1. TRAINING AGENDA Planner Module – September 20, 2005 Afternoon Session: I. Planners Training Exercise Review Marine Headquarters Case Study II. Complete 1391 for Integration of LID Approach into New Construction of Stormwater System Projects:

2. –LID Project Objectives –Master Planning Process Integration into Site Analysis, Benefit Analysis, Site Design Selection, Plan Development Green Roof –Discuss Traditional Site Plan vs. LID Approach

3. LID Project Objectives

4. LID approaches and techniques for the design of the MARFORLANT headquarters facility –Feasibility –Potential effectiveness

5. LID Project Objectives Utilizing LID techniques and practices to meet: –Regulatory requirements –Federal government program goals Water conservation Energy conservation Environmental stewardship –Natural resource program management objectives

6. MARFORLANT: Master Planning Process Meet Virginia Department of Conservation and Recreation (VDCR) stormwater management regulations. rainfall used for non-potable uses –irrigation or toilet flushing Ancillary benefits energy conservation –vegetated roof –strategic siting of vegetation.

7. MARFORLANT: Master Planning Process “GOVERNMENT BY EXAMPLE” Eliminate pond option by replacing the hydrologic and hydraulic functions with LID practices such as bioretention. –eliminating pond maintenance –pond vector issues.

8. Master Planning Process: Case Study MARFORLANT Integration into: –Site Analysis –Benefit Analysis –Site Design Selection –Plan Development

9. Master Planning Process: Site description 7.1 acres in size. Site slopes gently from the north and south Low point in the center of the property. mix of woods and grass The soils on site are compacted.

10. Master Planning Process: Proposal 55,000 sq. ft. building northern portion of site 280 parking spaces Future building planned western side of proposed facility. Conventional stormwater on western edge Woods should remain undisturbed

11. Master Planning Process: Hydrologic Analysis The Commonwealth of Virginia requires peak runoff post-development condition to equal or be below the discharge from the pre-development condition for: –2-year 24-hour storm (with a six-inch depth ) LID practices is three (3) percent, or 0.2 acres –10-year 24-hour storm event for urban areas LID practices is eight (8) percent, or 0.6 acres Pre-and Post-development conditions are compared to determine a storage volume

12. Master Planning Process: Non-potable water Secondary non-potable usage –toilet flushing, cooling, irrigation Daily water demand 4,500 gpd for 300 office workers (15 gal per person per day) Cistern size of 14 diameter and height of 37 ft to capture and reuse water.

13. Master Planning Process: Non-potable water

14. LID Site Design Requirement of 8% of the site in LID features (10 yr 24 hr storm) –Runoff will sheet flow to a centralized bioretention facility with several perimeter bioretention facilities –Permeable surfaces on walkways –Green roof

15. Master Planning Process Green Roof

16. Conditions that have spurred green roof development –Prevalence of combined sewer systems –Antiquated and over-taxed sewer and waste treatment facilities –Widespread pollution of rivers and estuaries –Frequent nuisance flooding –Limited space for instituting large management facilities

17. Green Roof (continued) Driving factors for Green roof at MARFORLANT facility –Mitigate water runoff impacts –Compensate for the loss of green space –Limited treatment options for site are limited due to location of low point and high water table –Increases service life of roofing system –Reducing energy cost

18. Layers of Green Roof Waterproofing membrane Root barrier (if the waterproofing is not certified as root resistant) Drainage layer Separation layer Growth media layer Plants

19. Green Roof: Pollution Removal It is estimated 30% of all nitrogen and phosphorus in local streams is from roof runoff Green roof have demonstrated the removal of: –68% of total phosphorus –80% of total nitrogen

20. Green Roof Benefits: Energy Estimated 10% reduction in air- conditioning related energy costs Roofing system is expected to last 2-3 times longer than normal

21. Traditional Site Plan vs. LID Approach

22. Conventional large capital investments in complex and costly engineering strategies pipes water to low spots as quickly as possible LID Design Integrates, green space, native landscape, natural hydrology functions to generate less runoff. Uses micro-scale techniques to manage precipitation close to where it hits the ground

23. Traditional Site Plan vs. LID Approach

24. Conventional vs. LID:

25. Conventional vs. LID

26. Conventional vs. LID Total costs Cost per length of pipe per ft C = 0.54D 1.3024 for D = $14.40 (12in) D = $30.10 (24 in) C ($/ft) = 14.45 (12 in) – 37.77 (24 in) 1999 dollars Cost of grass swale per ft C/L = K K = 5-14 C ($/ft) = 5 - 14 No land cost where considered, but could be significant

27. Cost Savings of LID Techniques Reduced downstream erosion and flood control. –preventing costly clean up and stream bank restorations. Infrastructure and development costs. –LID techniques reduces infrastructure requirements decreases the amount of pipes, roadways, detention facilities

28. Cost Savings of LID Techniques Improved groundwater recharge, drinking water, and decreased treatment costs. –Atlanta’s tree cover has saved over $883 million by reducing the need for stormwater facilities. –forest cover in the source area can reduce treatment cost 50 to 55% –Every 10% increase in forest cover treatment and chemical costs decreased approximately 20%

