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Robert Pitt Department of Civil, Construction, and Environmental Engineering University of Alabama

Effective Urban Stormwater Control Practices. Robert Pitt Department of Civil, Construction, and Environmental Engineering University of Alabama Tuscaloosa, AL, USA 35487.

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Robert Pitt Department of Civil, Construction, and Environmental Engineering University of Alabama

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  1. Effective Urban Stormwater Control Practices Robert Pitt Department of Civil, Construction, and Environmental Engineering University of Alabama Tuscaloosa, AL, USA 35487

  2. Comparison of Stormwater Control Practices in Residential Land Uses, EPA Rain Zone 2 (National Stormwater Quality Database, NSQD)

  3. Relative Effectiveness of Controls

  4. Probability distribution of rains (by count) and runoff (by depth). Central Alabama Rain Condition: <0.5”: 65% of rains (10% of runoff) 0.5 to 3”: 30% of rains (75% of runoff) We therefore need to focus on these rains! 3 to 8”: 4% of rains (13% of runoff) >8”: <0.1% of rains (2% of runoff) 3” 8” 0.5”

  5. Calculated Benefits of Various Roof Runoff Controls (compared to typical directly connected residential pitched roofs) There are therefore a number of potential controls for roof runoff, from the conventional to the unusual, that can result in very large runoff reductions.

  6. Roof drain disconnections Not this!

  7. Green(ish) Roof for Evapotranspiration of Rain Falling on Building (Portland, OR)

  8. Monitoring results showing green roof runoff benefits compared to conventional roofing (data from Shirley Clark, Penn State – Harrisburg) Greater than 65% volume reductions due to ET

  9. Rain Garden Designed for Complete Infiltration of Roof Runoff

  10. Recent Bioretention Retrofit Projects in Commercial and Residential Areas in Madison, WI

  11. Runoff volume benefits of many rain gardens/bioret-ention devices capturing runoff in neighborhood 97% Runoff Volume Reduction Land and Water, Sept/Oct. 2004

  12. Stormwater filters and bioretention areas in ultra urban setting (Melbourne, Australia)

  13. Street-side tree filters in downtown area (Melbourne, Australia)

  14. Rain water tank to capture roof runoff for reuse (Heathcote, Australia) Cistern tank, Kamiros, Rhodes (ancient Greece, 7th century BC)

  15. Infiltration Pollutant Control in Grass Filters and Swales Runoff from Pervious/ impervious area Trapping sediments and associated pollutants Reducing runoff velocity Sediment particles Reduced volume and treated runoff

  16. Neenah Foundry Employee Parking Lot Grass Filter/Biofilter, Neenah, WI

  17. 116 ft TSS: 10 mg/L 75 ft TSS: 20 mg/L 25 ft TSS: 30 mg/L 6 ft TSS: 35 mg/L 3 ft 2 ft TSS: 63 mg/L TSS: 84 mg/L Date: 10/11/2004 Head (0ft) Example grass filter monitoring results, Tuscaloosa, AL TSS: 102 mg/L

  18. Multi-Chambered Treatment Tank (MCTT) for Critical Source Areas (underground installation with very high removals of heavy metals and toxic organics, along with conventional pollutants)

  19. Milwaukee, WI, Ruby Garage Public Works Maintenance Yard and Minocqua, WI, MCTT Sites

  20. Monitored Test Results for Suspended Solids and Zinc

  21. Full-Scale MCTT Test Results

  22. EPA-funded SBIR2 Field Monitoring Equipment for UpFlow Filter, Tuscaloosa, AL

  23. Upflow filter insert for catchbasins Able to remove particulates and targeted pollutants at small critical source areas. Also traps coarse material and floatables in sump and away from flow path. HydroInternational, Ltd. Full-scale commercial unit currently being tested in Tuscaloosa, AL

  24. Installation of full-sized UpFlow Filter at Tuscaloosa for long-term monitoring

  25. Filtration Performance

  26. Wet Detention Ponds

  27. Retrofitted to result in 90% SS control, the long-term monitored results were 87%.

  28. Downtown Tuscaloosa Redevelopment

  29. Conducted a preliminary evaluation of the downtown Tuscaloosa area that contains the redevelopment sites. Soils are mostly hydrologic group B which is classified as silt, loam, and silt-loam, having typical infiltration rates of about 0.5 in/hr, although most of the soils are highly disturbed and will need to be restored.

  30. Separated area into six subareas of several blocks each and conducted detailed field surveys and modeling for each land use. This is one subarea.

  31. Directly connected roofs Landscaping Driveways Streets Directly connected paved parking areas Major sources of suspended solids in the drainage area for different sized rains. Fairly consistent pattern because of the large amounts of impervious surfaces in the drainage basin and the highly efficient drainage system.

  32. Calculated annualized total life cycle costs and TSS reductions for different stormwater controls (110 acre downtown Tuscaloosa, AL, example)

  33. North Huntsville Industrial Park Conservation Design

  34. The North Huntsville Industrial Park is a new development of 250 acres with 50 lots, each about 2 to 4 acres. Each site will use minimal galvanized metal and will have critical source area controls Sink holes are buffered and bermed Each site has bioswale/biofilter and level spreader Large regional swale with limestone checkdams Large regional swale with limestone checkdams Dry pond Wet pond Wet pond Toyota Engine Factory

  35. Sediment Reductions Volume Reductions

  36. Grass Swales • Wet Detention Pond • Infiltration Basin/Wetland • Reduced Street Width WI DNR photos

  37. Reductions in Runoff Volume for Cedar Hills (calculated using WinSLAMM and verified by site monitoring)

  38. Combinations of Controls Needed to Meet Many Stormwater Management Objectives • Smallest storms should be captured on-site for reuse, or infiltrated • Design controls to treat runoff that cannot be infiltrated on site • Provide controls to reduce energy of large events that would otherwise affect habitat • Provide conventional flooding and drainage controls Pitt, et al. (2000)

  39. Appropriate Combinations of Controls • No single control is adequate for all problems • Only infiltration reduces water flows, along with soluble and particulate pollutants. Only applicable in conditions having minimal groundwater contamination potential. • Wet detention ponds reduce particulate pollutants and may help control dry weather flows. They do not consistently reduce concentrations of soluble pollutants, nor do they generally solve regional drainage and flooding problems. • A combination of bioretention and sedimentation practices is usually needed, at both critical source areas and at critical outfalls.

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