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20071522 Ver 1_More Info Received_20071010
~.xp o'1-1522 1~ JOHN R. McADAMS COMPANY, INC. LETTER OF TRANSMITTAL To: Ms. Lia Myott Date: October 09, 2007 NCDWQ 401 Wetlands Unit 2321 Crabtree Boulevard Raleigh, North Carolina 27604 Re: Porto Fino -Clayton, NC DWQ Response to Comments I am sending you the following item(sl~ COPIES DATE NO. DESCRIPTION 1 Co of Comment Ltr dated 10/04/07 EXP # 07-1522 3 Bioretention worksheets 3 Revised Construction Notes 3 Revised O eration and Maintenance A reement These are transmitted as checked below: ® As requested ® For approval Remarks: Copy to: EXP # 07-1522 Kevin Yates Project Manager FOR INTERNAL USE ONLY ^ Copy Letter of Transmittal Only to File ® Copy Entire Document to File CIVIL ENGINEERING • LAND PLANNING • SURVEYING PO Box 14005 • Research Triangle Park, NC 27709 • (919) 361-5000 • fax (919) 361-2269 www.johnrmcadams.com D ~ (~~~ l~ ~ D ~~j1~1001 ~~N!? _ ~~C~4A,'MD CT~r{R,~y~ ~BWINCH ** HAND DELIVER ** Job No.: WLT-07010 ® For your use Signed: ' ur' ~o~~ wA~~9pG ~ r ~ ~ O `C October 4, 2007 EXPRESS REVIEW NOTIFICATION LETTER Mr. Rob Bailey 442 %-East Main St. Clayton, NC 27520 Project Name: Porto Fino Residential Subdivision D"ear Mr. Bailey: Michael F. Easley, Governor William G. Ross 3r., Secretary North Carolina Department of Environment and Natural Resources Coleen H. Sullins, Director Division of water Quality On October 3, 2007, the Express Review Program of the Division of Water Quality (DWQ} received additional information from Kevin Yates of.Iohn R. McAdams Company, Inc. The DWQ has determined that this information is incomplete. Please provide the fo[[owing information so that we may continue to review your project and prevent denial of your application as required by 15A NCAC 2H .0506: Diffuse Flow Provisions as required by the Neuse Riparian Buffer Rule: a. Please provide the supplements (worksheets} for the proposed Bioretention cells. These supplements can be found at: http://h2o.em•.state.nc.us(sufdocuments/SW401-Bioretention-Rev.l.xls 2. Bioretention cells: a. Please specify in construction notes that centipede grass sod must be used. b. Specified P-Index for soil media should be between IO and 30 (see supplement). 3. Operation and Maintenance Agreement: a. Fertilization is not allowed in a nutrient sensitive watershed except minimal use during the initial establishment of vegetation (if needed). b. Remove references to "vegetation and mulch" "mulch layer" and "trees" in Section IV and specify conditions for centipede sod. Please respond within five (5} days of the date of this letter by sending three (3) copies of this information. The Express Review Program is a process. that requires all parties to participate in a timely manner. This letter only addresses the application review and does not authorize any impacts to wetlands, waters or protected buffers. Please contact Lia Myott at (919} 733-9502 if you have any questions. Sincerely, Cyndi Karoly, Supervisor 401/Express Review Oversite Unit CBIC/lefla/jg 4010versight/Express Review Permittinng Unit 1650 tvlaitService Center, Ralogh, North GaroHna 21699-1650 2321 Crabtree Boulevard, Suite 250, Raleigh, North Carona 21604 Phone: 919-733-1186 /FAX 919-733-689311nternel: http:fAt2o_errrstatc,nc.us/ncwctlaads N°hcarolina dVaturn~ly An Equal OpporirxiityfABumative Action Employer - 50% Recycled110% Post Consumer Paper ~~ r ~r cc: DWQ Raleigh Regional Office DLR Raleigh Regional Office USAGE Raleigh Field Office Central Files File copy Kevin Yates, John R. McAdams Company, 2905 Meridian Pkwy., Durham, NC 27713 ~~ ~~~ NCDENR ~ x.,~ O 1 - ~, ~j 2 2 Permit Number: (to be provided by DWQ) o~~F W A 1'F9OG O 'c STORMWATER MANAGEMENT PERMIT APPLICATION FORM 401 CERTIFICATION APPLICATION FORM BIORETENTION CELL SUPPLEMENT This form must be filled out on line, printed and submitted with all of the required information. Make sure to also fill out and submit the Required Items Checklist (Part III) and the 1&M Agreement (Part IV) I. PROJECT INFORMATION Project name Flowers Tract Contact name Sabrina E. Davis Phone number 919-550-4740 Date September 24, 2007 Drainage area number 1 II. DESIGN INFORMATI Site Characteristics Drainage area 174,498 ft Impervious area 22,000 ftz Percent impervious 0.13 Design rainfall depth 1.0 inch Peak Flow Calculations Does this project require pre/post control of the 1-yr 24-hr peak n (Y or N) flow? 1-yr, 24-hr runoff depth in 1-yr, 24-hr intensity inlhr Pre-development 1-yr, 24-hr runoff ft3/sec Post-development 1-yr, 24-hr runoff ft3/sec Pre/Post 1-yr, 24-hr peak control ft3/~ Storage Volume: Non-SR Waters Design volume 1,163.0 ft3 Ponding depth of water 12 inches OK Ponding depth of water 1.00 ft Surface area of the top of the bioretention cell 1,166.0 ftz OK Length: 53 ft OK Width: 22 ft OK -or- Radius ft Storage Volume: SR Waters 1-yr, 24-hr depth in Pre-development 1-yr, 24-hr runoff ft3 Post-development 1-yr, 24-hr runoff ft3 Minimum volume required ft3 Volume provided ft3 Soils Report Summary Drawdown time, ponded volume 12 hr OK Drawdown time, to 24 inches below surface 36 hr OK Drawdown time, total: 48 hr In-situ soil.• Soil type Parcolet Loam Soil permeability 0.60 in/hr Planting media soil.• Soil type Sandy Loam Soil permeability 1.00 in/hr OK Soil composition Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 1 of 3 Permit Numt~er: (to be provided by DWQ) Sand (by weight) Fines (by weight) Organic (by weight) Phosphorus Index (P-Index) Basin Elevations Temporary pool elevation Planting elevation (top of the mulch) Bottom of the cell Planting depth Depth of mulch SHWT elevation Are underdrains being installed? 