variable seasonal periods but usually is well-drained during much of the growing season. This type is found both in upland depressions and in overflow bottomlands. In uplands, basins or flats may be filled with water during periods of heavy rain or melting snow. Vegetation varies greatly according to season and duration of flooding: from bottomland hardwoods to herbaceous plants. Where the water has receded early in the growing season, smartweeds, wild millet, fall panicum, redroot cyperus, and weeds (i.e., marsh elder, ragweed, and cockleburs) are likely to occur. Shallow basins that are submerged only very temporarily usually develop little or no wetland vegetation. City of Edina 2018 Comprehensive Water Resources Management Plan 16-9 16.3.2 Type 2: Wet Meadow, Fresh Wet Meadow, Wet to Wet-Mesic Prairie, Sedge Meadow, and Calcareous Fen Soil is usually without standing water during most of the growing season but is waterlogged within at least a few inches of the surface. Meadows may fill shallow basins, sloughs, or farmland sags, or these meadows may border shallow marshes on the landward side. Vegetation includes grasses, sedges, rushes and various broad-leaved plants. In the North, representative plants are Carex, rushes, redtop, reed grasses, manna grasses, prairie cordgrass, and mints. Other wetland plant community types include low prairies, sedge meadows, and calcareous fens. 16.3.3 Type 3: Shallow Marsh Soil is usually waterlogged early during the growing season and may often be covered with as much as 6 inches or more of water. These marshes may nearly fill shallow lake basins or sloughs, or may border deep marshes on the landward side. These are common as seep areas on irrigated lands. Vegetation includes grasses, bulrushes, spike rushes, and various other marsh plants such as cattails, arrowhead, pickerelweed, and smartweeds. Common representatives in the North are reed, whitetop, rice cutgrass, Carex, and giant bur reed. 16.3.4 Type 4: Deep Marsh Soil is usually covered with 6 inches to 3 feet or more of water during the growing season. These deep marshes may completely fill shallow lake basins, potholes, limestone sinks and sloughs, or they may border open water in such depressions. Vegetation includes cattails, reeds, bulrushes, spike rushes and wild rice. In open areas, pondweeds, naiads, coontail, watermilfoils, waterweeds, duckweed, water lilies, or spatterdocks may occur. 16.3.5 Type 5: Shallow Open Water Shallow ponds and reservoirs are included in this type. Water is usually less than 10-feet deep and is fringed by a border of emergent vegetation similar to open areas of Type 4. Vegetation (mainly at water depths less than 6 feet) includes pondweeds, naiads, wild celery, coontail, watermilfoils, muskgrass, waterlilies, and spatterdocks. 16.3.6 Type 6: Shrub Swamp; Shrub Carr, Alder Thicket The soil is usually waterlogged during the growing season and is often covered with as much as 6 inches of water. Shrub swamps occur mostly along sluggish streams and occasionally on flood plains. Vegetation includes alders, willows, buttonbush, dogwoods and swamp-privet. 16.3.7 Type 7: Wooded Swamps; Hardwood Swamp, Coniferous Swamp The soil is waterlogged at least to within a few inches of the surface during the growing season and is often covered with as much as 1 foot of water. Wooded swamps occur mostly along sluggish streams, on old riverine oxbows, on floodplains, on flat uplands, and in very shallow lake basins. Forest vegetation includes tamarack, arborvitae (cedar), black spruce, balsam fir, red maple, and black ash. Northern City of Edina 2018 Comprehensive Water Resources Management Plan 16-10 evergreen swamps usually have a thick ground covering of mosses. Deciduous swamps frequently support beds of duckweeds, smartweeds, and other herbs. 16.4 Cowardin Wetland Classification The Classification of Wetlands and Deepwater Habitats of the United States was published by the USFWS in 1979 (Cowardin et al., 1979). This wetland classification methodology was used to classify wetlands in the development of the NWI maps beginning in the late 1970s and early 1980s. The structure of the classification is hierarchical progressing from Systems and Subsystems, at the most general levels, to Classes, Subclasses, and Dominance Types at the most specific levels. A general description of the hierarchical structure is provided below. As part of the City of Edina’s 1999 wetland inventory and the 2003 MCWD FAW, Cowardin wetland classifications were assigned to each wetland during field inspections. The Cowardin classification for each wetland within the City is included in the GIS wetlands inventory database. 16.4.1 System The term System refers to a complex of wetlands and deep water habitats that share the influence of similar hydrologic, geomorphologic, chemical, or biological factors. The primary systems found in Edina are Palustrine, Lacustrine, and Riverine while Marine and Estuarine Systems are not found in the City. L: Lacustrine (lakes and deep ponds) - Lacustrine Systems include wetlands and deep water habitats with all of the following three characteristics: 1. Situated in a topographic depression or a dammed river channel; 2. Lacking trees, shrubs, persistent emergents, emergent mosses or lichens with greater than 30 percent areal coverage; 3. Total area exceeds 8 hectares (20 acres). Basins or catchments less than 8 hectares in size are also included if they have at least one of the following characteristics: • A wave-formed or bedrock feature forms all or part of the shoreline boundary; or • The catchment has, at low water, a depth greater than 2 meters (6.6 feet) in the deepest part of the basin. P: Palustrine (shallow ponds, marshes, swamps and sloughs) - Palustrine Systems include all non-tidal wetlands dominated by trees, shrubs, persistent emergents, emergent mosses or lichens. R: Riverine (rivers, creeks and streams) - Riverine Systems are contained in natural or artificial channels periodically or continuously containing flowing water. Upland islands or Palustrine wetlands may occur in the channel, but they are not part of the Riverine System. City of Edina 2018 Comprehensive Water Resources Management Plan 16-11 16.4.2 Subsystem The term Subsystem refers to a further subdivision of Systems into more specific categories. The Palustrine System has no subsystems associated with it while Lacustrine Systems have two Subsystems and Riverine Systems have four, of which only one applies in the City of Edina. Each Subsystem is unique for the System to which it applies. L1: Limnetic - Extends outward from Littoral boundary and includes deep water habitats within the Lacustrine System. L2: Littoral - Extends from shoreward boundary to 2 meters (6 feet) below annual low water or to the maximum extent of non-persistent emergents, if these grow at greater than 2 meters. R2: Lower Perennial 16.4.3 Class, Subclass The wetland Class is the highest taxonomic unit below the Subsystem level. The Class code describes the general appearance of the habitat in terms of either the dominant life form of the vegetation or the physiography and composition of the substrate. Life forms (e.g. trees, shrubs, emergents) are used to define classes because they are easily recognizable, do not change distribution rapidly, and have traditionally been used to classify wetlands. Finer differences in life forms are recognized at the Subclass level. Mixed classes are used as sparingly as possible, under two main conditions: (1) The wetland contains two or more distinct cover types each encompassing at least 30 percent areal coverage of the highest life form, but is too small in size to allow separate delineation of each cover type; and (2) The wetland contains two or more classes or subclasses each comprising at least 30 percent areal coverage so evenly interspersed that separate delineation is not possible at the scale used for classification. Mixed subclasses are also allowed and follow the same rules for mixed classes (Cowardin et al., 1979). AB: Aquatic Bed—Includes wetlands and deep water habitats dominated by plants that grow principally on or below the surface of the water for most of the growing season in most years. Subclasses include: AB1 = Algal, AB2 = Aquatic Moss, AB3 = Rooted Vascular, AB4 = Floating Vascular, AB5 = Unknown Submergent, and AB6 = Unknown Surface. EM: Emergent—Characterized by erect, rooted, herbaceous hydrophytes, excluding mosses and lichens. This vegetation is present for most of the growing season in most years. Subclasses include: EM1 = Persistent (plants that normally remain standing at least until the beginning of the next growing season), and EM2 = Nonpersistent (plants which fall to the surface of the substrate or below the surface of the water at the end of the growing season). City of Edina 2018 Comprehensive Water Resources Management Plan 16-12 FO: Forested—Woody vegetation greater than 6 meters (20 feet) tall. Subclass determination is based on: which type represents more than 50 percent of the areal canopy coverage during the leaf-on period. Subclasses include: FO1 = Broad-leaved Deciduous, FO2 = Needle-leaved Deciduous, FO3 = Broad-leaved Evergreen, FO4 = Needle-leaved Evergreen, FO5 = Dead, FO6 = Deciduous, and FO7 = Evergreen. SS: Scrub/Shrub—Woody vegetation less than 6 meters (20 feet) tall. The species include true shrubs, young trees (saplings) or trees that are small or stunted because of environmental conditions. Subclass determination is based on: which type represents more than 50 percent of the areal canopy coverage during the leaf-on period and include: SS1 = Broad-leaved Deciduous, SS2 = Needle-leaved Deciduous, SS3 = Broad-leaved Evergreen, SS4 = Needle-leaved Evergreen, SS5 = Dead, SS6 = Deciduous (used if deciduous woody vegetation cannot be identified on aerial photography as either Broad-leaved or Needle-leaved), and SS7 = Evergreen (used if evergreen woody vegetation cannot be identified on aerial photography as either Broad-leaved or Needle-leaved). UB: Unconsolidated Bottom—Includes all wetlands and deep water habitats with at least 25 percent cover of particles smaller than stones (less than 6-7 cm.), and a vegetative cover less than 30 percent. 16.4.4 Water Regime Precise description of hydrologic characteristics requires detailed knowledge of the duration and timing of surface inundation, both yearly and long-term, as well as an understanding of groundwater fluctuations. Because such information is seldom available, the water regimes that, in part, determine characteristic wetland and deep water plant and animal communities are described here in only general terms (Cowardin, et al., 1979). Water regimes are grouped under two major categories, Tidal and Nontidal. The Tidal Water Regime does not occur in the City so is not described here. A: Temporarily Flooded—Surface water present for brief periods during the growing season, but the water table usually lies well below the soil surface. Plants that grow both in uplands and wetlands are characteristic of this water regime. The temporarily flooded regime also includes wetlands where water is present for variable periods without detectable seasonal periodicity. Weeks, months, or even years may intervene between periods of inundation. The dominant plant communities under this regime may change as soil moisture conditions change. B: Saturated—The substrate is saturated to the surface for extended periods during the growing season, but surface water is seldom present. C: Seasonally Flooded—Surface water is present for extended periods especially early in the growing season, but is absent by the end of the growing season in most years. When surface water is absent, the water table is often near the land surface. The water table after flooding ceases is highly variable, extending from saturated to a water table well below the ground surface. City of Edina 2018 Comprehensive Water Resources Management Plan 16-13 F: Semipermanently Flooded—Surface water persists throughout the growing season in most years. When surface water is absent, the water table is usually at or very near the land surface. G: Intermittently Exposed—Surface water is present throughout the year except in years of extreme drought. H: Permanently Flooded—Water covers the land surface throughout the year in all years. Vegetation is composed of obligate hydrophytes. 16.4.5 Special Modifiers Many wetlands and deep water habitats are man-made and natural ones have been modified to some degree by the activities of man or beavers. Since the nature of these modifications often greatly influences the character of such habitats, special modifying terms have been included here to emphasize their importance (Cowardin, et al., 1979). b: Beaver—Created or modified by a beaver dam. d: Partly Drained—The water level has been artificially lowered, but he area is still classified as wetland because soil moisture is sufficient to support hydrophytes. Drained areas are not considered wetland if they can no longer support hydrophytes. f: Farmed—The soil surface has been mechanically or physically altered for production of crops, but hydrophytes will become reestablished if farming is discontinued. h: Diked/Impounded—Created or modified by a barrier or dam which purposefully or unintentionally obstructs the outflow of water. Both man-made and beaver dams are included. r: Artificial—Refers to substrates classified as Rock Bottom, Unconsolidated Bottom, Rocky Shore, and Unconsolidated Shore that were emplaced by humans, using either natural materials such as dredge spoil or synthetic materials such as discarded automobiles, tires, or concrete. s: Spoil—Refers to the placement of spoil materials which have resulted in the establishment of wetland. x: Excavated—Lies within a basin or channel excavated by humans. 16.5 Public Waters The MnDNR has designated certain waters of the state as public waters (Minn. Rules 6115.1060). MnDNR “Public Waters Inventory (PWI)” maps show public waters within the City. A MnDNR permit is required for work that would alter the course, current, or cross-section of a designated public water. PWI maps show public waters as one of the following: public water basin; public water wetland; public water watercourse; or, public ditch/altered natural watercourse. City of Edina 2018 Comprehensive Water Resources Management Plan 16-14 Table 16.3 lists the MnDNR Public Waters within the city. The table includes the MnDNR identifier for each pond, as well as the corresponding subwatershed for this stormwater study. Public water basins are identified with a number and the letter “P”. Public water wetlands are identified with a number and the letter “W”. Public wetlands include, and are limited to, Type 3, 4, and 5 wetlands that have been designated as public waters and are 2½ acres or more in size (10 acres in unincorporated areas). Public water courses and ditches in Edina include: •Minnehaha Creek •North Fork of Nine Mile Creek •South Fork of Nine Mile Creek •Braemar Branch of Nine Mile Creek Table 16.3 MnDNR Public Waters within Edina Waterbody ID Public Waters Class Public Waters Name Corresponding Subwatershed ID(s) 27002801 P Cornelia (North) NC_62 27002802 P Cornelia (South) SC_1 27002900 P Lake Edina LE_1 27004100 P Edina Mill Pond MHC_ 2 27004400 P Indianhead Lake IH_1 27004500 P Arrowhead Lake AH_1 27005000 P Bredesen MD_50, MD_1 27005400 P Meadowbrook Lake 27005500 P Mirror Lake ML_1, ML_32 27005600 P Hawkes Lake HL_1 27066600 W EI_19 27066700 W EI_1 27066800 P Highlands Park Pond HI_1 27066900 W Melody Lake ML_8 27067000 W Lake Harvey MHS_22 27067100 P Birchcrest NMC_112 27067200 W CO_1 City of Edina 2018 Comprehensive Water Resources Management Plan 16-15 Waterbody ID Public Waters Class Public Waters Name Corresponding Subwatershed ID(s) 27067300 P Heights NMC_1 27067400 W NMC_77 27067500 P Pamela Pond LP_14, LP_26 27067600 W NC_5 27067700 W Nancy NC_2 27067800 W NC_30 27067900 W NC_3 27068000 W NC_4 27078000 W EI_32 27078100 W ML_28 27078200 W ML_16 27079900 W NMN_76, NMN_55 27080000 W NMN_75 27080100 W NMN_50 27080200 W MD_25 27080300 W MD_21 27080400 W EdCrk3 27080500 W NMN_24 27080600 W Pauly's Pond AH_6 27080700 W Garrison Pond EP_2 27080800 W EP_2 27101300 W BRCrk4, BRCrk15, BRCrk16, BRCrk17, BRCrk18, NMSB_12 27103800 W SWP_3 27103900 W SWP_5, SWP_14, SWP_35 27104000 W SWP_1, SWP_2, SWP_4 27104100 W NMS_3 27110600 W EdCrk5 Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Min n e h a h a Cr e ek £¤169 100 62 100 456717 456731 4567158 456731 Nine Mile CreekWatershed District Minnehaha CreekWatershed District North B ranchNineMileCreek SouthBranc h N i ne Mile C r eekMinneapolisMinneapolis HopkinsHopkins Eden PrairieEden Prairie RichfieldRichfield BloomingtonBloomington MinnetonkaMinnetonka Saint Louis ParkSaint Louis Park Barr Footer: ArcGIS 