29. Funding Aspects

30. Funding Joint Effort –Department of Energy National Renewable Energy Research Laboratory (NREL) –Federal Management Program (FEMP) –Atlantic Division of the Naval Facilities Engineering Command (LANTDIV)

31. II.Complete 1391 for Integration of LID Approach into New Construction of Stormwater System Projects: 2:30 - 4:00pm

34. LID HYDROLOGIC ANALYSIS PROCEDURES

35. LID Techniques and Objectives Low-Impact Development Technique

36. Maintain Time of Concentration (Tc) X X X X X X X Low-Impact Development Technique

38. Match Practice with Soils/Site Conditions

39. Centralized Control Pond 1: Initial Architect’s Concept

40. 2: Revised Concept Reduced lawn, pulled in fields, redesigned parking area.

41. Decentralized Controls Roofs Parking Lots Open Drainage Rain Barrels Open Space Turf Educational components Multifunctional Use of Landscape and Infrastructure 3: Low Impact Design Outdoor Classroom Student Gardens Outdoor Classroom

42. RESULT: 5 Acres of Trees Saved

43. Planning Exercise Objectives Determine Goals Develop Concept Report

47. PG Chart

48. TR-55 VS/VR

49. 1391 Process PROJECT SUMMARY PROJECT NAME FACILITY PROJECT DESCRIPTION PROJECT OBJECTIVES

50. 1391 Process PROJECT BENEFITS ENVIRONMENTAL WATER CONSERVATION ENERGY MANAGEMENT MAINTENANCE AESTHETICS EDUCATION

51. 1391 Process LEED ISSUES (US GREEN BUILDING COUNCIL) GREENING THE GOVERNMENT EXECUTIVE ORDERS

52. 1391 Process DOE EPA Regulatory Chesapeake Bay 2000 Agreement Federal Agencies Chesapeake Ecosystem Unified Plan Chesapeake Bay Executive Council Directive 01-1 on Stormwater

53. Results

54. 1391 Process PROJECT SUMMARY PROJECT NAME MARFORLANT Facility FACILITY Naval Support Activity Norfolk PROJECT DESCRIPTION Determine feasibility and effectiveness of LID site design and green roof study. PROJECT OBJECTIVES 1)To improve water quality of site 2)To reduce runoff volume and peak flow rates for compliance 3)Meet FEMP objectives for water conservation and LID 4)Meet Greening Government, LEED, and other program objectives

55. 1391 Process PROJECT BENEFITS ENVIRONMENTAL Reduces pollutant loads by volume reduction and filtering. Bioretention and green roof systems provide superior filtering of oil and grease, TPH, thermal pollutant reduction, atmospheric nitrogen deposition WATER CONSERVATION Reduces potable water consumption by minimizing irrigation requirements. Opportunities for cisterns for other non-potable uses. ENERGY MANAGEMENT Shading of parking areas. Vegetation orientation reduces energy consumption. Green roof provides energy benefits. MAINTENANCE Minimizes maintenance requirements through the utilization of water-efficient, native, adaptable, climate- tolerant plant material. AESTHETICS Integration of natural landscape design with native plants and additional vegetation in bioretention cells. Green roof may be viewed from building. EDUCATION Promotes DoD awareness of environmental and water conservation activities

56. 1391 Process LEED ISSUES (US GREEN BUILDING COUNCIL) Potential for LEED credits for using natural treatment systems that treat the site’s stormwater, increase on-site infiltration, and reduce potable water requirements GREENING THE GOVERNMENT EXECUTIVE ORDERS Consistent with: EO13101 – Greening the Government through Waste Prevention, Recycling, and Federal Acquisition Reuse of stormwater EO13123 – Greening the Government through Efficient Energy Management Reduction of potable water requirements; improvement of water quality; minimization of maintenance requirements EO13134 – Developing and Promoting Biobased Products and Bioenergy Use of recycled materials (mulch, composted leaves and organic materials) to amend and fertilize soil EO13148 – Greening the Government through Leadership in Environmental Management Promotion of sustainability through the use of native plants

57. 1391 Process DOE Consistent with DOE’s FEMP Sustainability Initiative and Greening Program EPA Regulatory Potential for NPDES Credits Chesapeake Bay 2000 Agreement Bioretention will reduce nutrient and sediment loads Capture of atmospheric deposition by green roof and bioretention Government by Example Federal Agencies Chesapeake Ecosystem Unified Plan Pollution Prevention State-of-the-Art Techniques Low Impact Development Chesapeake Bay Executive Council Directive 01-1 on Stormwater Develop Innovative Technologies Installation of Innovative BMP Projects Education on Innovative BMPs

58. LID Site Design Requirement of 8% of the site in LID features (10 yr 24 hr storm) –Runoff will sheet flow to a centralized bioretention facility with several perimeter bioretention facilities –Permeable surfaces on walkways –Green roof