85% OK 12% OK 3% OK Total: 100% 30 (unitless) OK 231 fmsl OK 229.5 fmsl 227 fmsl 2.5 ft 2 inches OK 216 fmsl OK How many clean out pipes are being installed? What factor of safety is used for sizing the underdrains? (See BMP Manual Section 12.3.6) Additional distance between the bottom of the planting media and the bottom of the cell to account for underdrains Bottom of the cell required Distance from bottom to SHWT Type of bioretention cell (answer "Y" to only one of the two following questions): Is this a grassed cell? Is this a cell with trees/shrubs? Additional Information Does volume in excess of the design volume bypass the bioretention cell? Does volume in excess of the design volume flow evenly distributed through a vegetated filter? What is the length of the vegetated filter? Does the design use a level spreader to evenly distribute flow? Is the BMP located at least 30ft from surface waters (50ft if SA waters)? Is the BMP located at least 100ft from water supply wells? Are the vegetated side slopes equal to or less than 3:1? Is the BMP located in a recorded drainage easement with a recorded access easement to a public Right of Way (ROW)? Inlet velocity (from treatment system) Is the area surrounding the cell likely to undergo development in the future? y (Y or N) 2 OK 10 1ft 226 fmst 10 ft OK y (Y or N) OK n (Y or N) y (Y or N) n (Y or N) Excess volume must pass through filter. ft n (Y or N) Show how flow is evenly distributed. y (Y or N) y (Y or N) y (Y or N) y (Y or N) ft/sec n (Y or N) Are the slopes draining to the bioretention cell greater than 20%? n (Y or N) Is the drainage area permanently stabilized? y (Y or N) Pretreatment Used (Indicate Type Used with an "X" in the shaded cell) Gravel and grass (flinches gravel followed by 3-5 ft of grass) Grassed swale Forebay Plants Number of tree species Number of shrub species Number of herbaceous groundcover species OK OK OK OK Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 2 of 3 Permit Number: (to be provided by DWQ) Attach supporting calculations/documentation. The soils report must be based upon an actual field investigation, soil borings, and infiltration tests. The results of the soils report must be verified in the field by DWQ, by completing & submitting the soils investigation request form. County soil maps are not an acceptable source of soils information. All elevations shall be in feet mean sea level (fmsl). Form SW401-Bioretention-Rev.1 Parts 1 and II. Design Summary, Page 3 of 3 Permit Number: (to be provided by DWQ) O~O~ W A TF9OG ~`1 • ~ ~ ~ _ _ > NCDENR p STORMWATER MANAGEMENT PERMIT APPLICATION FORM 401 CERTIFICATION APPLICATION FORM BIORETENTION CELL SUPPLEMENT This form must be filled out on line, printed and submitted w-th all of the required information. Make sure to also fill out and submit the Required Items Checklist (Pa-t III) and the 1&M Agreement (Part IV) I. PROJECT INFORMATION Project name Flowers Tract Contact name Sabrina E. Davis Phone number 919-550-4740 Date September 24, 2007 Drainage area number 2 II. DESIGN INFORMATION Site Characteristics Drainage area 24,820 ft Impervious area 3,300 ft Percent impervious 0.13 Design rainfall depth 1.0 inch Peak Flow Calculations Does this project require prelpost control of the 1-yr 24-hr peak n (Y or N) flow? 1-yr, 24-hr runoff depth in 1-yr, 24-hr intensity in/hr Pre-development 1-yr, 24-hr runoff ft3/sec Post-development 1-yr, 24-hr runoff ft3/sec Pre/Post 1-yr, 24-hr peak control ft3/sec Storage Volume: Non-SR Waters Design volume 268.0 ft3 Ponding depth of water 12 inches OK Ponding depth of water 1.00 ft Surface area of the top of the bioretention cell 300.0 ft2 OK Length: 25 ft OK Width: 12 ft OK -or- Radius ft Storage Volume: SR Waters 1-yr, 24-hr depth in Pre-development 1-yr, 24-hr runoff ft3 Post-development 1-yr, 24-hr runoff ft3 Minimum volume required ft3 Volume provided ft3 Soils Report Summary Drawdown time, ponded volume 12 hr OK Drawdown time, to 24 inches below surface 36 hr OK Drawdown time, total: 48 hr IR-SItU S011: Soil type Parcolet Loam Soil permeability 0.60 inlhr Planting media soil: Soil type Sandy Loam Soil permeability 1.00 in/hr OK Soil composition Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 1 of 3 Permit Number. (to be provided by DWQ) Sand (by weight) Fines (by weight) Organic (by weight) Phosphorus Index (P-Index) Basin Elevations Temporary pool elevation Planting elevation (top of the mulch) Bottom of the cell Planting depth Depth of mulch SHWT elevation Are underdrains being installed? 85% OK 12% OK 3% OK Total: 100% 30 (unitfess) OK 232.5 fmsl OK 231.5 fmsl 229 fmsl 2.5 ft 2 inches OK 216 fmsl OK How many clean out pipes are being installed? What factor of safety is used for sizing the underdrains? (See BMP Manual Section 12.3.6) Additional distance between the bottom of the planting media and the bottom of the cell to account for underdrains Bottom of the cell required Distance from bottom to SHWT Type of bioretention cell (answer "Y" to only one of the two following questions): Is this a grassed cell? Is this a cell with treeslshrubs? Additional Information Does volume in excess of the design volume bypass the bioretention cell? Does volume in excess of the design volume flow evenly distributed through a vegetated filter? What is the length of the vegetated filter? Does the design use a level spreader to evenly distribute flow? Is the BMP located at least 30ft from surface waters (50ft if SA waters)? Is the BMP located at least 100ft from water supply wells? Are the vegetated side slopes equal to or less than 3:1? Is the BMP located in a recorded drainage