10.4.1, 2017-10-31 10:05 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_16_1_Wetlands.mxd User: smsWETLANDSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 16.1 0 3,000 Feet !;N Lake/Wetland Watershed District Boundary Streets and Highways Creek/Stream City of Edina Boundary Imagery Source: MnGeo, 2016 Mud Lake Lake Cornelia Lake Edina Mirror Lake Arrowhead Lake Indianhead Lake Highlands Lake Melody Lake Lake Pamela Harvey Lake Hawkes Lake Centennial Lakes Minne h a h a C r e e k£¤169 100 62 100 456717 456731 4567158 456731 Nine Mile CreekWatershed District Minnehaha CreekWatershed District No rth B ranchNineMileCreek SouthBranch N i ne MileCreek Min n eapolisMin n eapolis Hopkin sHopkin s Eden PrairieEden Prairie RichfieldRichfield Bloomin gtonBloomin gton Min n eton kaMin n eton ka Sain t Louis ParkSain t Louis Park Barr Footer: ArcGIS 10.4.1, 2017-10-31 10:07 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Reports\Figures_CityReviewDraft\Fig_16_2_Wetland_Classifications.mxd User: smsWETLAND CLASSIFICATIONSComprehensiveWater ResourcesManagement PlanCity of Edina, Minnesota FIGURE 16.2 0 3,000 Feet !;N Watershed District Boun dary Streets an d Highways City of Edin a Boun dary Wetlan d T ype* Un classified T ype 1 T ype 1 Predomin an t + Others T ype 2 T ype 2 Predomin an t + Others T ype 3 T ype 3 Predomin an t + Others T ype 4 T ype 5 T ype 5 Predomin an t + Others T ype 6 T ype 7 T ype 7 Predomin an t + Others Imagery Source: Mn Geo, 2016 *Based on the Fish an d Wildlife ServiceCircular 39 Classification System. Wetlan ds within the Min n ehaha CreekWatershed District were iden tified an dassessed in 2005 as part of theMin n ehaha Creek Fun ction al Assessmen tof Wetlan ds. Wetlan ds located in theremain in g portion of the city wereiden tified an d assessed in 1999 as partof the City of Edin a’s wetlan d in ven tory. City of Edina 2018 Comprehensive Water Resources Management Plan 17-1 17.0 References Barr Engineering Company, 1999a. Glen Lake Use Attainability Analysis. Barr Engineering Company, 1999b. Round Lake Use Attainability Analysis. Barr Engineering Company, 2001. Bloomington Use Attainability Analysis. Prepared for Nine Mile Creek Watershed District. Barr Engineering Company, 2004. Draft Mirror Lake Use Attainability Analysis. Barr Engineering Company, 2006. Draft Lake Cornelia Use Attainability Analysis. Barr Engineering Company, 2016. City of Edina Imperviousness Assumptions for Stormwater Modeling. Prepared for City of Edina. City of Edina, 2009. Edina Comprehensive Plan. Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe, 1979. Classification of Wetlands and Deepwater Habitats of the United States. U.S. Fish and Wildlife Service, FWS/OBS-79/31. Federal Emergency Management Agency (FEMA), 2016. Flood Insurance Study for Hennepin County, MN All Jurisdictions. Hennepin Conservation District, 2003. Functional Assessment of Wetlands, Minnehaha Creek Watershed District. Minnehaha Creek Watershed District, 2007. Minnehaha Creek Watershed District Comprehensive Water Resources Management Plan. Minnehaha Creek Watershed District, 2018. Minnehaha Creek Watershed District Watershed Management Plan. Minnesota Department of Natural Resources, 1999. Minnesota Routine Assessment Method for Evaluating Wetland Functions (MnRAM). Minnesota Pollution Control Agency (MPCA), 2000. Protecting Water Quality in Urban Areas, March 2000. Minnesota Pollution Control Agency (MPCA), 2005. Minnesota Stormwater Manual. Minnesota Pollution Control Agency (MPCA), 2010. Nine Mile Creek Biological Stressor Identification. Prepared by Barr Engineering Company. Minnesota Pollution Control Agency (MPCA), 2013. Minnehaha Creek E. coli Bacteria Total Maximum Daily Load. Prepared by Tetra Tech, Inc. Minnesota Pollution Control Agency (MPCA), 2016. Twin Cities Metropolitan Area Chloride Total Maximum Daily Load Study. Prepared by MPCA and LimnoTech. City of Edina 2018 Comprehensive Water Resources Management Plan 17-2 Mitsch, W.J. and J.G. Gosselink, 2000. Wetlands. Nine Mile Creek Watershed District, 2017. Nine Mile Creek Watershed District Water Management Plan. National Oceanic and Atmospheric Administration, 2013. Atlas 14 Volume 8 - Precipitation-Frequency Atlas of the United States, Midwestern States. Schwab, G.O., D. Fangmeier, W. Elliot, and R. Frevert, 1993. Soil and Water Conservation Engineering. Shaw, S.P., and C.G. Fredine, 1959. Wetlands of the United States: Their Extent and Their Value to Waterfowl and Other Wildlife. U.S. Fish and Wildlife Service. Circular 39. State of Minnesota, Stormwater Advisory Group, 1997. Stormwater and Wetlands: Planning and Evaluation Guidelines for Addressing Potential Impacts of Urban Stormwater and Snow Melt Runoff on Wetlands. June 1997. U.S. Army Corps of Engineers Wetlands Delineation Manual, 1987. U.S. Department of Commerce, Weather Bureau, 1961. “Technical Paper No. 40. Rainfall Frequency Atlas of the United States.” U.S. Environmental Protection Agency, 1988. Stormwater Management Model, Version 4: User’s Manual. Appendices Appendix A City of Edina Imperviousness Assumptions for Stormwater Modeling Appendix B Summary of Nine Mile Creek and Minnehaha Creek Modeling Approach Appendix C Legacy Flood Protection Projects Appendix D List of Pond Improvement Recommendations Appendix E Aquatic Vegetation Prioritization List Appendix F Modified Minnesota Routine Assessment Method for Evaluating Wetland Functions (MnRAM) Version 2.0 Appendix G GIS Wetlands Inventory Database Appendix A City of Edina Imperviousness Assumptions for Stormwater Modeling Barr Engineering Co. 4300 MarketPointe Drive, Suite 200, Minneapolis, MN 55435 952.832.2600 www.barr.com Technical Memorandum To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Project: 23/27-0354.00 BCO 160 1.0 Introduction Redevelopment throughout the City of Edina (City), particularly the rebuilding of older homes with newer, larger homes, has raised questions about the imperviousness assumptions used for stormwater modeling. Therefore, as directed by the City, Barr evaluated the most recent imperviousness data throughout different neighborhoods of the city to help determine if the assumptions that were previously used for stormwater modeling are representative of current conditions. This memo documents the findings of this imperviousness assessment, referred to herein as the “2016 analysis”. There are two forms of imperviousness: (1) “Total Impervious” which represents the total area of impervious surfaces such as pavement, roof tops, etc., and (2) “Directly Connected Impervious” which represents the area of impervious surface from which water flows directly into storm sewer or water bodies. The Directly Connected Impervious area is the area that is most important for hydrologic modeling. The majority of this memo discusses the Total Impervious, and Section 5.0 discusses methods for converting from Total Impervious area to Directly Connected Impervious area. Table 1 provides a summary of the imperviousness assumptions used for modeling associated with both the 2003 and 2011 CWRMPs (2003/2011 CWRMPs). Table 1 Imperviousness assumptions from the 2003/2011 CWRMPs Land Use Type Total Impervious % Directly Connected Impervious % Ratio of Directly Connected to Total Commercial 90% 80% 0.889 Developed Park Not previously used Not previously used N/A Golf Course 5% 2% 0.400 High Density Residential 70% 40% 0.571 Highway 50% 50% 1.000 Industrial/Office 90% 80% 0.889 Institutional 40% 20% 0.500 Institutional - High Imperviousness 70% 50% 0.714 Low Density Residential 40% 20% 0.500 Medium Density Residential 55% 30% 0.545 Natural/Park/Open 2% 0% 0.000 Open Water 100% 100% 1.000 To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 2 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Land Use Type Total Impervious % Directly Connected Impervious % Ratio of Directly Connected to Total Other Not previously used Not previously used N/A Very Low Density Residential 12% 8% 0.667 Wetland 100% 100% 1.000 2.0 Data Sources The main data source for this 2016 analysis is the 2011 Twin Cities impervious surface area dataset developed by the University of Minnesota (reference [1]). This geographic information system (GIS) dataset is a 30-meter resolution raster (grid) of impervious surface classification for the seven-county Twin Cities Metropolitan Area. The values in this GIS layer represents total imperviousness, not directly connected imperviousness. The impervious surface classification was created using a combination of multi-temporal Landsat (satellite) data and Light Detection and Ranging (LiDAR) data. This raster data set is shown in Figure 1. Barr analyzed the imperviousness data by land use type and neighborhood. This approach allowed us to review the range of results by neighborhood for imperviousness of each land use type. A neighborhood analysis was performed (as opposed to a parcel analysis) due to the larger grid size of the imperviousness raster dataset (i.e., the U of M’s imperviousness data is too coarse for a parcel-level analysis). The City provided the neighborhood GIS layer containing 45 neighborhoods throughout the city (Figure 2 (reference [2]). The land use data utilized for this analysis was the same land use data provided by the City for the 2003/2011 CWRMPs (reference [3]). Using the same land use data allowed us to analyze results with the understanding that changes were strictly based on the changing imperviousness within the city. The land use data is shown in Figure 3. 3.0 Analysis Methods The neighborhood and land use type polygon GIS layers were intersected to define smaller polygons of land use type within each neighborhood. Zonal statistics were then used to calculate the average raster cell value for each land use type within each neighborhood (Table 2). Additionally, the area of each land use type within each neighborhood was calculated to understand which land use types are more prevalent in each neighborhood (Table 3). The data from Table 2 and Table 3 were then used to create a histogram of imperviousness and a cumulative area function to understand the range of imperviousness for each land use type. Figure 4 also shows the average and range of the resulting imperviousness values of all neighborhoods by land use type. These results are presented and discussed in Section 4.0. CahillBraemar Hills Countryside Parkwood Knolls Concord Southdale Bredesen Park Lake Cornelia Indian Hills Highlands Dewey Hill Creek Valley Todd Park Birchcrest Grandview Presidents The Heights Prospect Knolls Parklawn South Cornelia Melody Lake Arden Park Normandale Park Pentagon Park Morningside Pamela Park Lake Edina Fox Meadow Golf Terrace Heights Country ClubInterlachen Park Chowen Park Indian Trails Hilldale Promenade Rolling Green Brookview Heights Edinborough Minnehaha Woods Strachauer Park White Oaks Centennial Lakes Sunny Slope Creek Knoll 50th and France Source: Esri, DigitalGlobe, GeoEye, i-cubed, USDA, USGS, AEX,Getmapping, Aerogrid, IGN, IGP, and the GIS User Community PERCENT IMPERVIOUSNESS2011 U OF M DATASETImperviousness AnalysisCity of Edina FIGURE 1 Barr Footer: ArcGIS 10.4, 2016-09-16 16:52 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Meetings\Percent Imperviousness.mxd User: cda1 0 1 Miles !;N Percent ImperviousnessHigh : 100 Low : 0 Edina Neighborhoods Note: Raster grid cells with0% imperviousness aretransparent and the backgroundimagery is visible. §¨¦494§¨¦494 £¤212 £¤169 £¤169 100 62 7 10062 7 456728 456717 456753 456734 456731 45673 4567158 456720 456732 456761 CahillBraemar Hills Countryside Parkwood Knolls Concord Southdale Bredesen Park Lake Cornelia Indian Hills Highlands Dewey Hill Creek Valley Todd Park Birchcrest Grandview Presidents The Heights Prospect Knolls Parklawn South Cornelia Melody Lake Arden Park Pentagon Park Morningside Pamela Park Lake Edina Fox Meadow Golf Terrace Heights Country ClubInterlachen Park Chowen Park Normandale Park Indian Trails Hilldale Promenade Rolling Green Brookview Heights Edinborough Minnehaha Woods Strachauer Park White Oaks Centennial Lakes Sunny Slope Creek Knoll 50th and France Source: Esri, DigitalGlobe, GeoEye, i-cubed, USDA, USGS, AEX,Getmapping, Aerogrid, IGN, IGP, and the GIS User Community EDINA NEIGHBORHOODSImperviousness AnalysisCity of Edina FIGURE 2 Barr Footer: ArcGIS 10.4, 2016-09-16 16:24 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Meetings\Edina Neighborhoods.mxd User: cda1 0 1 Miles !;N Edina Neighborhoods Streets and Highways Interstate Highway US Highway State Trunk Highway County State-Aid Highway Source: Esri, DigitalGlobe, GeoEye, i-cubed, USDA, USGS, AEX,Getmapping, Aerogrid, IGN, IGP, and the GIS User Community LAND USE TYPEImperviousness AnalysisCity of Edina FIGURE 3 Barr Footer: ArcGIS 10.4, 2016-09-16 16:44 File: I:\Client\Edina\Projects\CRWMP_Update_2017\Maps\Meetings\Land Use Map.mxd User: cda1 0 1 Miles !;N Edina Neighborhoods Land Use Natural/Park/Open Developed Parkland Golf Course Very Low Density Residential Low Density Residential Medium Density Residential High Density Residential Institutional Institutional - High Imperviousness Highway Commercial Industrial/Office Other Open Water Wetland Table 2 - Mean total imperviousness by land use type within each neighborhood Commercial Developed Park Golf Course High Density Residential Highway Industrial/ Office Institutional Institutional - High Imperviousness Low Density Residential Medium Density Residential Natural/Park/ Open Open Water Other Very Low Density Residential Wetland Average % Impervious Legend 50th and France 87.3 72.6 52.0 61.8 86.5 Arden Park 64.6 0.0 34.3 63.4 39.4 32.6 65.6 7.3 100.0 36.6 100.0 Birchcrest 48.9 68.1 32.8 18.4 100.0 21.0 36.9 90.0 Braemar Hills 66.7 3.5 63.3 69.3 54.8 27.9 14.2 100.0 12.5 100.0 29.7 80.0 Bredesen Park 72.2 4.6 40.9 61.8 33.7 42.1 5.6 100.0 100.0 46.4 70.0 Brookview Heights 71.8 59.7 30.9 12.6 100.0 21.3 100.0 37.9 60.0 Cahill 72.4 49.9 74.1 60.4 63.5 24.3 100.0 41.9 100.0 70.5 50.0 Centennial Lakes 88.0 41.3 60.0 83.0 100.0 76.9 40.0 Chowen Park 42.2 38.9 7.7 100.0 38.6 30.0 Concord 53.2 38.6 53.6 60.6 35.3 19.4 100.0 100.0 45.5 20.0 Country Club 33.8 65.6 38.0 100.0 41.1 10.0 Countryside 22.3 37.7 32.7 28.6 49.1 25.7 100.0 18.8 100.0 32.0 0.0 Creek Knoll 62.2 34.2 76.7 14.9 100.0 36.9 Creek Valley 12.8 39.6 30.8 27.7 2.0 100.0 100.0 36.9 Dewey Hill 6.5 65.5 32.0 41.2 11.8 100.0 100.0 39.3 Edinborough 64.5 63.1 57.9 64.5 76.3 34.0 47.9 57.0 Fox Meadow 19.6 28.9 51.4 6.9 100.0 21.6 37.4 Golf Terrace Heights 65.6 27.5 7.2 68.3 61.3 35.1 100.0 28.7 Grandview 80.0 42.0 46.8 59.0 46.5 66.6 37.7 54.0 100.0 44.7 50.4 Highlands 12.5 26.0 35.3 28.4 10.7 100.0 27.8 100.0 31.8 Hilldale 0.0 21.5 100.0 100.0 39.7 Indian Hills 62.8 30.5 56.3 27.6 100.0 18.1 100.0 38.0 Indian Trails 65.8 56.0 71.7 28.6 4.6 13.3 100.0 33.5 Interlachen Park 57.5 6.6 25.8 100.0 100.0 17.6 Lake Cornelia 60.2 34.1 60.6 48.1 33.5 11.3 100.0 100.0 45.2 Lake Edina 90.7 9.2 0.0 62.4 34.6 15.2 100.0 100.0 43.9 Melody Lake 53.4 44.5 30.3 3.1 100.0 23.7 33.7 Minnehaha Woods 56.2 4.4 16.7 34.6 71.5 34.7 100.0 100.0 35.4 Morningside 68.2 15.2 45.1 32.1 2.7 15.4 100.0 100.0 32.3 Normandale Park 10.0 53.5 43.0 31.6 10.0 100.0 24.5 100.0 34.0 Pamela Park 72.0 8.4 59.0 59.2 37.1 28.0 100.0 100.0 35.9 Parklawn 77.2 6.7 61.9 72.8 26.7 100.0 51.6 Parkwood Knolls 66.4 19.7 47.5 59.0 29.5 51.7 3.6 100.0 22.1 100.0 31.7 Pentagon Park 78.0 40.4 60.5 71.3 0.0 100.0 75.2 Presidents 13.8 63.1 56.5 29.5 24.8 100.0 29.1 Promenade 80.2 52.8 63.6 73.8 71.9 Prospect Knolls 57.4 17.1 34.3 52.2 27.4 45.7 0.4 100.0 100.0 29.7 Rolling Green 17.4 21.4 100.0 100.0 27.1 South Cornelia 76.9 58.2 34.3 39.0 30.7 41.0 Southdale 81.2 67.7 59.0 60.7 84.5 49.9 100.0 76.1 Strachauer Park 7.1 55.5 39.7 39.1 Sunny Slope 39.8 68.7 75.0 29.4 100.0 41.0 The Heights 64.0 15.2 74.3 39.2 30.9 45.1 8.6 16.0 100.0 33.3 Todd Park 37.4 12.5 60.9 31.0 39.0 22.8 100.0 100.0 37.2 White Oaks 40.6 44.5 30.3 47.8 100.0 100.0 36.0 Commercial Developed Park Golf Course High Density Residential Highway Industrial/ Office Institutional Institutional - High Imperviousness Low Density Residential Medium Density Residential Natural/Park/ Open Open Water Other Very Low Density Residential Wetland Maximum 90.7 67.7 40.4 72.6 71.8 83.0 75.0 84.5 60.4 76.7 34.7 100.0 44.7 27.8 100.0 Minimum 37.4 0.0 0.0 38.6 37.7 52.2 16.7 56.3 21.4 2.7 0.0 100.0 16.0 12.5 100.0 Average 77.6 18.7 5.4 58.7 53.8 71.7 41.7 71.6 31.7 42.6 10.5 100.0 31.3 20.1 100.0 Table 3 - Area (acres) of each land use type within each neighborhood Commercial Developed Park Golf Course High Density Residential Highway Industrial/ Office Institutional Institutional - High Imperviousness Low Density Residential Medium Density Residential Natural/Park/ Open Open Water Other Very Low Density Residential Wetland Total Acres of Neighborhood 50th and