easement with a recorded access easement to a public Right of Way (ROW)? Inlet velocity (from treatment system) Is the area surrounding the cell likely to undergo development in the future? Are the slopes draining to the bioretention cell greater than 20%? Is the drainage area permanently stabilized? Pretreatment Used (Indicate Type Used with an "X" in the shaded cell) Gravel and grass (flinches gravel followed by 3-5 ft of grass) Grassed Swale Forebay Plants Number of tree species Number of shrub species Number of herbaceous groundcover species y (Y or N) 2 OK 10 1ft 228 fmsl 12 ft OK y (Y or N) OK n (Y or N) y (Y or N) n (Y or N) Excess volume must pass through filter. ft n (Y or N) Show how flow is evenly distributed. y (Y or N) y (Y or N) y (Y or N) OK y (Y or N) OK ft/sec n (Y or N) n (Y or N) OK y (Y or N) OK Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 2 of 3 Permit Number: (to be provided by DWQ) Attach supporting calculations/documentation. The soils report must be based upon an actual field investigation, soil borings, and infiltration tests. The results of the soils report must be verified in the field by DWQ, by completing & submitting the soils investigation request form. County soil maps are not an acceptable source of soils information. All elevations shall be in feet mean sea level (fmsl). Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 3 of 3 Permit Number: (to be provided by DWQ) O~o~ W A 7E9Qv ~ r ~~ ~ ti NCDENR STORMWATER MANAGEMENT PERMIT APPLICATION FORM 401 CERTIFICATION APPLICATION FORM BIORETENTION CELL SUPPLEMENT This form must be filled out on line, printed and submitted with all of the required information. Make sure to also fill out and submit the Required Items Checklist (Part III) and the 1&M Agreement (Part IV) I. PROJECT INFORMATION Project name Flowers Tract Contact name Sabrina E. Davis Phone number 919-550-4740 Date September 24, 2007 Drainage area number 3 II. DESIGN INFORMATION Site Characteristics Drainage area 32,131 ftZ Impervious area 4,600 ft2 Percent impervious 0.14 Design rainfall depth 1.0 inch Peak Flow Calculations Does this project require prelpost control of the 1-yr 24-hr peak flow? 1-yr, 24-hr runoff depth 1-yr, 24-hr intensity Pre-development 1-yr, 24-hr runoff Post-development 1-yr, 24-hr runoff Pre/Post 1-yr, 24-hr peak control Storage Volume: Non-SR Waters Design volume Ponding depth of water Ponding depth of water Surface area of the top of the bioretention cell Length: Width: -or- Radius Storage Volume: SR Waters 1-yr, 24-hr depth Pre-development 1-yr, 24-hr runoff Post-development 1-yr, 24-hr runoff Minimum volume required Volume provided Soils Report Summary Drawdown time, ponded volume Drawdown time, to 24 inches below surface Drawdown time, total: In-situ soil.• Soil type Soil permeability Planting media soil: Soil type Soil permeability Soil composition n (Y or N) In inihr ft3/sec ft3/sec ft3/sec 349.0 ft3 12 inches OK 1.00 ft 350.0 ftz OK 25 ft OK 14 ft OK ft in ft3 ft3 ft3 ft3 12 hr OK 36 hr OK 48 hr Parcolet Loam 0.60 in/hr Sandy Loam 1.00 inihr OK Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 1 of 3 Permit Number: (to be provided by DWQ) Sand (by weight) Fines (by weight) Organic (by weight) Phosphorus Index (P-Index) Basin Elevations Temporary pool elevation Planting elevation (top of the mulch) Bottom of the cell Planting depth Depth of mulch SHWT elevation Are underdrains being installed? How many clean out pipes are being installed? What factor of safety is used for sizing the underdrains? (See BMP Manual Section 12.3.6) Additional distance between the bottom of the planting media and the bottom of the cell to account for underdrains Bottom of the cell required Distance from bottom to SHWT Type of bioretention cell (answer "Y" to only one of the two following questions): Is this a grassed cell? Is this a cell with trees/shrubs? Additional Information Does volume in excess of the design volume bypass the bioretention cell? Does volume in excess of the design volume flow evenly distributed through a vegetated filter? What is the length of the vegetated filter? Does the design use a level spreader to evenly distribute flow? Is the BMP located at least 30ft from surface waters (50ft if SA waters)? Is the BMP located at least 100ft from water supply wells? Are the vegetated side slopes equal to or less than 3:1? Is the BMP located in a recorded drainage easement with a recorded access easement to a public Right of Way (ROW)? Inlet velocity (from treatment system) Is the area surrounding the cell likely to undergo development in the future? Are the slopes draining to the bioretention cell greater than 20%? n (Y or N) Is the drainage area permanently stabilized? y (Y or N) Pretreatment Used (Indicate Type Used with an "X" in the shaded cell) Gravel and grass (flinches gravel followed by 3-5 ft of grass) Grassed swale Forebay Plants Number of tree species Number of shrub species Number of herbaceous groundcover species 85% OK 12% OK 3% OK ivuio 30 (unitless) OK 222.0 fmsl OK 221 fmsl 218.5 fmsl 2.5 ft 2 inches OK 180 fmsl OK Total: y (Y or N) 1 OK 10 1ft 217.5 fmsl 37.5 ft OK y (Y or N) OK n (Y or N) y (Y or N) n (Y or N) Excess volume must pass through filter. ft n (Y or N) Show how flow is evenly distributed. y (Y or N) y (Y or N) y (Y or N) y (Y or N) ft/sec n (Y or N) OK OK OK OK Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 2 of 3 Permit Number. (to be provided by DWG Attach supporting calculations/documentation. The soils report must be based upon an actual field investigation, soil borings, and infiltration tests. The results of the soils report must be verified in the field by DWQ, by completing & submitting the soils investigation request form. County soil maps are not an acceptable source of soils information. All elevations shall be in feet mean sea level (fmsl). Form SW401-Bioretention-Rev.1 Parts 1 and II. Design Summary, Page 3 of 3 Permit Number: (to be provided by DWQ) Sand (by weight) Fines (by weight) Organic (by weight) Phosphorus Index (P-Index) Basin Elevations Temporary pool elevation Planting elevation (top of the mulch) Bottom of the cell Planting depth Depth of mulch SHWT elevation Are underdrains being installed? 85% OK 12% OK 3% OK Total: 100% 30 (unitless) OK 222.0 fmsl OK 221 fmsl 218.5 fmsl 2.5 ft 2 inches OK 180 fmsl OK How many clean out pipes are being installed? What factor of safety is used for sizing the underdrains? (See BMP Manual Section 12.3.6) Additional distance between the bottom of the planting media and the bottom of the cell to account for underdrains Bottom of the cell required Distance from bottom to SHWT Type of bioretention cell (answer "Y" to only one of the two folbwing questions): Is this a grassed cell? Is this a cell with trees/shrubs? Additional Information Does volume in excess of the design volume bypass the bioretention cell? Does volume in excess of the design volume flow evenly distributed through a vegetated filter? What is the length of the vegetated filter? Does the design use a level spreader to evenly distribute flow? Is the BMP located at least 30ft from surface waters (50ft if SA waters)? Is the BMP localed at least 100ft from water supply wells? Are the vegetated side slopes equal to or less than 3:1? Is the BMP located in a recorded drainage easement with a recorded access easement to a public Right of Way (ROW)? Inlet velocity (from treatment system) Is the area surrounding the cell likely to undergo development in the future? Are the slopes draining to the bioretention cell greater than 20%? Is the drainage area permanently stabilized? Pretreatment Used (Indicate Type Used with an "X" in the shaded cell) Gravel and grass (flinches gravel followed by 3-5 ft of grass) Grassed swale Forebay Plants Number of tree species Number of shrub species Number of herbaceous groundcover species y (Y or N) 1 OK 10 1ft 217.5 fmsl 37.5 ft OK y (Y or N) OK n (Y or N) y (Y or N) n (Y or N) Excess volume must pass through filter. ft n (Y or N) Show how flow is evenly distributed. y (Y or N) y (Y or N) y (Y or N) OK y (Y or N) OK ft/sec n (Y or N) n (Y or N) OK y (Y or N) OK Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 2 of 3 Permit Number: (to be provided by DWQ) Attach supporting calculations/documentation. The soils report must be based upon an actual field investigation, soil borings, and infiltration tests. The results of the soils report must be verified in the field by DWQ, by completing & submitting the soils investigation request form. County soil maps are not an acceptable source of soils information. All elevations shall be in feet mean sea level (fmsl). Form SW401-eioretention-Rev.1 Parts I and II. Design Summary, Page 3 of 3 Permit Number: (to be provided by OWQ) O~~F W A TE9OG ©~~ __ NCDENR STORMWATER MANAGEMENT PERMIT APPLICATION FORM 401 CERTIFICATION APPLICATION FORM BIORETENTION CELL SUPPLEMENT This form must be filled out on line, printed and submitted with all of the required information. Make sure to also fill out and submit the Required Items Checklist (Part 111J and the 1&M Agreement (Part IV) I. PROJECT INFORMATION Project name Flowers Tract Contact name Sabrina E. Davis Phone number 919-550740 Date Septemt~er 24, 2007 Drainage area number 5 II. DESIGN INFORMATION Site Characteristics Drainage area 41,495 ftZ Impervious area 6,100 ftz Percent impervious 0.15 Design rainfall depth 1.0 inch Peak Flow Calculations Does this project require prelpost control of the 1-yr 24-hr peak n (Y or N) flow? 1-yr, 24-hr runoff depth in 1-yr, 24-hr intensity in/hr Pre-development 1-yr, 24-hr runoff ft3/sec Post-development 1-yr, 24-hr runoff ft3/sec Pre/Post 1-yr, 24-hr peak control ft3/sec Storage Volume: Non-SR Waters Design volume 449.5 ft3 Ponding depth of water 12 inches OK Ponding depth of water 1.00 ft Surface area of the top of the bioretention cell 450.0 ft OK Length: 30 ft OK Width: 15 ft OK -or- Radius ft Storage Volume: SR Waters 1-yr, 24-hr depth in Pre-development 1-yr, 24-hr runoff ft3 Post-development 1-yr, 24-hr runoff ft3 Minimum volume required ft3 Volume provided ft3 Soils Report Summary Drawdown time, ponded volume 12 hr OK Drawdown time, to 24 inches below surface 36 hr OK Drawdown time, total: 48 hr In-situ soil: Soil type Parcolet Loam Soil permeability 0.60 inlhr Planting media soil: Soil type Sandy Loam Soil permeability 1.00 in/hr OK Soil composition Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 1 of 3 Permit Number: (to 6e provided by DWQ) Sand (by weight) Fines (by weight) Organic (by weight) Phosphorus Index (P-Index) Basin Elevations Temporary pool elevation Planting elevation (top of the mulch) Bottom of the cell Pianting depth Depth of mulch SHWT elevation Are underdrains being installed? Total: How many clean out pipes are being installed? What factor of safety is used for sizing the underdrains? (See BMP Manual Section 12.3.6) Additional distance between the bottom of the planting media and the bottom of the cell to account for underdrains Bottom of the cell required Distance from bottom to SHWT Type of bioretention cell (answer "Y" to only one of the two following questions): Is this a grassed cell? Is this a cell with trees/shrubs? Additional Information Does volume in excess of the design volume bypass the bioretention cell? Does