France 18.91 0.97 0.004 0.06 20 Arden Park 8.87 0.003 0.60 4.40 2.48 114.16 1.98 12.47 6.20 151 Birchcrest 25.23 3.95 150.04 2.73 4.76 3.91 191 Braemar Hills 31.69 263.86 28.79 32.89 23.17 134.46 91.91 23.33 4.42 43.16 678 Bredesen Park 2.72 12.57 44.07 40.70 125.31 52.99 104.13 17.25 97.77 497 Brookview Heights 13.80 5.28 144.99 2.56 3.01 2.51 5.88 178 Cahill 64.78 26.48 255.13 0.26 0.03 7.41 4.52 14.58 5.43 379 Centennial Lakes 38.64 13.35 17.48 18.10 10.05 98 Chowen Park 1.26 176.30 4.25 1.33 183 Concord 1.87 3.97 28.21 48.29 192.44 1.15 17.91 1.38 295 Country Club 5.74 1.49 164.24 8.68 180 Countryside 35.12 14.79 42.68 355.49 5.11 1.98 17.09 4.60 4.05 481 Creek Knoll 2.83 33.47 1.05 13.15 4.27 55 Creek Valley 18.36 21.55 97.42 73.60 18.11 0.95 35.28 265 Dewey Hill 16.17 12.15 111.44 60.86 16.00 20.62 1.48 239 Edinborough 8.36 0.39 43.10 16.01 6.79 10.32 12.70 98 Fox Meadow 0.25 132.88 5.58 10.21 27.29 20.89 197 Golf Terrace Heights 5.92 5.57 127.51 18.80 7.81 130.09 10.04 306 Grandview 25.54 0.13 28.21 9.59 23.51 20.87 77.02 1.32 0.40 3.17 190 Highlands 13.72 0.30 12.26 226.84 19.85 16.89 10.81 4.34 305 Hilldale 0.74 59.42 5.42 12.99 79 Indian Hills 28.33 3.83 6.20 166.68 42.64 88.49 0.98 337 Indian Trails 5.69 13.63 14.02 88.52 4.76 22.82 0.18 150 Interlachen Park 1.96 153.62 53.14 13.46 0.88 223 Lake Cornelia 0.12 30.50 0.15 29.27 289.09 14.18 66.43 8.32 438 Lake Edina 2.06 14.78 0.07 11.31 112.77 7.03 25.43 0.58 174 Melody Lake 6.72 0.31 157.97 4.35 8.51 3.00 181 Minnehaha Woods 0.02 1.06 3.69 132.39 1.14 0.67 1.06 1.58 142 Morningside 7.90 12.08 7.79 192.01 10.28 6.02 3.15 0.82 240 Normandale Park 14.07 31.98 0.05 155.17 6.51 0.79 4.75 3.71 217 Pamela Park 4.98 51.10 0.01 3.89 153.82 0.08 4.08 10.94 229 Parklawn 28.42 38.14 58.45 7.95 0.77 4.91 139 Parkwood Knolls 11.34 20.33 4.76 3.68 369.33 18.96 42.00 30.65 118.87 4.30 624 Pentagon Park 86.52 0.26 6.88 49.05 0.18 2.53 145 Presidents 5.11 1.24 2.89 135.05 35.08 0.77 180 Promenade 59.92 8.69 42.49 9.46 121 Prospect Knolls 0.17 19.23 0.56 0.67 174.03 36.74 10.25 4.13 0.51 246 Rolling Green 0.26 126.78 4.65 5.31 137 South Cornelia 8.75 11.01 22.24 167.28 2.71 212 Southdale 248.23 0.15 61.71 12.39 13.86 8.14 3.24 348 Strachauer Park 5.89 7.85 101.19 115 Sunny Slope 0.35 6.11 0.07 55.82 8.01 70 The Heights 0.03 7.83 0.05 4.06 171.32 2.15 6.00 1.35 10.07 203 Todd Park 8.58 15.52 6.41 129.88 14.22 0.33 0.05 16.02 191 White Oaks 0.19 0.05 61.87 1.33 0.23 4.95 69 Commercial Developed Park Golf Course High Density Residential Highway Industrial/ Office Institutional Institutional - High Imperviousness Low Density Residential Medium Density Residential Natural/Park/ Open Open Water Other Very Low Density Residential Wetland Maximum 248 51 264 62 44 255 97 21 369 61 104 66 15 119 98 Minimum 0.02 0.003 0.07 0.01 1.24 0.05 0.004 3.95 0.26 0.03 0.08 0.05 1.35 4.42 0.18 Total Acres in Edina 683 315 602 272 404 456 312 52 5416 227 446 396 38 266 309 To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 8 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx 4.0 Results The average imperviousness for each land use type and the range of imperviousness among neighborhoods is shown in Figure 4. The imperviousness values assumed for the 2003/2011 CWRMPs are also shown in Figure 4. For some land use types such as Golf Course, Highway, Institutional, and Institutional – High Imperviousness, the 2016 analysis average value matches very closely with the 2003/2011 CWRMPs assumed value. For others, such as Commercial, High Density Residential, and Industrial/Office, the 2003/2011 CWRMPs assumed value is substantially higher when compared to the results of this 2016 analysis. For a few other land use types, such as Natural/Park/Open and Very Low Density Residential, the 2003/2011 CWRMPs assumptions appear to be low compared to the results of the 2016 analysis. Low and Medium Density Residential land use types both have wide ranges of imperviousness based on the 2016 analysis, and the 2003/2011 CWRMPs assumptions are on the high end of these new results. Open Water and Wetland land use types are 100% in both the 2003/2011 CWRMPs and this 2016 analysis; those will not change. Land use types Developed Park and Other were not used previously. The following figures (Figure 5 through Figure 17) show the resulting histograms of each of the land use types. Figure 4 - Average and range of imperviousness within all neighborhoods by land use type 0 10 20 30 40 50 60 70 80 90 100 0 10 20 30 40 50 60 70 80 90 100 Imperviousness (%)Maximum Minimum Average 2003/2011 CWRMPs To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 10 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 5 Percent impervious histogram of the Commercial land use type Figure 6 Percent impervious histogram of the Developed Park land use type 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Commercial; N = 27 Neighborhoods Total Commercial area in Edina = 683 acres 2003/2011 CWRMP Total Imp% = 90% 2003/2011 CWRMP Directly Connected Imp% = 80% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Developed Park; N = 27 Neighborhoods Total Developed Park area in Edina = 315 acres 2003/2011 CWRMP Total Imp% = N/A 2003/2011 CWRMP Directly Connected Imp% = N/A To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 11 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 7 Percent impervious histogram of the Golf Course land use type Figure 8 Percent impervious histogram of the High Density Residential land use type 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Golf Course; N = 13 Neighborhoods Total Golf Course area in Edina = 602 acres 2003/2011 CWRMP Total Imp% = 5% 2003/2011 CWRMP Directly Connected Imp% = 2% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) High Density Residential; N = 12 Neighborhoods Total High Density Residential area in Edina = 272 acres 2003/2011 CWRMP Total Imp% = 70% 2003/2011 CWRMP Directly Connected Imp% = 40% To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 12 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 9 Percent impervious histogram of the Highway land use type Figure 10 Percent impervious histogram of the Industrial/Office land use type 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 7 8 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Highway; N = 25 Neighborhoods Total Highway area in Edina = 404 acres 2003/2011 CWRMP Total Imp% = 50% 2003/2011 CWRMP Directly Connected Imp% = 50% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Industrial/Office; N = 13 Neighborhoods Total Industrial/Office area in Edina = 456 acres 2003/2011 CWRMP Total Imp% = 90% 2003/2011 CWRMP Directly Connected Imp% = 80% To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 13 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 11 Percent impervious histogram of the Institutional land use type Figure 12 Percent impervious histogram of the Institutional – High Imperviousness land use type 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Institutional; N = 20 Neighborhoods Total Institutional area in Edina = 312 acres 2003/2011 CWRMP Total Imp% = 40% 2003/2011 CWRMP Directly Connected Imp% = 20% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 0.5 1 1.5 2 2.5 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Institutional -High Imperviousness; N = 5 Neighborhoods Total Institutional -High Imperviousness area in Edina = 52 acres 2003/2011 CWRMP Total Imp% = 70% 2003/2011 CWRMP Directly Connected Imp% = 50% To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 14 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 13 Percent impervious histogram of the Low Density Residential land use type Figure 14 Percent impervious histogram of the Medium Density Residential land use type 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 2 4 6 8 10 12 14 16 18 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Low Density Residential; N = 41 Neighborhoods Total Low Density Residential area in Edina = 5416 acres 2003/2011 CWRMP Total Imp% = 40% 2003/2011 CWRMP Directly Connected Imp% = 20% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Medium Density Residential; N = 17 Neighborhoods Total Medium Density Residential area in Edina = 227 acres 2003/2011 CWRMP Total Imp% = 55% 2003/2011 CWRMP Directly Connected Imp% = 30% To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 15 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 15 Percent impervious histogram of the Natural/Park/Open land use type Figure 16 Percent impervious histogram of the Other land use type 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 1 2 3 4 5 6 7 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Natural/Park/Open; N = 29 Neighborhoods Total Natural/Park/Open area in Edina = 446 acres 2003/2011 CWRMP Total Imp% = 2% 2003/2011 CWRMP Directly Connected Imp% = 0% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Other; N = 8 Neighborhoods Total Other area in Edina = 38 acres 2003/2011 CWRMP Total Imp% = N/A 2003/2011 CWRMP Directly Connected Imp% = N/A To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 16 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 17 Percent impervious histogram of the Very Low Density Residential land use type Table 4 shows the fraction of the area throughout the city in which the imperviousness from this 2016 analysis is below the assumptions used for the 2003/2011 CWRMPs. In other words, high numbers in Table 4 suggest that the previously used assumptions are conservative with respect to runoff volume because they may be overestimating the imperviousness of the land use type in some areas within Edina. Percentages in Table 4 around 40% to 50% suggest that imperviousness is underestimated for about half the area, and therefore, overestimated for the other half of the area. Low percentages in Table 4 (e.g., Very Low Density Residential) suggest that the previous assumptions in the 2003/2011 CWRMPs for associated land use types may be too low, and consideration should be given for increasing those imperviousness values. Table 4 Percent of total area of Edina where new average imperviousness value is below 2003/2011 CWRMP values Land Use Type Percent of Area below 2003/2011 CWRMP Imperviousness value Commercial ~100% Developed Park Not previously used Golf Course ~44% High Density Residential ~100% Highway ~41% Industrial/Office ~100% Institutional ~60% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 0 0.5 1 1.5 2 2.5 0% - 5%5% - 10%10% - 15%15% - 20%20% - 25%25% - 30%30% - 35%35% - 40%40% - 45%45% - 50%50% - 55%55% - 60%60% - 65%65% - 70%70% - 75%75% - 80%80% - 85%85% - 90%90% - 95%95% - 100%Fraction of Total Land Use AreaNumber of NeighborhoodsPercent Impervious (U of M 2011 data) Very Low Density Residential; N = 6 Neighborhoods Total Very Low Density Residential area in Edina = 266 acres 2003/2011 CWRMP Total Imp% = 12% 2003/2011 CWRMP Directly Connected Imp% = 8% To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 17 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Land Use Type Percent of Area below 2003/2011 CWRMP Imperviousness value Institutional - High Imperviousness ~60% Low Density Residential ~100% Medium Density Residential ~98% Natural/Park/Open < 18% Open Water ~100% Other Not previously used Very Low Density Residential < 10% Wetland ~100% A discussion of the results for four different land use types is presented here to provide guidance for interpreting the results. • Open Water: This land use type, by definition is 100% impervious. Therefore, the imperviousness values of this 2016 analysis match the 2003/2011 CWRMPs and do not need to be adjusted. • Commercial: There are 27 neighborhoods that contain the Commercial land use type. The total area of Commercial land use is about 680 acres, with nearly 250 acres of Commercial land use falling within the Southdale neighborhood. There are five neighborhoods with imperviousness less than 60%, and there is one neighborhood with imperviousness greater than 90%. However, those extremes comprise only about 13 acres of the 680 total acres of Commercial land use. Close to 50% of the area of Commercial land use is less than 80% impervious, and about 90% of the Commercial land use area is below 85% impervious. Finally, essentially all of the Commercial land use area is less than 90% impervious. Therefore, the assumption of 90% impervious used in the 2003/2011 CWRMPs for Commercial land use may be overestimated. Alternatively, 90% impervious can be thought of as a conservative assumption with respect to runoff volume. • Institutional: There are 20 neighborhoods that contain the Institutional land use type. The total area of Institutional land use is about 310 acres, with nearly 190 acres of Institutional land use within the Concord, Countryside, and Creek Valley neighborhoods. There is one neighborhood with imperviousness less than 20%, and there are two neighborhoods with imperviousness greater than 70%. However, those extremes comprise only about 13 acres of the 310 total acres of Institutional land use. Roughly 60% of the area of Institutional land use is less than 40% impervious. Therefore, the assumption of 40% impervious used in the 2003/2011 CWRMPs for Institutional land use is right in the middle of the imperviousness results of the 2016 analysis. • Very Low Density Residential: There are six neighborhoods that contain the Very Low Density Residential land use type. The total area of Very Low Density Residential land use is almost 270 acres, with about 230 acres of Very Low Density Residential land use within the Indian Hills, Indian Trails, and Parkwood Knolls neighborhoods. The three neighborhoods between 15% and 25% impervious make up about 85% of the Very Low Density Residential area. Close to 50% of the total area of Very Low Density Residential land use is less than about 20% impervious, and about To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 18 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx 95% of the Very Low Density Residential land use area is below 25% impervious. There are no neighborhoods with imperviousness less than 12%. Therefore, the assumption of 12% impervious used in the 2003/2011 CWRMPs for Very Low Density Residential land use may be underestimated which is consistent with the assumption that increasing development has impacted imperviousness. However, the increase in imperviousness does not appear to be significant enough to make the imperviousness values for this land use type consistent with the imperviousness values for the Low Density Residential land use type. There is still a difference in the imperviousness values of these two land use types. 5.0 Conversion from Total Imperviousness to Directly Connected Imperviousness Sections 1.0 – 4.0 of this memo have discussed total imperviousness for each land use type. However, what is important for hydrologic modeling is the directly connected imperviousness which is similar to effective impervious area. A July 2015 report on effective impervious area suggests that these terms are slightly different (reference [4]). The report describes how the effective impervious area is usually less, about 80% to 90% of the directly connected impervious area. Two possible approaches for converting from total to directly connected imperviousness are listed below. First, the simplest approach for converting the total imperviousness described in Section 4.0 to directly connected imperviousness is to simply use the same conversion ratios (ratio of directly connected to total) used in the 2003/2011CWRMPs as shown in Table 1 and then apply some engineering judgment to the results. For example, if the total imperviousness of Commercial land use was changed from 90% to 80%, and the same ratio was then used to convert total imperviousness to directly connected imperviousness (0.889), the result for Commercial land use would be 71%, or potentially rounded to 70% directly connected imperviousness. Second, an alternative method is proposed in a report by John Gulliver and others at the University of Minnesota (reference [4]). The proposed method of determining the directly connected impervious area fraction in ungauged urban watersheds is summarized in the following steps: • Extract total imperviousness from land use and the hydrologic soil groups from the SSURGO data set and calculate the weighted average saturated hydraulic conductivity of the soil. • Estimate the actual curve number of the watershed as a function of total imperviousness and the saturated hydraulic conductivity. • Determine the fraction of effective impervious area as a function of the actual curve number. • Assume that the effective impervious area is roughly 85% of the directly connected impervious area, and scale up the values to account for this difference with a factor of 1.176 (or 0.85-1). To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 19 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx The approach suggested in the paper by Gulliver could be followed to determine the directly connected impervious area for the purposes of the 2017 XP-SWMM modeling. However, there are some concerns about the applicability of the paper to this modeling. First, much of the method relies on regression equations that do not account for the spread in the data and the error bars, which appear to be relatively significant. Second, the suggested approach is likely more useful for simpler hydrologic modeling methods, such as the rational method. In XP-SWMM, hydrologic factors such as depression storage and infiltration parameters based on soil type are treated as independent inputs. In the method described in the paper, it appears that these other hydrologic factors are implicitly included in the estimated value of effective impervious area. Therefore, we do not recommend using this approach to estimate imperviousness for the 2017 XP-SWMM modeling. 6.0 Consequences and Risks Understanding the consequences and risks of over- or under-estimating the imperviousness can help determine an appropriate value for each land use type in the city of Edina. Figure 18 is a simple diagram to help illustrate this decision making process. Currently, there is a range of imperviousness throughout the city, and it varies by land use type (residential versus commercial versus park space, etc.). Accounting for the trend that the city is becoming more impervious, it is reasonable to expect that in the near future, the imperviousness will be higher than what it is today. However, with policies and regulations being put in place to limit the increase in imperviousness and to offset any additional imperviousness being created (e.g., using stormwater BMPs), the long term outlook is much more uncertain. If the current imperviousness is used in the modeling for the 2017 CWRMP, then the risk is that it will likely be outdated and too low in the near future. The consequence is that flooding of structures may increase, stormwater infrastructure may be undersized, and the level of service provided by the City will decrease creating frustration within the community. If the current trend of increasing imperviousness is extended into the future, the risk is that the imperviousness will be overestimated. The consequence is that more locations may be identified as flood risk locations and may require expensive updates to infrastructure. The flooding of structures may decrease because the stormwater infrastructure will generally be oversized. The level of service will increase, but it will come at a significant and potentially unnecessary cost to the community. Finally, choosing an imperviousness value that is higher than the current average, but one that captures the current trend of increasing imperviousness without extending it too far into the future may be the best selection. Risk of over- or under-estimating the imperviousness still exists, but the consequences may be less because the error in the selected value will likely be less. Therefore, for each land use type, selecting a value that is higher than 80% to 90% of the total area of that land use type is expected to be a reasonably protective, yet still accurate value. To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 20 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx Figure 18 Total imperviousness estimation; consequences and risks diagram current status likely future ??? current trend low total imperviousness high Consequences and risks •Flood risk •Infrastructure size •Level of service current range of imperviousness likely near future range of imperviousness To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 21 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx 7.0 Conclusions An analysis of the imperviousness throughout the city of Edina for multiple land use types was completed using the most recent available imperviousness data set. For some of the land use types, the imperviousness has historically been over- or under-estimated, and for others, the current value has been estimated very well. The values for total imperviousness were updated based on the 2016 imperviousness analysis and consideration of the risks and consequences presented in the previous section. Recommended total imperviousness values for stormwater modeling associated with the 2017 CWRMP are listed in Table 5. Additionally, after discussion with City staff concerning the trends in residential development throughout the city, recommendations for updates to the directly connected imperviousness are also presented in Table 5. For most of the land use types, the recommended total imperviousness for the 2017 CWRMP is at or above the average imperviousness of the 2016 analysis. The two exceptions to this are the “Natural/Park/Open” and “Other” (essentially a railroad corridor) land use types. In both cases, these land use polygons tend to be small and narrow and the analysis was highly affected by the adjacent land use polygons which were often Industrial/Office or Commercial and were raising the average imperviousness. A closer look at the aerial imagery within the small and narrow land use polygons representing Natural/Park/Open and Other justifies using lower numbers for the total imperviousness. Table 5 Summary of imperviousness values and recommendation for impervious assumptions for the 2017 CWRMP update Land Use Type Total Area (acres) Imperviousness Value Assumptions (%) 2003/2011 CWRMPs 2016 Imperviousness Analysis Recommended for 2017 CWRMP Total Directly Connected Total (Range) Total (Average) Total Directly Connected Commercial 683 90% 80% 37% - 91% 78% 85% 80% Developed Park 315 not previously used 0% - 68% 19% 30% 20% Golf Course 602 5% 2% 0% - 40% 5% 5% 2% High Density Residential 272 70% 40% 39% - 73% 59% 65% 50% Highway 404 50% 50% 38% - 72% 54% 65% 65% Industrial/Office 456 90% 80% 52% - 83% 72% 75% 75% Institutional 312 40% 20% 17% - 75% 42% 60% 30% Institutional - High Imperviousness 52 70% 50% 56% - 85% 72% 80% 70% Low Density Residential 5,416 40% 20% 21% - 60% 32% 40% 25% Medium Density Residential 227 55% 30% 3% - 77% 43% 50% 40% Natural/Park/Open 446 2% 0% 0% - 35% 11% 2% 0% Open Water 396 100% 100% N/A 100% 100% 100% Other 38 not previously used 16% - 45% 32% 20% 20% Very Low Density Residential 266 12% 8% 13% - 29% 20% 25% 15% Wetland 309 100% 100% N/A 100% 100% 100% To: Jessica Wilson and Ross Bintner From: Cory Anderson, Sarah Stratton, and Janna Kieffer Subject: City of Edina Imperviousness Assumptions for Stormwater Modeling Date: October 25, 2016 Page: 22 P:\Mpls\23 MN\27\23271514 2017 CWRMP SW Modeling Updates\WorkFiles\Imperviousness Analysis\Imperviousness Analysis Summary.docx 8.0 References [1] Remote Sensing and Geospatial Analysis Laboratory, University of Minnesota, Marvin Bauer, "Twin Cities Metropolitan Area Land Cover Classification and Impervious Surface Area by Landsat Remote Sensing: 2011 Update," St. Paul, MN, 2011. [2] City of Edina, "Neighborhood Layer," Edina, MN, 2016. [3] City of Edina, "Land Use Data," 2000. [4] J. S. Gulliver, A. Ebrahimian and B. N. Wilson, "Determination of Effective Impervious Area in Urban Watersheds," Minnesota Department of Transportation, St. Paul, Minnesota, July, 2015. Appendix B Summary of Nine Mile Creek and Minnehaha Creek Modeling Approach Barr Engineering Co. 4300 MarketPointe Drive, Suite 200, Minneapolis, MN 55435 952.832.2600 www.barr.com Technical Memorandum To: Jessica Vanderwerff Wilson and Ross Bintner From: Cory Anderson and Sarah Stratton Subject: History of Nine Mile Creek and Minnehaha Creek Model Development and Incorporation of Tailwater Conditions into the Edina XP-SWMM models Date: September 22, 2017 Project: 23/27-1514.00 c: Janna Kieffer The City of Edina updated its Comprehensive Water Resources Management Plan (CWRMP) in 2017. As part of this update, 10 previously developed XP-SWMM models of the city were updated. The storm sewer data (City’s GIS layer provided in June 2016), soils information (2012 Natural Resources Conservation Service Soil Survey Geographic (SSURGO) data), imperviousness (reflecting 2011 University of Minnesota imperviousness raster data), and watershed divides and detention storage (2011 Minnesota DNR LiDAR) were all updated in the XP-SWMM models to reflect newer data. In addition to updating the data in the 10 XP-SWMM models that cover the city, the models were merged together so that there is now one model covering the areas of Edina draining to Nine Mile Creek, and one model covering the areas of Edina draining to Minnehaha Creek. The details of the model construction are described in the 2017 CWRMP. This memo provides some historical context for how Nine Mile Creek and Minnehaha Creek were previously modeled and also describes the methodology used to account for each creek within the City of Edina XP-SWMM modeling updated for the 2017 CWRMP. 1.0 Nine Mile Creek Methodology An XP-SWMM model of Nine Mile Creek was developed by Barr in 2005 for the Nine Mile Creek Watershed District to determine the 1%-annual-chance flood (100-yr flood) elevations along the creek. Due to the large size of the Nine Mile Creek watershed (~50 square miles) and the detail of the modeling to be done (e.g. 3065 subwatersheds), the study area was split into 15 different “city” models and one creek model. Watershed drainage divides (subwatersheds) were delineated using 2-foot topography data provided by each of the cities that the creek flows through, with the exception of the South Fork of Nine Mile Creek that passes through the City of Eden Prairie. The City of Eden Prairie did not have 2-foot topography data at the time the model was developed, therefore watersheds delineated for that portion of the model are less detailed. For the entire stretch of the creek itself, surveyed cross-sections were used to estimate the To: Jessica Vanderwerff Wilson and Ross Bintner From: Cory Anderson and Sarah Stratton Subject: History of Nine Mile Creek and Minnehaha Creek Model Development and Incorporation of Tailwater Conditions into the Edina XP-SWMM models Date: September 22, 2017 Page: 2 backwater effects of the bridges and culverts and to reflect variations in the stream valley topography. All of the cross-sections within the different reaches of Nine Mile Creek were surveyed within the channel banks and extended on the floodplain using 2-foot topography to define the changes in slopes for the large overbank areas. In the City of Eden Prairie where 2-foot topography data was unavailable, full cross- sections (stream channel and overbanks) for that stretch of the creek were surveyed. Road crossing information was obtained primarily through survey; plan sheets were reviewed as available. Loss coefficients for bridges, other channel obstructions, channel roughness, and overbank roughness (Manning’s “n”) were estimated by field inspection and photographs. Lakes and large wetland areas that have a consistent water surface elevation along Nine Mile Creek were modeled as storage areas in the XP- SWMM model. The peak flood flow that was predicted by the XP-SWMM model was compared to the expected peak flow using the National Flood Frequency Program (NFF) regional regression analysis on Nine Mile Creek as a QA/QC measure. Flows were compared on the north fork of Nine Mile Creek at Highway 169, Highway 62, and Interstate 494. The peak flows calculated for the three different locations using the regional regression were all within 11% of the peak hydraulically routed flow calculated using XP-SWMM. Since the standard error for the 1%-annual-chance recurrence interval using NFF is 54%, the flows calculated by XP-SWMM are reasonable. Two other precipitation events were used to calibrate and validate the model. The calibration event was in April 2004, and the amount of precipitation varied throughout the watershed. Therefore, average precipitation amounts were calculated by major watershed and were used in the appropriate models. Flows for the calibration event were compared to monitored flows at four different locations throughout the watershed—one location on the North Fork of the Creek, one location on the South Fork of the Creek, and two locations on the Lower Valley portion of the Creek (below the confluence of the North Fork and South Fork). The validation event was in June 2003 and the amount of precipitation was also varied throughout the watershed. Therefore, average precipitation amounts were calculated by major watershed and were used in the appropriate models. The water surface elevation for the validation event was also compared to a monitored water surface elevation at Normandale Lake (the confluence of the North Fork and South Fork of Nine Mile Creek). Simulating storm events using 15 different city models and one creek model required an iterative process to account for overflows and tailwater conditions between models. Each city model had numerous points of outflow into the creek. XP-SWMM creates a hydrograph at each outflow point and each outflow point from the city model was assigned an inflow point in the creek model. Since some of the inflow points had several outflow points attached to it (not a 1:1 ratio) it was necessary to sum the hydrographs created To: Jessica Vanderwerff Wilson and Ross Bintner From: Cory Anderson and Sarah Stratton Subject: History of Nine Mile Creek and Minnehaha Creek Model Development and Incorporation of Tailwater Conditions into the Edina XP-SWMM models Date: September 22, 2017 Page: 3 by XP-SWMM. An Excel macro was used to sum hydrographs so there would be one hydrograph for each inflow point into the creek. The hydrographs were input into the creek model as text files. In some of the city models, there was overflow out of the model into a different city model. These points were treated similar to the outflow into the creek. A hydrograph was created by XP-SWMM and then imported into the downstream city model. In cases where more than one overflow went into a single downstream system, the hydrographs were summed. For larger events (100-yr and 500-yr) it was necessary to consider the tailwater elevation in the creek. When the creek model was run XP-SWMM saved the elevation versus time data for each node that had inflow from a city model. These elevations were imported back into the city models at locations where there was outflow to the creek. This replaced the original downstream condition (free outfall) with the actual downstream elevation in the creek at that outlet. The city models then needed to be re-run to determine new hydrographs. The hydrographs were again summed where necessary and imported into the creek model. The creek model was re-run, and a new tail-water file was created. The process was repeated until the elevation in the creek stabilized. The model of Nine Mile Creek (including all of the associated city models) was updated by Barr in 2014 to reflect Atlas 14 precipitation depths. Faster computing times and newer versions of XP-SWMM have now made it more feasible to combine the city models and creek model into one model. Prior to combining the models (for this 2017 CWRMP update), the modeling connection between Nine Mile Creek and the XP-SWMM models of the city was time-consuming and required iterations between model runs to properly determine boundary conditions. Therefore, to remove the iteration process that was necessary, the nodes and links of the Nine Mile Creek model were merged directly into the city model. This created one complete model of the areas of Edina draining to Nine Mile Creek including the creek itself, extending from Hopkins northwest of Edina down through Bloomington southeast of Edina. However, the input data associated with the creek nodes and links was not updated with any new data. Because the creek nodes and links were included in the overall city model contributing to Nine Mile Creek, the modeled storm events could be routed through all of the runoff nodes in the model to determine the runoff hydrographs, and through the hydraulic layer nodes and links to route the storm events through both the creek and the city. The iteration process is no longer necessary to determine flood levels in the creek or in the nodes adjacent to the city that might be affected by creek tailwater levels. To: Jessica Vanderwerff Wilson and Ross Bintner From: Cory Anderson and Sarah Stratton Subject: History of Nine Mile Creek and Minnehaha Creek Model Development and Incorporation of Tailwater Conditions into the Edina XP-SWMM models Date: September 22, 2017 Page: 4 2.0 Minnehaha Creek Methodology The previous XP-SWMM models developed for the city of Edina did not account for tailwater conditions from Minnehaha Creek. Previously, any areas of Edina that drained to Minnehaha Creek through