volume in excess of the design volume flow evenly distributed through a vegetated filter? What is the length of the vegetated filter? Does the design use a level spreader to evenly distribute flow? Is the BMP located at least 30ft from surface waters (50ft if SA waters)? Is the BMP localed at least 100ft from water supply wells? Are the vegetated side slopes equal to or less than 3:1? Is the BMP located in a recorded drainage easement with a recorded access easement to a public Right of Way (ROW)? Inlet velocity (from treatment system) Is the area surrounding the cell likely to undergo development in the future? Are the slopes draining to the bioretention cell greater than 20%? Is the drainage area permanently stabilized? Pretreatment Used (Indicate Type Used with an "X" in the shaded cell) Gravel and grass (8'inches gravel followed by 3-5 ft of grass) Grassed swale Forebay Plants Number of tree species Number of shrub species Number of herbaceous groundcover species 85% OK 12% OK 3% OK ~„ ,,, 30 (unitless) OK 213.0 fmsl OK 212 fmsl 209.5 fmsl 2.5 ft 2 inches OK 185 fmsl OK y (Y or N) 1 OK 10 1ft 208.5 fmsl 23.5 ft OK y (Y or N) OK n (Y or N) y (Y or N) n (Y or N) Excess volume must pass through filter. ft n (Y or N) Show how flow is evenly distributed. y (Y or N) y (Y or N) y (Y or N) OK y (Y or N) OK ftlsec n (Y or N) n (Y or N) OK y (Y or N) OK Form SW401-Bioretention-Rev.1 Pans I and II. Design Summary, Page 2 of 3 Permit Number: (to be provided by DWQ) Attach supporting calculationsldocumentation. The soils report must be based upon an actual field investigation, soil borings, and infiltration tests. The results of the soils report must be verified in the field by DWQ, by completing & submitting the soils investigation request form. County soil maps are not an acceptable source of soils information. All elevations shall be in feet mean sea level (fmsl). Form SW401-Bioretention-Rev.t Parts I and II. Design Summary, Page 3 of 3 Permit Number: (to be provided by DWQ) ®. O~o~ W ATF9OGv r NCDENR STORMWATER MANAGEMENT PERMIT APPLICATION FORM 401 CERTIFICATION APPLICATION FORM BIORETENTION CELL SUPPLEMENT This form must be filled out on line, printed and submitted with all of the required information. Make sure to also fill out and submit the Required Items Checklist (Part Ill) and the I&M Agreement (Parf IV) I. PROJECT INFORMATION Project name Flowers Tract Contact name Sabrina E. Davis Phone number 919-550-4740 Date September 24, 2007 Drainage area number 6 II. DESIGN INFORMATION Site Characteristics Drainage area 47,040 ftZ Impervious area 6,500 ft2 Percent impervious 0.14 Design rainfall depth 1.0 inch Peak Flow Calculations Does this project require pre/post control of the 1-yr 24-hr peak n (Y or N) flow? 1-yr, 24-hr runoff depth in 1-yr, 24-hr intensity in/hr Pre-development 1-yr, 24-hr runoff ft3/sec Post-development 1-yr, 24-hr runoff ft3/sec PrelPost 1-yr, 24-hr peak control ft3/sec Storage Volume: Non-SR Waters Design volume 508.5 ft3 Ponding depth of water 12 inches OK Ponding depth of water 1.00 ft Surface area of the top of the bioretention cell 512.0 ft OK Length: 32 ft OK Width: 16 ft OK -or- Radius ft Storage Volume: SR Waters 1-yr, 24-hr depth In Pre-development 1-yr, 24-hr runoff ft3 Post-development 1-yr, 24-hr runoff ft3 Minimum volume required ft3 Volume provided ft3 Soils Report Summary Drawdown time, ponded volume 12 hr OK Drawdown time, to 24 inches below surface 36 hr OK Drawdown time, total: 48 hr In-situ soih. Soil type Parcolet Loam Soil permeability 0.60 in/hr Planting media soil: Soil type Sandy Loam Soil permeability 1.00 in/hr OK Soil composition Form SW401-Bioretention-Rev.1 Parts 1 and II. Design Summary, Page 1 of 3 Permit Number: (to be provided by DWQ) Sand (by weight) Fines (by weight) Organic (by weight) Phosphorus Index (P-Index) Basin Elevations Temporary pool elevation Planting elevation (top of the mulch) Bottom of the cell Planting depth Depth of mush SHWT elevation Are underdrains being installed? 85% OK 12% OK 3% OK Total: 100% 30 (unifless) OK 211.0 fmsl OK 210 fmsl 207.5 fmsl 2.5 ft 2 inches OK 185 fmsl OK How many clean out pipes are being installed? What factor of safety is used for sizing the underdrains? (See BMP Manual Section 12.3.6) Additional distance between the bottom of the planting media and the bottom of the cell to account for underdrains Bottom of the cell required Distance from bottom to SHWT Type of bioretention cell (answer "Y" to only one of the two following questions): Is this a grassed cell? Is this a cell with treeslshrubs? y (Y or N) 1 OK 10 1tt 206.5 fmsl 29.5 tt OK y (Y or N) OK n (Y or N) Additional Information Does volume in excess of the design volume bypass the y (Y or N) bioretention cell? Does volume in excess of the design volume flow evenly distributed n (Y or N) Excess volume must pass through filter. through a vegetated filter? What is the length of the vegetated filter? tt Does the design use a level spreader to evenly distribute flow? Is the BMP located at least 30ft from surface waters (50tt if SA waters)? Is the BMP localed at least 100tt from water supply wells? Are the vegetated side slopes equal to or less than 3:1? Is the BMP located in a recorded drainage easement with a recorded access easement to a public Right of Way (ROW)? Inlet velocity (from treatment system) Is the area surrounding the cell likely to undergo development in the future? Are the slopes draining to the bioretention cell greater than 20%? Is the drainage area permanently stabilized? Pretreatment Used (Indicate Type Used with an "X" in the shaded cell) Gravel and grass (8`inches gravel followed by 3-5 tt of