storm sewer assumed that those areas could freely drain to the creek. This assumption may reflect actual conditions for some areas along the creek and/or for some shorter duration storm events, but may not be true for other lower-lying areas adjacent to the creek or for longer duration storm events. The XP-SWMM models of Minnehaha Creek and its upstream contributing area were developed by EOR for the Minnehaha Creek Watershed District (MCWD) in 2003. The methodology used for developing these models is provided on MCWD’s website (Hydrologic, Hydraulic, and Pollutant Loading Study, 2003). For this 2017 CWRMP modeling effort, the Minnehaha Creek XP-SWMM models were provided by Wenck (MCWD’s engineer) in August 2016. Wenck provided two XP-SWMM models – one for the Upper Watershed of Minnehaha Creek (the upper watershed down to Lake Minnetonka at Gray’s Bay Dam) and one for the stretch of Minnehaha Creek below Lake Minnetonka at Gray’s Bay Dam). The Upper Watershed model determines the outflow from Lake Minnetonka to Minnehaha Creek. The models provided by Wenck used TP-40 1%-annual-chance precipitation event inputs. Barr then updated the two Minnehaha Creek models with the Atlas 14 1%-annual-chance precipitation event to be consistent with the Atlas 14 1%-annual-chance precipitation event depths and nested distribution used for the other Edina XP-SWMM models. The two Minnehaha Creek models provided by Wenck were also re-run for other events (Atlas 14 10%-annual-chance precipitation and 1%-annual-chance snowmelt). No other model changes were made. The separation of the models has been maintained (i.e., the Minnehaha Creek model provided by Wenck is not combined with the City of Edina model). Therefore, to account for Minnehaha Creek tailwater conditions, user-defined stage hydrographs were extracted from the Minnehaha Creek model for each modeled event and were included as downstream boundary conditions at all model node locations where Edina subwatersheds drain to Minnehaha Creek. Appendix C Legacy Flood Protection Projects Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-1 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Nine Mile Creek-North 5.3.1.1 Hawkes Drive (HL_2) Hawkes Drive is a cul-de-sac on the east side of Hawkes Lake. A low area exists along this street, south of the intersection with Hawkes Terrace. Two catch basins are located in this low area, which connect to the 12-inch storm sewer system that discharges into Hawkes Lake. During the 100-year frequency storm event, the 12-inch storm sewer does not provide enough capacity and street flooding occurs in the low area along Hawkes Drive to an elevation of 902.3 MSL. Based on the 2-foot topographic information, flood waters from the street will flow west via overland flow toward the Lake at an elevation above 902 MSL. To ensure that the flooding does not encroach upon the homes at 5713 and 5717 Hawkes Drive, a positive overland flow swale should be constructed between the homes. Addressed in 2012 Street reconstruction with 4 inlets and a 12” RCP to 18” HDPE pipe burst improvement. 5.3.1.2 5711 & 5717 Grove Street (HL_18) A depression area exists in the backyards of 5711 and 5717 Grove Street. Stormwater from a 3-acre subwatershed (HL_18) drains to this depression area. A 21-inch storm sewer system runs through the backyard area and flows northward to Grove Street. A beehive structure is located at the low point in the backyard area to collect the stormwater. During the 100-year frequency storm event, the 21-inch system does not provide sufficient capacity, and water pools in the backyard depression area. The predicted 100-year frequency flood elevation is 904.4 MSL. This flood elevation is slightly higher than the low house elevations for 5711 and 5717 Grove Street, which were surveyed at 903.6 MSL and 903.5 MSL, respectively. To decrease the 100-year frequency flood elevation in the backyard depression area and provide a 100-year level of protection, it is recommended that the 21-inch pipe system spanning from the backyard depression area to Grove Street be upgraded to 24-inch pipes. This change would decrease the calculated 100-year flood elevation to 903.5 MSL without causing negative effects upstream or downstream. This flood issue was evaluated as part of the 2015 street reconstruction project. Pipes were upsized in 2015 Countryside H Neighborhood Roadway Improvement (ENG 15-4). Improvement included a 21”RCP to 24” pipe burst and upsize to 28” RCP arch pipe. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-2 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 5.3.1.3 5516 & 5520 Dundee Road (HL_25) West of 5516 and 5520 Dundee Road, a depression area is located that collects stormwater during precipitation events. Due to past flooding problems, a lift station was installed in this backyard area to pump stormwater east to Dundee Road, where the stormwater flows southward down Dundee Road until it reaches the gravity storm sewer system. The current lift station has a pumping capacity of approximately 150 gpm. For the XP-SWMM analysis, the available storage volume in the backyard depression area and the elevation at which the pump turns on/off were based on the 2-foot topographic data. Based on this information, the calculated 100-year frequency flood elevation is 897.2 MSL. This elevation is higher than the surveyed low house elevations for 5516 and 5520 Dundee Road, 894.26 MSL and 895.67 MSL, respectively. Comparison of the field survey data with the 2-foot topographic data leads to uncertainty of the accuracy of the topographic information in this area. It is recommended that a detailed field survey be performed to determine the accuracy of the topographic data and storage assumptions in this area. If it is determined that the topographic data used was accurate, it is recommended that additional pump capacity be added to the lift station to prevent the structures at 5516 and 5520 Dundee Road from incurring flood damage. Another option to alleviate flooding in the backyard depression area is to create a positive overland flow swale toward the pond that is located approximately 400 feet north of the 5516 Dundee Road property. Based on the 2-foot topographic data, the overland flow swale would begin near the property line between 5516 and 5512 Dundee Road. There have not been any studies or improvements completed for this area. Considered for study as part of STS-406, but dropped due to cost. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-3 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 5.3.1.4 505, 509, & 513 Tyler Court (ML_19) An inundation area is located east of the homes along Tyler Court, south of Maloney Avenue and west of Arthur Street. Stormwater runoff from a drainage area of approximately 29 acres discharges into this dry basin. A 24-inch storm sewer system drains this area. The 24-inch system flows south and west to Arthur Street, then south to the intersection of Arthur Street and Waterman Avenue. At this intersection, the pipe flowing east toward Mirror Lakes is reduced to an 18-inch pipe. Due to the restricted pipe capacity at Arthur Street and Waterman Avenue, flow in the system draining the dry basin reverses during intense rainfall events such as the 100-year frequency event, and the basin is inundated. During the 100-year frequency storm event, the dry basin reaches a flood elevation of 936.6 MSL. This flood elevation is considerably higher than the low house elevations at 505, 509, and 513 Tyler Court, surveyed at 932.9 MSL, 933.1 MSL, and 934.07 MSL, respectively. To alleviate a portion of the flooding problem, it is recommended that the 18-inch pipe flowing east from the Arthur Street and Waterman Avenue intersection be upgraded to a larger pipe. By upgrading to a 24-inch pipe, runoff from Waterman Avenue and Arthur Street will not back up into the dry pond and the 100-year frequency flood elevation of the pond would decrease to 934.7 MSL. To further alleviate the flooding problem, it will be necessary to perform a more detailed analysis on the system that drains the backyard inundation area. No studies or improvements completed to date. Included as a current flood protection project in Section 5.3.1.1. 5.3.1.5 6009 Leslee Lane (MD_22) A backyard depression area exists between the properties on the south side of Leslee Lane and north side of Kaymar Drive. The depression area collects stormwater from a drainage area of approximately 6.4 acres. A 15-inch storm sewer system extends southward into the backyard depression area from Leslie Lane, collecting stormwater from the low area, and continues to the west toward Jeffrey Lane. This system eventually connects with the Blake Road system at the intersection of Blake Road and Kaymar Drive. During the 100-year frequency storm event, flow is restricted in the 15-inch system and water pools in the backyard depression area behind 6009 Leslee Lane. The predicted 100-year frequency flood elevation in this area is 916.7 MSL. Based on the 2-foot topographic data, it appears that this flood elevation will impact the structure at 6009 Leslee Lane. To alleviate the backyard flooding and prevent property damage at 6009 Leslie Lane, it is recommended that the 15-inch pipe draining the backyard depression and the downstream 18-inch pipe be upgraded to 24-inch diameter pipes. This would result in a predicted 100-year frequency flood elevation of 915.8 in the backyard depression area. There have not been any studies or improvement projects completed for this area. Included as a current flood protection project in Section 5.3.1.2. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-4 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 5.3.1.6. 5316 Schaefer Road (MD_28) A small, 0.5-acre stormwater detention pond is located just northwest of the intersection of Schaefer Road and Parkwood Road. The outlet to the pond is a 12-inch system that drains south to Parkwood Road and then east toward Blake Road. During the peak of the 100-year frequency storm, the flow in the 12-inch system is reversed and all the stormwater from subwatershed MD_28 and MD_48 flows into the pond. As the water elevation of the pond increases to an elevation of approximately 938 MSL during storm events, water will overtop Schaefer Road and flow east through a drainage swale that leads to another stormwater detention basin. However, before the flood water from the pond overtops the road, the pond will extend well into the yard of 5316 Schaefer Road, encroaching upon the structure. The 100-year frequency flood level of the pond is 939.0 MSL. Although based on the 2-foot topographic data it appears that the structure at 5316 Schaefer Road will not be affected by a 100-year rainfall event, it is recommended that an overflow across the road be maintained or slightly lowered during any future road improvement projects in this area. There have not been any studies or improvement projects completed for this area. Included as a current flood protection project in Section 5.3.1.3. 5.3.1.7 Fountain Wood Apartments (NMN_90 & NMN_23) The NMN_90 subwatershed encompasses an area of approximately 3 acres. The subwatershed includes the townhomes on Wellesley Place north of Vernon Avenue and a portion of the Fountain Woods apartment complex. The low spot in the watershed is located in the southwest corner of the Fountain Woods parking lot, near the parking entrance/exit for buildings 6650 and 6710. During the 100-year frequency storm event, stormwater pools in this area, reaching a flood elevation of 876.6 MSL. Field survey data indicates that this flood elevation will impact the two garage entrances for buildings 6650 and 6710, both recorded at 872.1 MSL. The Fountain Woods Apartments drainage system is a privately maintained drainage system. It is recommended that the owners of the apartment complex be notified of this potential problem and recommend that they may wish to make modifications to their system to alleviate potential flooding problems. There have not been any studies or improvement projects completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-5 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Nine Mile Creek-Central 6.3.1.1 6005 & 6009 Crescent Drive (manhole 457) Stormwater runoff from subwatershed NMC_110 collects at a low area along Crescent Drive. Stormwater is collected at two catchbasins located on both sides of the street at 6013 Crescent Drive and flows eastward through an 18-inch storm sewer that connects with the trunk system that flows south along the SOO Line railroad tracks. During intense rainstorms, such as the 100-year frequency event, flow through the 18-inch system is restricted due to high flows entering the larger trunk system from the east. Due to the restricted flow, water pools in the street along Crescent Drive and eventually overtops the street and flows eastward between the homes toward a backyard depression area behind the homes of 6001, 6005, 6009, and 6013 Crescent Drive. As a result of the overland flow from Crescent Drive, this backyard depression area becomes inundated. The 100-year frequency flood elevation within this depression area is 903.0 MSL. This flood elevation is higher than the low house elevations at 6005 and 6009 Crescent Drive, which were surveyed at 902.2 MSL. Based on the 2-foot topographic information, it appears that water in the backyard depression area will drain southward through a ditch along the west side of the railroad tracks, once it reaches elevation of 902.6 MSL. To alleviate the flooding potential, it is recommended that a gravity channel be constructed from the depression area to the ditch along the west side of the railroad tracks at an elevation lower than the low house elevation of 902.2 MSL. This will allow the depression area to drain and alleviate flooding at 6005 and 6009 Crescent Drive. Barr modeled proposed upsizing, but it made very little difference due to high tailwater. This flood issue was evaluated as part of the 2012 street reconstruction project. Pipes were upsized in 2012 Countryside Neighborhood Reconstruction (ENG 12-3). Ponding in the low area along the railroad tracks was reviewed in relation to the Forslin Pond/Birchcrest Pond analysis conducted prior to the 2017 street reconstruction project. The recommendation stands (but details/elevations should be re-evaluated, as well as potential downstream impacts). 6.3.1.2 Cherokee Trail & Gleason Backyard Depression Area (IP_4) A backyard depression area exists east of Cherokee Trail, just southwest of the intersection of Cherokee Trail and Gleason Road. This is currently a land-locked area. During the 100-year frequency storm event, the flood elevation in this backyard area reaches 887.8 MSL. This flood elevation is slightly higher than the low house elevation at 6529 Cherokee Trail, which was surveyed at 887.34 MSL. To alleviate this flooding problem, it is recommended that a low level outlet be constructed. There have not been any studies or improvement projects completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-6 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 6.3.1.3 5339 West 64th Street (NMC_80) A backyard depression area exists south of West 64th Street and west of Ridgeview Drive, just east of the SOO Line railroad tracks. Stormwater from the direct subwatershed (NMC_80) and overflow from West 64th Street collects in the depression area, where it enters an 18-inch storm sewer system through an intake structure. During the 100-year frequency storm event, the backyard depression is inundated with stormwater and the flood elevation rises to 875.7 MSL. This flood elevation is slightly higher than the low house elevation at 5339 West 64th Street, surveyed at 875.4 MSL. To alleviate the flooding problem and provide a 100-year level of protection, it is recommended that the two 18-inch pipes (pipes 293 and 294) that connect the backyard depression area to the storm sewer system at the intersection of Ridgeview Drive and Valley Lane be upgraded to 24-inch pipes. This upgrade would result in a 100-year flood elevation of 875.3 MSL, thus lower than the low house elevation at 5339 West 64th Street. There have not been any studies or improvement projects completed for this area. 6.3.1.4 Valley View Road & Hillside Road (NMC_86, NMC_120) The streets and homes in the area around the intersection of Valley View Road and Hillside Road are situated in a low depression area. Storm sewer in this area collects the stormwater, which flows southward underneath T.H. 62, and eventually connects with the SOO Line railroad system and discharges into the North Fork of Nine Mile Creek. During large rain events, such as the 100-year frequency event, the capacity of the storm sewer system in this area is inadequate, and this area and the nearby ditch on the north side of T.H. 62 are inundated with stormwater. The 100-year flood elevation is 862.0 MSL for subwatersheds NMC_86 and NMC_120. Based on the 2-foot topographic information, these flood elevations will affect several structures in the area, including 6309 and 6313 Hillside Road and 6328 Valley View Road. Flooding problems have historically been encountered in this area. Past analysis of the problem concluded that no solutions to the problem were feasible. However, the flood elevations in this area can be decreased by upgrading the 24-inch pipe that spans from Valley View Road to the north ditch of T.H. 62 (pipe 303p) to a 36-inch pipe. This would decrease the 100-year frequency flood elevations of NMC_86 and NMC_120 to 859.9 MSL and 860.2 MSL, respectively. This flood issue was evaluated as part of the 2012 Countryside street reconstruction project. Significant flooding occurred in this area as a result of the August 30-31, 1977 rainfall event (7+ inches of rainfall in a 4 hour time period), and a detailed analysis was completed following the flooding. At that time, they identified that the best solution would be for the City to consider purchasing the impacted homes, as options for remedying the problem through infrastructure improvements were extremely limited. Pipe upgrade options were evaluated in 2012, but made minimal impacts due to the high tailwater conditions in the MnDOT ROW. This issue was evaluated again in 2016 for ENG 17-5. Upsizing of existing pipes and installation of parallel pipes were analyzed and deemed infeasible as part of this project. Existing pipe sizes will be maintained with current reconstruction project. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-7 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 6.3.1.5 West 66th Street & Naomi Drive Area (NMC_71, NMC_103) Flooding problems have historically been encountered during intense rainstorms at the low-lying intersection of West 66th Street and Naomi Drive, as well as the in the backyard depression area in the rear of the homes on the east side of Naomi Drive. Stormwater overflow from the 66th Street and Naomi Drive intersection flows into the adjacent Normandale Park storage area (ball field). The intersection and ball field are eventually drained by a 33-inch trunk storm sewer system that flows northwest to the low area along Warren Avenue and eventually westward to the North Fork of Nine Mile Creek. Based on the XP-SWMM analysis, the 100-year flood elevation at the West 66th Street and Naomi Drive intersection (subwatershed NMC_71) and the adjacent storage area in Normandale Park reaches 864.8 MSL. The backyard depression area behind the Naomi Drive homes is drained by a 15-inch culvert that connects to the 15-inch storm sewer flowing north from Circle Drive Pond. During periods of intense rainfall, the flow in this system backs up, thus flowing southward into Circle Drive Pond. A flapgate has been installed on the culvert draining the backyard depression area to prevent backflow from inundating the area. However, with the flapgate closed, there is no outlet from this area and the backyard storage volume is not sufficient to prevent flooding of the structures along Naomi Drive. The 100-year frequency flood elevation for this depression area (subwatershed NMC_103) is 859.6 MSL. This flood elevation is over 2 feet higher than the low house elevation at 6605 Naomi Drive (857.7 MSL) and slightly less than 2 feet above the low house elevation at 6609 Naomi Drive (857.9 MSL). This flooding problem has been analyzed in the past and recommendations to alleviate the flooding were made, in which case some were implemented. However, the recommendation to add additional outlet capacity to the backyard depression area, via a pumped outlet to the Normandale Park storage area or a separate gravity system flowing west to the North Fork of Nine Mile Creek, has not yet been implemented. To ensure a 100-year level of protection, it is recommended that additional outlet capacity be provided for this area. If a pumped outlet is installed to drain the backyard area, it will be necessary to add additional storage capacity in Normandale Park. There have not been any studies or improvement projects completed for this area. Included as a current flood protection project in Section 6.3.1.3. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-8 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 6.3.1.6 6712, 6716, 6720 Ridgeview Drive (NMC_106) Subwatershed NMC_106 is a 3.3-acre drainage area, characterized by a drainage swale that extends for nearly 1,200 feet through numerous backyards between Ridgeview Drive and the SOO Line railroad tracts, flowing southward. The stormwater pools in a depression area behind 6712, 6716, and 6720 Ridgeview Drive. During large storm events such as the 100-year frequency rainstorm, this backyard area is inundated. The 100-year frequency flood elevation of this depression area is 845.9 MSL. Based on the 2-foot topographic data, this flood elevation will encroach upon the structures at 6712, 6716, and 6720 Ridgeview Drive. To alleviate this flooding problem, it is recommended that a gravity storm sewer system be installed that discharges stormwater from the backyard area to the North Fork of Nine Mile Creek. There have not been any studies or improvement projects completed for this area. Included as a current flood protection project in Section 6.3.1.2. 6.3.1.7 6808, 6812, 6816, 6820 Ridgeview Drive (NMC_107) A backyard depression area exists at the 6808, 6812, 6816, and 6820 Ridgeview Drive properties, just east of the SOO Line railroad tracks. The depression area is landlocked and thus becomes inundated with stormwater during large rainstorm events such as the 100-year frequency event. Flooding has historically occurred in this area. The 100-year frequency flood elevation in this backyard area is 843.6 MSL. Based on the 2-foot topographic data, this flood elevation will potentially affect structures at 6808, 6812, 6816, and 6820 Ridgeview Drive. To alleviate the flooding conditions in this backyard depression area, it is recommended that an outlet system be constructed to flow west and discharge to the floodplain of the North Fork of Nine Mile Creek. There have not been any studies or improvement projects completed for this area. Included as a current flood protection project in Section 6.3.1.2. Lake Cornelia/Lake Edina/Adam’s Hill 7.3.1.1 Swimming Pool Pond (NC_3)/North Lake Cornelia (NC_62) During the design process for the West 66th Street drainage improvements, a detailed analysis of the storm water system was performed that included the entire Lake Cornelia drainage area. The system was modeled based on several recommended improvements, many of which have been since implemented. One recommendation was to replace the 18-inch RCP pipe and orifice structure between the Swimming Pool Pond and North Lake Cornelia with a 42-inch equivalent RCP arch pipe. A 20-foot weir control structure was recommended to be installed at the inlet to this pipe. The overland flow elevation between these two areas was recommended to be lowered to 863.5 MSL This flooding area was re-evaluated in 2014-2015. City chose not to move forward because it required the raising of the 66th Street Causeway as an integral improvement so that risk wasn’t transferred to South Cornelia. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-9 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 7.3.1.2 Hibiscus Avenue (LE_53, LE_7, LE_10) Stormwater runoff from a 48.5-acre subwatershed (LE_53) collects at the intersection of Hibiscus Avenue and West Shore Drive. Along the south side of this intersection, two catchbasins connect to the 54-inch storm sewer system that discharges into Lake Edina. Due to the lack of inlet capacity at this intersection, the stormwater that does not enter the storm sewer system flows west along Hibiscus Avenue toward the low area near 4708, 4709, and 4713 Hibiscus Avenue. A separate storm sewer system exists at this low area along Hibiscus, with two catchbasins on the street to allow water into the system. This system extends upstream, collecting runoff from the backyard depression area behind 4708 and 4712 Hibiscus Avenue. During the 100-year frequency event, the low area in the street becomes inundated with stormwater runoff from the watersheds directly tributary to this system and from the excess runoff coming from West Shore Drive (subwatershed LE_53). The street flooding causes the system to back up and reverse flow into the backyard depression area. The 100-year flood elevation in the street and in the backyard depression area reaches approximately 831.1 MSL. This flood elevation has the potential to affect structures at 4704, 4708, 4712, 4716 Hibiscus Avenue on the north side and 4705 Hibiscus on the south side of the street. To alleviate this problem and ensure a 100-year level of protection is provided, it is recommended that a positive overflow drainage way be constructed between the low area of the street and Lake Edina. This will allow the street to drain and prevent the system from backing up into the backyard depression area. An option of adding additional inlet capacity to the trunk 54-inch system at the intersection of West Shore Drive and Hibiscus Avenue was considered; however, the 54-inch storm sewer system drains nearly 200 acres in addition to the 48.5 acres from subwatershed LE_53 and is already at full capacity. Adding additional inlet capacity at the intersection of West Shore Drive and Hibiscus Avenue would cause additional street flooding problems at upstream locations. This flood issue was evaluated as part of the 2013 street reconstruction project. Pipes were upsized as part of the 2013 Lake Edina Neighborhood Roadway Improvements (ENG 13-4). 7.3.1.3 6312, 6316, 6321, 6329 Tingdale Avenue (NC_11) A depression area exists along Tingdale Avenue, between West 63rd and West 64th Streets. Two catchbasins are located at the low portion of the street, collecting stormwater runoff. During the 100-year frequency storm event, the flood elevation at this location reaches 936.5 MSL. A field survey determined that this flood elevation would potentially impact egress windows at 6312 and 6316 Tingdale Avenue (935.24 MSL and 935.20 MSL, respectively). There have not been any studies or improvement projects completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-10 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 7.3.1.4 St. Johns/Ashcroft and West 64th Street (NC_40, NC_26) A low area exists directly north of North Lake Cornelia, encompassing portions of T.H. 62 and West 64th Street between Ashcroft Lane and St. Johns Avenue. The storm sewer system in this depression area includes two catchbasins on West 64th Street and several inlets along T.H. 62, including an inlet in the grassed median of T.H. 62. During extreme storm events such as the 100-year frequency event, this area is inundated with stormwater runoff, receiving flows from the subwatersheds directly tributary to the system, as well as flow not captured by the storm sewer system at the intersection of Ashcroft and West 64th Street (40 cfs) and excess T.H. 62 flows not collected upstream (160 cfs). Because of the topography and the slope of the highway at this location, during intense rainstorm events water from the highway will flow north toward the low area on West 64th Street. The 100-year frequency flood elevation for the highway and West 64th Street area is 868.1 MSL. At this flood elevation, the entire stretch of West 64th Street between Ashcroft Lane and St. Johns Avenue will be inundated, in addition to the highway and backyard area just north of West 64th Street, endangering structures at 6336 St. Johns Avenue and 6329 Ashcroft Lane. To alleviate this situation, it is recommended that an additional pipe be installed at the low point in the T.H. 62 median that would drain to North Lake Cornelia. A 24-inch pipe would decrease the 100-year frequency flood elevation of this depression area to 867.7 MSL and alleviate the flooding concerns for 6336 St. Johns Avenue and 6329 Ashcroft Lane. This area was evaluated as part of the STS-406 project (2013-2014). No improvements have been completed for this flood protection project. Will consider the improvement if HWY 62 is rebuilt. 7.3.1.5 Barrie Road and Heritage Drive (NC_86, NC_97, NC_99) A depression area exists at the intersection of Barrie Road and Heritage Drive and extends south of the intersection along Barrie Road to West 65th Street. Stormwater from this area is collected by storm sewer and flows northward, eventually connecting with the T.H. 62 system. During large storm events, this large depression area is inundated, causing street and parking lot flooding. The calculated flood elevation for the 100-year frequency storm event is 879.8 MSL. The low elevations of several properties in this area were surveyed to determine if this flood level would encroach upon and potentially cause damage to any structures. The field survey identified only one property at 6328 Barrie Road with a 878.6 MSL walkout patio elevation, with a low elevation below the 100-year frequency flood level. The analysis of this system determined that the flooding problem in this area results from lack of capacity of the T.H. 62 system. As large stormwater flows enter the T.H. 62 storm sewer system from the highway, flow into that system from Barrie Road and Heritage Drive is restricted. To alleviate this problem, it will be necessary to re- examine the capacity of the T.H. 62 storm sewer system. This area was evaluated as part of the STS-406 project (2013-2014). No improvements have been completed for this flood protection project. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-11 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 7.3.1.6 York Avenue and West 64th Street (NC_88) A stormwater detention basin is located southeast of the intersection of York Avenue and West 64th Street. This basin has two pumped outlets, one which discharges to the west and one that discharges to the east. The outlet to the west is controlled by two pumps, each with an approximate pumping rate of 500 gpm (1.1 cfs). For the XP- SWMM model, it was assumed that the first pump on the west side turns on as the water elevation reaches 863 MSL, with the second pump turning on at water elevation 864 MSL. It was assumed the pumps turn off at water elevation 862 MSL. The pumped discharge flows west through a forcemain and connects to the gravity system along Barrie Road. The outlet to the east is also controlled by two 500 gpm pumps. Similar to the west outlet, it was assumed that the first pump on the east side turns on as the water elevation reaches 863 MSL, with the second on at elevation 864 MSL and both pumps off when the water level recedes to 862 MSL. Discharge from this outlet flows south along Xerxes Avenue, eventually connecting into the West 66th Street system. The predicted 100-year flood elevation for this detention basin is 870.9 MSL. Based on the 2-foot topographic information, if flood waters reach this elevation the structure at 6415 York Avenue would be affected and potentially the structure at 6455 York Avenue. To prevent these structures from incurring flood damage, the pump capacity from the system should be increased. It is recommended that the capacity of both the east and west lift stations be upgraded to 1500 gpm (approximately 3 cfs) each. It is also recommended that the pumps turn on at water elevation 862.5 and off at 861.5 MSL. With implementation of these recommendations, the predicted 100-year frequency flood elevation is 870 MSL, providing a level of protection for these structures. This area was evaluated as part of the STS-406 project (2013-2014). No improvements have been completed for this flood protection project. 7.3.1.7 T.H. 62 at France Avenue (NC_132) The modeling results indicated that isolated flooding would occur along T.H. 62 during a 100-year frequency storm event. Specifically, flooding would occur on T.H. 62 near the France Avenue crossing. The 100-year frequency flood elevation of this area is 873.2 MSL. To correct this problem, it will be necessary to re-examine the capacity of the T.H. 62 storm sewer system. Adjacent areas were evaluated as part of the STS-406 project (2013-2014). Although flooding in this subwatershed was not specifically addressed, improvement alternatives proposed in STS-406 may also reduce the flood elevation in NC_132. No improvements have been completed for this flood protection project. 