grass) Grassed swale Forebay Plants Number of tree species Number of shrub species Number of herbaceous groundcover species n (Y or N) Show how flow is evenly distributed. y (Y or N) y (Y or N) y (Y or N) OK y (Y or N) OK ftlsec n (Y or N) n (Y or N) OK y (Y or N) OK Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 2 of 3 Permit Number: (to be provided by DWQ) Attach supporting calculations/documentation. The soils report must be based upon an actual field investigation, soil borings, and infiltration tests. The results of the soils report must be verified in the field by DWQ, by completing & submitting the soils investigation request form. County soil maps are not an acceptable source of soils information. All elevations shall be in feet mean sea level (fmsl). Form SW401-Bioretention-Rev.1 Parts I and II. Design Summary, Page 3 of 3 ~ x p o'~ - 5 2 2 PORTO FIND Clayton, NORTH CAROLINA _ BIORETENTIONAREAS # 1-6 OPERATION AND MAINTENANCE AGREEMENT (Revised 10/05/07) WLT-07010 October 2007 SECTION I MAINTENANCE OF EMBANKMENTS ~~ I. MAINTEN~iNCE OFBIORETENTIONAREA EMBANSMENTS A. Vegetation The primary vegetative ground cover for all berm/embankments (excluding inside the wet pond facility) is to be tall fescue. Proper maintenance of this cover will serve to prevent erosion while providing optimal access for inspection as well as preventing excessive sediment from entering the facility. Woody vegetation and trees should not be allowed to propagate on the dam embankments or top of dam. Trees and brush, if desired, are acceptable on embankments other than the dam. Inspection of embankment centipede sod condition should be performed monthly or after every rainfall event greater than 0.5 inches of rainfall over a 24-hour period. 1. Seeding: Seeding should be accomplished by the use of a spiker and large tractor aerifier to ensure proper seed and soil contact along the top of banks. The temporary and permanent seeding schedules are shown on the bioretention area detail sheet, which has been included within this manual. Reseeding may be necessary in instances where initial seeding failed or existing areas have been compromised. The seeding schedules shown on the original design documents for the bioretention area should be followed for any necessary reseeding. 2. Mowing: All vegetative cover should be maintained below 6" in height. Due to the slope of the embankments, string trimmers (no mechanical mowers) must be utilized for mowing turf. Mowing and maintenance should be performed once a month to keep the maximum grass height below 6 inches and to maintain appropriate turf cover and health of turf. B. Erosion Erosion is initiated when vegetative cover is insufficient and/or concentration of runoff destabilizes centipede sod. Runoff then tends to concentrate into channel flow, and soils tend to become entrained in the water and be transported downstream. Unsuitable fill material, inadequate compaction, and/or poor stabilization of centipede sod can accelerate the erosion process. This has a negative environmental impact on downstream features, and has the potential to undermine the stability of the wet pond. facility. Erosion can be minimized with the proper care of centipede sod and the use of appropriate methods to repair eroded areas and prevent recurrences of eroded areas. Appropriately, compacted soil meeting the berm design requirements will be placed in any gullies or rills, and then reseeded as described above. Re-occurrence of erosive problems should be addressed with appropriate geotextile fabrics that are installed according to manufacturer's instructions and per an engineer's recommendation. Uneven surfaces on the crest of the berm may lead to the formation of rills and/or gullies. It is possible to eliminate this problem by properly filling any depressed areas such that the entire top of berm is flat and level. Addition of fill to the top of berm should be completed by first preparing the existing soil such that a distinct boundary layer does not form beneath existing soil and newly placed soil. New fill should meet all soil requirements (as to material, placement, and compaction) as stated on the original design documents for this structure. Inspection for erosion should be performed monthly or after every major rainfall- event. Abutment (or toe) areas: The location where the fill of the berm contacts the existing ground is the abutment (or toe). Erosive channels have a tendency to form in these areas. Appropriate geotextile fabrics, as mentioned above, may be necessary to prevent or stop this form of erosion from occurring. An engineer is required if erosion in this area is significant. C. Seepage 1. Detection: Soft wet areas and. flowing springs are an indication of seepage. Early indicators of seepage include vegetation which is more robust than surrounding centipede sod. Vegetation normally associated with wetland areas such as cattails, ferns, reeds- and mosses may also indicate the initiation of seepage. The previously described abutment (or toe) area is a common location for seepage to occur. Another common location for seepage problems is the area where the outlet structure exits the berm section. This is especially true in cases where the soil around the barrel is not compacted properly. Another problem related to seepage may be indicated by the occurrence of `boils' below the abutment of the dam. These boils are springs that tend to deposit soils. Locating the occurrence of any boils should be included in the bi-annual inspection of the facility. `Boils' are a possible indication of -piping and could lead to berm failure. Piping occurs when a void space is