7.3.1.8 Parnell Avenue and Valley View Road (NC_135) A backyard depression area exists between the blocks of Ryan Avenue and Parnell Avenue, just south of Valley View Road. The backyard depression area collects stormwater from its direct subwatershed of approximately 3 acres. The area is currently not connected to the storm sewer system. The predicted 100-year frequency flood elevation for this area is 910.2 MSL. Based on the 2-foot topographic data, this flood elevation would potentially impact the structures at 4801 and 4809 Valley View Road and 6112 Parnell Avenue. There have not been any studies or improvement projects completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-12 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Nine Mile Creek-South 8.3.1.1 7001 & 7025 France Avenue (CL_51) A depression area exists at the properties of 7001 and 7025 France Avenue. The depression area is drained by an 18-inch storm sewer pipe that connects into the trunk system along France Avenue. During intense storm events, such as the 100-year frequency storm, high flows through the France Avenue trunk system restrict the drainage from the depression area and the area becomes inundated with stormwater. The 100-year frequency flood elevation for this depression area is 862.6 MSL. Flooding problems have been historically noted in this area. A flapgate was added to the collection pipe at this area to prevent the France Avenue system from backing up and causing further inundation. However, with the flapgate closed, there is no outlet from this area and the storage volume in the parking lot is not sufficient to prevent flooding of the structures. Prior to construction of the bank currently located on this property, the property owner was informed of the flooding potential. No recommendations to alleviate the flooding are being made at this time. There have not been any studies or improvement projects completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-13 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Nine Mile South Fork 9.3.1.1 6309 Post Lane (AH_31) A depression area exists in the backyard area of 6309 Post Lane. The depression area receives stormwater from a direct watershed of 1.7 acres. Stormwater collected in the depression area enters a 30-inch storm sewer system through a catchbasin located at the low point of the backyard. Upstream of the backyard depression area, the 30-inch system receives stormwater from the T.H. 62 and T.H. 169 interchange and discharge from the Arrowhead Pointe pond (AH_4). During intense rain storms, such as the 100-year frequency event, the capacity of the 30-inch system is limited from upstream drainage, preventing the backyard area from being drained. Under current conditions, the 100-year frequency flood elevation in the backyard depression area is 883.4 MSL. This flood elevation is above the low entry of the home at 6309 Post Lane, surveyed at 880.6 MSL. To alleviate the flooding of the backyard area, it is necessary to restrict the flow in the 30-inch system from upstream drainage areas during the time period of the backyard inundation. Currently, stormwater from the T.H. 62 and T.H. 169 interchange is collected in a series of ditches and enters the 30-inch storm sewer system through a flared end section on the north side of T.H. 62 (subwatershed AH_25) and a catchbasin/manhole inlet on the southeast side of the interchange (subwatershed AH_29). To retard the flow in the 30-inch system during the time period of the backyard inundation, it is recommended that a control structure be installed at the catchbasin/manhole inlet in the ditch southeast of the T.H. 62 and T.H. 169 interchange (node AH_29). The control structure should consist of a 6-inch orifice at elevation 882 MSL to allow low flows through during smaller storm events and to allow the ditches to completely drain. A 6-foot weir at elevation 887 MSL will restrict high flows through the system during the time period of the backyard inundation and take advantage of available temporary storage in the highway ditches. In addition, it is recommended that the control structure from the Arrowhead Pointe pond (AH_4) be modified to restrict flow from the pond during the time period of the backyard inundation. It is recommended that the control structure consist of a 4-inch diameter orifice at elevation 884 MSL and a 6-foot weir at elevation 887 MSL. With implementation of these recommendations, the resulting 100-year frequency flood elevation in the backyard depression area is 880.5 MSL, below the low entry elevation at 6309 Post Lane. There have not been any studies or improvement projects completed for this area. 9.3.1.2 Braemar Golf Course (NMSB_62) The predicted 100-year flood elevation of the NMSB_62 watershed is 840.9 MSL. Based on the 6-foot topographic information from the City, it appears that this flood level will impact the Executive Course clubhouse at the Braemar Golf Course. Anecdotal information suggests this structure has been affected by flood waters in the past. There have not been any studies or improvement projects completed for this area. Recent improvements have been constructed at Braemar Golf Course, including significant re-grading. The NMCWD or City models have not been revised to reflect the updated grading at Braemar. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-14 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 9.3.1.3 Paiute Pass & Sally Lane Intersection (NMSB_83, NMSB_84) The storm sewer system at the Paiute Pass and Sally Lane intersection collects stormwater from a total drainage area of approximately 27 acres. The system discharges into the Braemar Branch, west of Sally Lane, via two 24-inch pipes. During the 10-year and 100-year storm events, the Paiute Pass/Sally Lane intersection is inundated with stormwater and ponding occurs. Based on topographic information from the City, ponding will occur in this intersection to Elevation 863.6 MSL. As water levels rise higher than this, water will begin to encroach upon the homes west of Sally Lane (7000, 7004, 7008 Sally Lane) and eventually flow to the Braemar Ditch via overland flow. It is recommended that the topography of this area be examined in further detail and a controlled positive overflow path be constructed between the homes if necessary to ensure the homes are protected from flood waters. This area was evaluated as part of the STS-406 project (2013-2014). Barr worked with the City’s consultant in evaluating options for storm sewer modifications as part of the local street reconstruction project in the summer/fall of 2014 to address some of the recommendations from STS-406. New storm sewer was installed in 2015. Included as a current flood protection project in Section 9.3.1.2. 9.3.1.4 7009 & 7013 Sally Lane Backyard Depression Area (NMSB_70) A backyard depression area exists behind the homes along Sally Lane and Paiute Pass. A 12-inch piped outlet exists from this area, draining northward and connecting to the system along Paiute Pass. During the 100-year storm event, the predicted flood elevation reaches 864.5 MSL, assuming an overland flow channel from this area. Based on topographic information from the City, this flood elevation encroaches upon the homes at 7009 and 7013 Sally Lane. It is recommended that the topography of this area be further examined to determine the elevation at which the flooded area will drain west toward Sally Lane via overland flow. If necessary, a controlled positive overflow should be constructed between the homes to prevent flood water from damaging the structures. This area was evaluated as part of the STS-406 project (2013-2014). Barr worked with WSB in evaluating options for modifications to the storm sewer in this area (specifically NMSB_70) in the summer/fall of 2014. Pipes were upsized in 2015 Valley View Road Improvements. Southwest Ponds 10.3.1.1 7411 Coventry Way (SWP_14) A small stormwater pond is located in the backyard of 7411 Coventry Way. The small stormwater pond outlets to a larger pond located directly east, across Delaney Boulevard (SWP_5) through a 15-inch storm sewer system. During extreme storm events, such as the 100-year frequency event, the flood elevation of the larger pond east of Delaney Boulevard increases and flow reverses in the 15-inch system connecting the two ponds, equalizing the ponds. The 100-year frequency flood elevation for both ponds (SWP_14 and SWP_5) is 833.6 MSL. Based on the 2-foot topographic data, this flood elevation would affect the structure at 7411 Coventry Way. To prevent flooding at 7411 Coventry Way, it is recommended that a flapgate be installed at the outlet of the small pond to prevent backflow from the larger pond. With installation of a flapgate, the 100-year frequency flood elevation of the small pond is 830.6 MSL. This area was evaluated as part of the STS-406 project (2013-2014). No improvements have been completed for this flood protection project. Programmed for future CIP. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-15 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 10.3.1.2 7317 Cahill Road (SWP_46) A low depression area exists along Cahill Road just north of the Cahill and Dewey Hill Road intersection and extends eastward into the parking lot of 7317 Cahill Road. During intense rainfall events, such as the 100-year frequency storm, this low area becomes inundated. The 100-year frequency flood elevation in this area is 833.8 MSL. Based on the 2-foot topographic data, this flood elevation will impact the structure at 7317 Cahill Road. However, because the flood elevations of the two stormwater ponds in Lewis Park north of Dewey Hill Road (SWP_35 and SWP_34) and the stormwater pond on the south side of Dewey Hill Road (SWP_5) are nearly as high, options to reduce the flooding of the road and parking lot of 7317 Cahill Road are limited. It is recommended that options to lower the flood elevation of this area be further investigated as road improvement projects are planned in the area in the future. This area (FilmTech) was evaluated as part of the STS-406 project (2013-2014). No improvements have been completed for this flood protection project. 10.3.1.3 7709 Stonewood Court (NM494_4) A stormwater pond is located northeast of the Stonewood Court and Gleason Road intersection. The basin is drained by a 12-inch storm sewer pipe with a negative slope that acts as an inlet and an outlet, depending upon the water level in the pond. The water level of the pond is controlled by the pipe invert downstream of the outlet on the west side of Gleason Road at Elevation 828.1 MSL. If the water level in the pond is below 828.1 MSL, the storm sewer system that collects stormwater from Tanglewood Court and Gleason Road discharges to the pond. If the water elevation is higher than 828.1 MSL, discharge from the stormwater pond will combine with stormwater from the Tanglewood Court and Gleason Road system and will continue flowing southward towards the South Fork of Nine Mile Creek. During the 100-year frequency storm event, the flood elevation of this stormwater pond reaches 832.5 MSL. Based on a field survey, this flood elevation will impact the structure at 7723 Stonewood Court (low house elevation of 831.97 MSL). To protect this structure from the 100-year flood elevation, it is recommended that the capacity of the downstream storm sewer system along Stonewood Court be increased. Based on modeling results, increasing the size of pipes 1011p and 1012p from 12-inch diameter to 24-inch diameter will reduce the 100-year flood elevation of the stormwater pond to 831.81 MSL, slightly below the low house elevation. There have not been any studies or improvement projects completed for this area. Programmed for future CIP. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-16 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Northeast Minnehaha Creek 12.3.1.1 4000 West 42nd Street and 4100, 4104, and 4108 France Avenue (MS_40) A large portion of the Morningside watershed discharges to a pond located on the east side of Weber Park (Weber Park Pond). This pond was designed to provide protection for a 50-year storm. The City’s 2004 Comprehensive Water Resources Management Plan identified the potential for flooding of properties adjacent to the pond, which was confirmed during a significant rainfall event that occurred in 2005. In 2006, the City completed a Feasibility Analysis to assess the flooding problem and evaluate options to minimize the flooding potential. Results of the 2006 analysis indicate that the predicted high water elevations in the Weber Park Pond for a 50-year and 100-year frequency flood event, based on existing conditions, are 868.6 ft MSL and 869.0 ft MSL, respectively. A field survey completed at the time indicates that the low entry elevations of four homes adjacent to the pond are at or below the predicted 100-year high water elevation, including 4000 West 42nd Street, 4100 France Avenue, 4104 France Avenue, and 4108 France Avenue. Based on the feasibility study completed, it was determined that the options to alleviate the flooding potential for the homes adjacent to the Weber Park pond are limited due to constraints in the downstream storm sewer system. Adding additional storage volume to the Weber Park pond would reduce the 100-year flood elevation of the pond to approximately 868.5 ft MSL. However, this flood elevation is still at or above the low entry elevation of three of the homes adjacent to the pond. An additional downstream capacity of 80 cfs would be required to alleviate the flooding at all adjacent properties under existing pond conditions, which is an expensive option. Should the City of Minneapolis update their storm sewer system in this area in the future, Edina will consider working with the City of Minneapolis to incorporate upgrades sufficient to provide additional capacity for the Morningside area drainage. The most cost effective option to upgrade to a 100-year level of protection for the homes currently below the 100-year flood level (4100, 4104, and 4108 France Avenue) would be to floodproof the affected homes and installation of a pumping station to drain stormwater runoff from the backyard area of the affected properties during significant storm events. This area was evaluated in detail as part of the 2017 CWRMP Update. Included as a current flood protection project in Section 12.3.1.3. 12.3.1.2 4308 France Avenue (MS_17) The low area in the backyard of 4308 France Avenue is inundated to an elevation of 902.5 MSL during the 100-year frequency storm. The results of a field survey indicate that this water level will potentially impact the house located at 4308 France Avenue. To protect the structure at 4308 France Avenue, it is recommended that in this depression area a catch basin be located and connected to the storm sewer system at the intersection of Scott Terrace and West 42nd Street. This area was evaluated as part of the STS-406 project (2013-2014). No improvement projects have been completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-17 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 12.3.1.3 4300, 4214, and 4212 Branson Street (MS_3) A depression in the backyard of 4300, 4214, and 4212 Branson Street is inundated to an elevation of 900.6 MSL during the 100-year frequency storm event. At this elevation structures will be affected at 4300, 4214 and 4212 Branson Street. A 15-inch storm sewer originating at Branson Street flows north and connects to the pipe system on Morningside Street. It is recommended that a catch basin be placed in the backyard depression area and pipe 955 upgraded to 24-inch diameter. This will reduce the 100-year frequency storm elevation to 899.5 MSL and protect the structures at 4300, 4214, and 4212 Branson Street. This area was evaluated in detail as part of the 2017 CWRMP Update. Included as a current flood protection project in Section 12.3.1.6. 12.3.1.4 4140 and 4150 West 44th Street (MS_7) A depression in the backyard of 4140 and 4150 West 44th Street is inundated to 900.6 MSL during the 100-year frequency storm as a result of runoff from its tributary watershed area. In addition, the storm sewer system on West 44th Street surcharges during the 100-year frequency storm and as a result, water flows from West 44th Street and into the backyard depression area. The addition of a catch basin to the backyard of 4140 and 4150 West 44th Street with a connection to the pipe system on West 44th Street was evaluated, but this alternative would require that the entire pipe system along West 44th Street and Morningside Avenue be upgraded. It is recommended that the storage capacity of this backyard area be increased by 1.4 acre-feet to an elevation of 899.3 MSL to protect the structure at 4140 and 4150 West 44th Street. This additional storage capacity can be achieved by lowering the depth of the backyard depression area by approximately 2 feet. There have not been any studies or improvement projects completed for this area. Included as a current flood protection project in Section 12.3.1.6. 12.3.1.5 Arden Avenue (MHN_14) Storm sewer improvements made in 2000 on Bridge Street, Sunny Side Road, and Arden Avenue were designed to reduce the potential for flooding at the low area on Arden Avenue just south of Bridge Street. The high water elevation of the 100-year frequency storm was 884.6 MSL, indicating that during a 100-year storm event the storm sewer improvements would protect the houses on Arden Avenue with the exception of the low house at 4611 Arden Avenue. There have not been any studies or improvement projects completed for this area. 15.2.2.1 White Oaks Landlocked Area (MHN_1, MHN_49, MHN_12, MHN_65) The MCWD Plan identified a landlocked area located in the northeast portion of the city, generally south of Sunnyside Road and north of West 49th Street, east of Arden Avenue and west of France Avenue. To assess the flood potential in this landlocked area, the 100-year, 10-day snowmelt event was simulated in XP-SWMM, assuming impervious (frozen ground) conditions. Comparison of the modeling results with the City’s 2-foot topographic information indicates that there is potential for the 100-year high water levels to impact structures in the following subwatersheds: MHN_1, MHN_49, MHN_12, MHN_65. To assess the potential for flooding, the City will complete a field survey to determine the low entry elevations of the potentially impacted structures and a detailed feasibility study to identify remedial measures, if necessary. This area was evaluated as part of the STS-406 project (2013-2014). No improvements have been completed for this flood protection project. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-18 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Southeast Minnehaha Creek 13.3.1.1 6213 Ewing Avenue (LP_15) A depression area on the street adjacent to 6213 Ewing Avenue collects water from a 3.8-acre watershed. The 100-year frequency flood elevation of 884.3 MSL will potentially impact the structure at 6213 Ewing Avenue. It is recommended that the diameters of pipes 1696 and 1695 be increased to 18-inches to provide a 100-year level of protection. This issue was evaluated in 2015 for ENG 16-3. Upsizing existing pipes was deemed infeasible as part of this project. 13.3.1.2 3600 West Fuller Street (MHS_4) The 100-year frequency flood elevation for the backyard depression area directly behind 3600 West Fuller Street is 875.4 MSL. A field survey indicates this elevation is above the low entry (872.6 MSL) at 3600 West Fuller Street. It is recommended that a catch basin be placed in the backyard depression and connected to a new storm sewer system installed east along Fuller Street and south along Beard Avenue to Minnehaha Creek. An existing bituminous drainage channel between Beard Avenue and Minnehaha Creek at this location appears to be a potential access point to Minnehaha Creek for the new pipe. The addition of a pipe system and catch basins extending from Fuller Street to Beard Avenue and then to Minnehaha Creek would provide the additional benefit of handling the significant street flows that occur on Fuller Street and Beard Avenue. There have not been any studies or improvement projects completed for this area. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-19 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 13.3.1.3 5605, 5609, 5613, 5617, 5621, 5625, and 5629 South Beard Avenue (MHS_79) Water in the alley between Abbott and Beard Avenue and south of West 56th Street rises to an elevation of 880.1 MSL during the 100-year frequency storm and affects the garages in this alley. This is the result of water flowing from West 56th Street to the alley and the limited flow in the pipe leading from the alley to the storm sewer system located on Beard Avenue. Currently the storm sewer system on Beard Avenue does not provide a 10-year level of service and is significantly undersized for the 100-year storm. At the intersection of Beard and West 56th Street, street flow on Beard Avenue reaches a peak of 97 cfs during the 100-year storm while the pipe carries only a peak flow of only 4.7 cfs. The street flow then flows on Beard Avenue to Minnehaha Creek. The following pipe sizes are recommended to protect the structures in the alley during a 100-year storm: Pipe 1851p ................................. 12 to 24-inch Pipe 1852p ................................. 12 to 24-inch Pipe 1156 ................................... 12 to 24-inch Pipe 1159 ................................... 27 to 36-inch Pipe 1158 ................................... 27 to 36-inch Pipe 1152 ................................... 33 to 36-inch Pipe 1153 ................................... 15 to 36-inch An additional catch basin is also required at the low point in the alley. To collect runoff along West 56th Street before it enters the alley, an additional catch basin is recommended on the south side of West 56th Street, east of the alley entrance. These recommendations are not designed to reduce the large street flows that are present on Beard Avenue during the 100-year storm. Further pipe size increases of the entire system and the addition of catch basins would be required to significantly reduce the flow of water along Beard Avenue. There have not been any studies or improvement projects completed for this area. 13.3.1.4 5837, 5833, 5829, 5825 South Chowen Avenue (LP_24) A backyard depression area directly behind 5829 South Chowen Avenue is inundated to an elevation of 884.6 MSL during the 100-year frequency storm and affects the structures at 5837 5833, 5829, and 5825 South Chowen Avenue. It is recommended that a catch basin be placed in the backyard depression area and connected with a 12-inch RCP to the storm sewer node LP_27 located at the intersection of South Chowen Avenue and West 60th Street. This area was evaluated as part of the STS-406 project (2013-2014). There have not been any studies or improvement projects completed for this area. There is potential for this to be addressed in future neighborhood roadway construction. 13.3.1.5 Chowen Avenue and West 60th Street (LP_27) A 100-year frequency flood elevation of 883.9 MSL has been calculated at the intersection of Chowen Avenue and West 60th Street. Although the model shows that there is the potential for significant flooding in this intersection, a thorough survey of the storm sewers and structures in this area needs to be completed to verify their size, invert elevations, and low point of entry. This area was evaluated as part of the STS-406 project (Part 1) in 2013-2014. Issue was re-evaluated in 2015 for ENG 16-3. Upsizing existing pipes along Chowen and 61st was analyzed and deemed infeasible. It was determined this could be solved by additional pipes along 60th and France to Pamela Park as part of future street reconstruction or stand-alone storm project. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-20 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes 13.3.1.6 5912, 5916, 5920, 5924, 5928 Ashcroft Avenue and 5925 Concord Avenue (MHS_51) Water in the backyard depression area of subwatershed MHS_51 will rise to 882.9 MSL during the 100-year frequency storm event. This flood elevation will inundate several of the houses adjacent to the depression. Water frequently ponds in this backyard depression area and either a pumped or gravity outlet from this area with a 3 cfs capacity is required to provide a level of protection. There have not been any studies or improvement projects completed for this area. 13.3.1.7 5840 and 5836 Ashcroft Avenue (MHS_89) The houses at 5840 and 5836 Ashcroft Avenue are located in a shallow depression area that fills with water from a small 0.7-- directly adjacent watershed. The calculated 100-year frequency flood elevation of 884 MSL will inundate the structures at 5840 and 5836 Ashcroft Avenue. It is recommended that a catch basin be placed at this depression and connected to the adjacent storm sewer system on Concord Avenue (node MHS_58). This outflow capacity will reduce the flood elevation to 883 MSL and provide the required level of protection for these structures. There have not been any studies or improvement projects completed for this area. 13.3.1.8 5609 and 5605 Dalrymple Road (MHS_24) and 5610 and 5612 St. Andrews Avenue (MHS_66) The calculated 100-year frequency flood elevation for the depression on Dalrymple Road is 895.3 MSL. This flood elevation is above the lowest entry way for both 5609 (low entry at 893.4 MSL) and 5605 (low entry at 893.25) Dalrymple Road. A field survey of the area indicates that a surface outflow existed between Dalrymple Road and the backyard area of subwatershed MHS_66 but has been filled. It is recommended that either this outflow be reestablished or pipes 1784 and 1240 be upgraded to 24-inch diameter pipes. The backyard depression area of MHS_66 is inundated to 894.8 MSL during the 100-year frequency flood. This elevation is above the elevation (894.46 MSL) of a back yard entry to 5610 Andrews Avenue, the basement windowsill (891.44 MSL) at 5612 Andrews Avenue, and the basement windowsill (893.53 MSL) at 5608 Andrews Avenue. It is recommended that a surface outflow be established between the backyard depression area and St. Andrews Avenue or pipes 1784 and 1240 be upgraded to 24-inch diameter pipes. There have not been any studies or improvement projects completed for this area. 13.3.1.9 5701 Dale Avenue (ML_12) A depression on Dale Avenue, directly adjacent to 5701 Dale Avenue, is inundated to an elevation of 935.8 MSL during the 100-year frequency storm event. According to a field survey, the low entry way at 5701 Dale Avenue is at an elevation of 935.5 MSL, indicating that the storm sewer system on Dale Avenue does not provide a level of protection for the structure at 5701 Dale Avenue during the 100-year frequency storm event. It is recommended that the diameter of pipes 1 and 1826 be increased to 24 inches to protect the structure at 5701 Dale Avenue from flooding. There have not been any studies or improvement projects completed for this area. 13.3.1.10 5213 and 5217 Richwood Drive (ML_7) A wetland area behind 5213 and 5217 Richwood Drive receives runoff from a 3-acre watershed. This wetland receives water from backyard areas, rooftops, and a small section of Windsor Avenue. During the 100-year frequency storm event the water level in this wetland rises to 928.6 MSL. This water level is above the elevation of the low entry for 5213 and 5217 Richwood Drive. It is recommended that the storage capacity of this wetland area be surveyed and the flooding potential be further evaluated. This area was evaluated in preparation for the 2012 Richmond Hills Park Neighborhood Improvements. New storm sewer installed in 2012. Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina C-21 2011 CWRMP Plan Section Title 2011 CWRMP Text Status notes Northwest Minnehaha Creek 14.3.1.1 Interlachen Landlocked Area The MCWD Plan identified a landlocked area located west of T.H. 100 and north of Vernon Avenue. This area, which encompasses subwatersheds EI_11, EI_12, EI_24, EI_13, and EI_19, currently drains to a wetland complex (EI_19) just south of Meadowbrook Golf Course. Two-foot topographic information for the area indicates that the natural overflow elevation between the landlocked wetland complex and the Meadowbrook Golf Course is approximately 885 feet M.S.L. Based on the FEMA Flood Insurance Study for Hennepin County (FEMA, 2004), the 100-year flood level of Minnehaha Creek as it flows through the golf course is 892 feet M.S.L. The maximum flood elevation that the City will allow in the wetland area (EI_19) is 888 feet M.S.L. To prevent the backflow of water from the Meadowbrook Golf Course to the wetland complex (EI_19), it is recommended that an embankment be constructed/raised between the wetland and the golf course to an elevation of at least 892 feet M.S.L. Upon raising the embankment, a pumped outlet will be required to keep the flood elevation below 888 feet M.S.L. The City should establish a management plan to address necessary pumping scenarios. Previous analyses for the area indicate a 1 cfs pumped outlet would be sufficient. There have not been any studies or improvement projects completed for this flood protection project. Appendix D List of Pond Improvement Recommendations Barr Engineering Co. 2018 Comprehensive Water Resources Management Plan: City of Edina D-1 List of Pond Improvement Recommendations 2011 CWRMP Plan Section Project Name/Location Proposed Improvement Nine Mile Creek-North 5.3.2.1 Pond MD_15 (Sun Road) Provide additional 0.3 acre-feet of dead storage volume. 5.3.2.2 Pond NMN_27 (Northeast of TH 62 and TH 169) Provide additional 1.4 acre-feet of dead storage volume. 5.3.2.3 Pond NMN_24 (Between Waterford Ct and Habitat Ct) Increase pond depth. 5.3.2.4 Pond NMN_49 (West of 5521 Malibu Drive) Provide additional 0.2 acre-feet of dead storage volume. 5.3.2.5 Pond MD_3 (Bredesen Park, east of parking area) Excavate to remove accumulated sediment. Lake Cornelia/Lake Edina/Adam’s Hill 7.3.2.1 Pond LE_38 (West of Lake Edina) Provide additional 1.4 acre-feet of dead storage volume within MnDOT right-of-way Nine Mile Creek-South 8.3.2.1 Subwatershed NMS_1 (Southwest quadrant of the TH 100 and West 77th Street interchange) Construct water quality basin. 8.3.2.2 Pond NMS_76 (Fred Richards Golf Course) Provide additional 2.5 acre-feet of dead storage volume. 8.3.2.3 Pond NMS_104 (Fred Richards Golf Course) Provide additional 0.2 acre-feet of dead storage volume. 8.3.2.4 Ponds NMS_72, NMS_74 (Fred Richards Golf Course) Increase pond depths. 8.3.2.5 Pond SP_1 (Border Basin - West of Minnesota Drive and West 77th St) Provide additional 21.5 acre-feet of dead storage volume. Nine Mile South Fork 9.3.2.1 Ponds NMSB_3, NMSB_2 (Braemar Golf Course) Provide additional 1.2 acre-feet of dead storage volume. 9.3.2.2 Pond NMSB_12 (Braemar Golf Course) Regular maintenance. 9.3.2.3 Pond NMSB_86 (Braemar Golf Course) Provide additional 0.15 acre-feet of dead storage volume. 9.3.2.4 Pond NMSB_7 (Braemar Golf Course) Increase pond depth. 9.3.2.5 Pond NMSB_85 (Braemar Golf Course) Provide additional 1.2 acre-feet of dead storage volume. Appendix E Aquatic Vegetation Prioritization List Aquatic vegetation services requests - Prioritization ChartThe prioritization list is not comprehensive, and more water bodies may be added. Water bodies may be reclassified using updated information.This prioritization list is used to determine eligibility for aquatic vegetation services.Water Body Tiny Small Medium Large No dataData showing water body does not meet goalsDrains directly to a 303(d) Impaired Water303(d) Impaired Waters ListTotal PointsPublic access and use - raise one service level50% shoreline owner involvement - raise one service levelService Level12 3 4 0 2 3 4Lake Cornelia448Yes Yes (for 2016+)HighMud Lake404YesMediumLake Edina448 HighMirror Lake404LowArrowhead Lake426YesHighIndianhead Lake426YesHighHighlands Lake404YesMediumOtto Pond303LowMelody Lake325YesHighLake Pamela336YesHighHawkes Lake303LowHarvey Lake303LowSwimming Pool Pond336 MediumLong Brake Trail Pond303Yes (for 2015+)MediumLake Nancy336YesHighPoint of France Pond303LowCreek Valley303LowUnnamed (near Parkwood & Knoll)303 LowUnnamed (Schaefer & Harold Woods)303 LowCote Pond202Yes (for 2016+)LowUnnamed (near Nine Mile Village Townhomes)202 NoneIncreased Service LevelSizeWater Quality Last Updated 12/13/2017 Page 1 of 2 Aquatic vegetation services requests - Prioritization ChartThe prioritization list is not comprehensive, and more water bodies may be added. Water bodies may be reclassified using updated information.This prioritization list is used to determine eligibility for aquatic vegetation services.Water Body Tiny Small Medium Large No dataData showing water body does not meet goalsDrains directly to a 303(d) Impaired Water303(d) Impaired Waters ListTotal PointsPublic access and use - raise one service level50% shoreline owner involvement - raise one service levelService LevelIncreased Service LevelSizeWater QualityUnnamed (south of Cote & Long Brake Tr)202 NoneBirchcrest Pond202Yes (for 2017+)LowSouth Pond202 NoneHyde Park Pond/Shannon Pond202Yes (for 2016+)LowWest Garrison Pond202 NoneUnnamed (south of Mirror Lake)202 NoneUnnamed (Blake Rd & Knoll Drive)202 NoneAnnaway Pond202 NonePrescott Pond101Yes (for 2017+)LowEdina incorporated Lake AssociationsArrowhead Lake Association (ALA)Cote PondLake Cornelia groupEdina lake groupsLong Brake Trail PondHyde Park/Shannon Pond groupPrescott Cirlce Pond groupBirchcrest Pond groupThe Indianhead Lake Association (TILA)Friends of Melody Lake (FoML)Lake Nancy Lake Association (LNLA) Last Updated 12/13/2017 Page 2 of 2 Appendix F Modified Minnesota Routine Assessment Method for Evaluating Wetland Functions (MnRAM) Version 2.0 Appendix G GIS Wetlands Inventory Database Data is located in a stand-alone file