formed within the interior of the berm embankment. These void spaces tend to be preferred - paths for water to travel, which will erode the interior of the berm and lead to failure. D. Cracks, Slides, Sloughing and Settlement Cracks: Large, well-defined cracks of greater than '/a" width indicate the potential for serious problems and the inspector of the facility should be alert for their presence. Cracks in the berm generally follow one of two patterns: • Transverse cracks appear perpendicular to the length of the berm and may be caused by differential settlement. Transverse cracks increase the likelihood of the formation of piping and seepage. • Longitudinal cracks appear horizontally along the berm and could serve as warnings to a future slide event. Longitudinal cracks in newly constructed berms may be an indication of poor compaction techniques and poor foundation preparation. 2. Slides: Slides and slumps have the potential to critically undermine the integrity of the berm. Arch-shaped cracks that expose soil indicate the initiation of slides. Detection of slides by inspectors should be addressed in a timely manner and a geotechnical engineer should be contacted for consultation. 3. Settlement: Settlement of the soil in the berm reduces freeboard in large storm events and may even lead to overtopping. Differential settlement of the berm can also lead to the concentration of runoff and therefore erosion as mentioned above. For this reason the berm should be maintained uniformly to its original design elevation. Greater than six inches of settlement may be indicative of significant issues within the berm foundation and could lead to catastrophic failure. Indications of this degree of settlement necessitate inspection by a geotechnical engineer. 4. Inspections for cracks, slides,_ sloughing, and settlement should be performed biannually. Actions to take if any of the above is detected: Any of the problems mentioned above require that a geotechnical or civil engineer be contacted, and that corrective action be taken. SECTION II SEDIMENT MONITORING II. SEDIMENT MONITORING A. Bioretention Area Accumulation of sediment within the bioretention area should be kept to a minimum by stabilization of the bioretention drainage area and proper prevention of erosion. Excess sediment. accumulation within the bioretention area will cause suffocation. of the bioretention area - centipede sod, thus crippling the water.._ quality function of the bioretention area. Inspection for sediment deposition should be performed biannually. 1. Check the depth at various points within the bioretention area, especially in the upland areas around the inlets to the bioretention area. Accumulated sediment will be removed semiannually or when the depth reaches 0.5 inches or more. A stake shall be set during construction to indicate 0.5 inches of - sediment accumulation. The measuring device used to determine the sediment elevation shall be such that it will give an accurate depth reading and not readily penetrate into accumulated sediments. 2. Removed sediment shall be disposed of in an appropriate manner and shall be handled in a manner that will not adversely impact water quality (i.e. stockpiling -near the bioretention area or surrounding streams). 3. If the elevation of the bio-retention area bottom exceeds the planned elevation, the sediment shall be removed to design levels: This shall be performed by removing the upper 6 inches of soil and stockpiling the soil. The soil shall not be stockpiled for more that 2 weeks. Any dead or damaged bio-retention area plants must be replaced after this process per the original planting plan. B. Forebay Accumulation of sediment within the forebay area should be kept to a minimum by stabilization of the bioretention area drainage area and proper prevention of erosion. Excess sediment accumulation within the forebay area will cause sediment transport to the main pool of the bioretention area and subsequent difficulty with maintenance procedures. Inspection for sediment deposition should be performed biannually. Check the depth at various points within the forebay, especially in the .upland areas around the inlets to the bioretention area. Accumulated sediment will be removed semiannually or when the depth reaches 2 inches or more. A stake shall be set during construction to indicate 2 inches of sediment accumulation. The measuring device used to determine the sediment elevation shall be such that it will give an accurate depth reading and not readily penetrate into accumulated sediments. 2. Removed sediment shall be disposed of in an appropriate manner and shall be handled in a manner that will not adversely impact water quality (i.e. stockpiling near the pond basin or streams). 3. NCDOT class "B" rip-rap is recommended to form the forebay. This rip-rap shall be replaced annually or when necessary between annually replacements. Care should be taken to insure that a 12" lip of rip-rap is maintained at all times .around the perimeter of the forebay. This lip prevents the occurrence of an erosive environment. Loss of the lip could result in the loss of the water quality benefits associated with the bio-retention area. C. Principal Spillway System 1. If present, remove accumulated sediment from the outlet structure. The principal spillway system should be inspected for sediment accumulation monthly or after every rainfall event greater than 0.5 inches of rainfall over a 24-hour period. D. Storm Drainage System 1. The upstream storm drainage- system should be maintained along with the bioretention area. Trash from the site has a tendency to be washed into the storm drainage system and become lodged in the catch basins or pipes. The catch basins and pipes should be cleaned of debris at the time that maintenance is performed on the bioretention area. Sediment may accumulate in portions of the storm drainage system where slopes are relatively flat. This sediment may be washed out of the system, or flushed with a - garden hose. Sediment shouhi be flushed monthly or after every rainfall event greater than 0.5 inches of rainfall over a 24-hour period. Steps should be taken to trap this "flushed" sediment at the entrance to the bioretention area to prevent it from -being deposited within the wet pond. SECTION III MAINTENANCE OF O UTLET STRUCTURES _ _,~_, III. MAINTENANCE OF OUTLET STR UCTURES The bioretention area is designed to pass stormwater quality storms through the low flow orifice located in the secondary outlet structure and larger storm events through the principal spillway. It is of vital importance that these structures remain unblocked so that the hydraulic functionality is not compromised. The outlet structure system should be inspected to ensure that it is functioning ~.'~• properly. A. Bio-Retention Underdrain System 1. The underdrain system for both bio-retention areas consists of a series of 8-inch diameter perforated HDPE pipes. These underdrain pipes connect to the concrete principal spillway drop inlet via 8-inch diameter HDPE pipes. Tied to the underdrain system are vertical HDPE cleanouts that extend up to the surface of the mulch layer. The underdrain system is wrapped in a nonwoven geotextile filter fabric and is installed within a gravel - jacket in order to minimize the probability of blockage. However, in the event that the underdrain systems become blocked, the bio-retention area will not drain appropriately and will tregin to pond up, which means---that the water quality benefits associated with the bio-retention area are lost. The underdrain system should be inspected for blockage monthly or - - after every rainfall event greater than 0.5 inches of rainfall over a 24 hour period. If inspected after a major rainfall event, all ponded water should dissipate over 4-6 hours. Debris causing the blockage should be promptly removed from the underdrain system such that sufficient infiltration through the bio-retention area may occur. The underdrain systems may be accessed / flushed out via the HDPE cleanouts located at the top of the mulch layer. B. Principal Spillway 1. The principal spillway for the bioretention area consists of a 4' x -- 4' square weir box structure attached to a 18-inch O-ring RCP barrel. The principal spillway is responsible for safely conveying larger storm events through the facility. The principal spillway system is expected to remain robust throughout the life of the bioretention area, but periodic inspection of the system is required. This inspection should occur biannually. The inspector should check for the presence of spalling, scaling, or cracking in the spillway system. Spalling is evident when pieces of concrete fall from the main pipe. It is defined as breaking, chipping, or fraying of concrete slabs that leave an uneven surface or edge, most often at joints or cracks. Scaling occurs when the surface of the concrete begins to flake off. The presence of cracking is indicated by separations in the concrete that are not located in the joints. Cracking can indicate the presence of structural problems and lead to leaks. Cracking can cause loss of the water tightness of the system, which can lead to piping (i.e. migration of soil particles into the pipe}. If piping occurs, the risk of failure of the dam structure is greatly increased. Evidence. of any of the above issues requires that an engineer be contacted for additional inspection to determine the need for repairs. 2. _ If the principal spillway system becomes blocked so that it does not operate at full capacity, the risk of dam overtopping or other . uncontrolled releases may result. Therefore, to ensure hydraulic capacity of the spillways, the principal spillway system should be _ ..~ inspected for blockage monthly or after each major rainfall ~~ event. -Any vegetative growth that occurs within the principal spillway system should be removed promptly so that the full hydraulic capacity of the system is maintained. C. Stormwater Pipes 1. The underground pipes should be inspected for any structural damage. Structural damage includes but is not limited to deterioration, joint failure, punctures, cracks, misalignment, settling;- leaking, deflection, and sagging. Deformations in the - ground surface directly above or near the stormwater pipe may be a sign of failure in the system. Any structural damage - -- should- be immediately reported to a register professional engineer so that the appropriate course of action can be determined. 2. The underground pipes, including inlet and outlet areas, should be inspected for trash/debris accumulation to ensure runoff can move freely into and out of the pipes. Any accumulated trash/debris should be removed and disposed of in an approved manner. D. Ground Surface The ground surface should be inspected for visual signs of sink holes. If any signs of a sink hole are present, a registered professional engineer should be immediately consulted for remediation action. a. SECTION IV MAINTENANCE OF BIO-RETENTION AREA CENTIPEDE SOD IY. Maintenance of Bio Retention Area Centipede sod A. Bio-retention Area Centipede sod 1. Once the construction of the bio-retention area is complete, the centipede sod should be watered for 14 consecutive days unless sufficient natural rainfall in order to establish the centipede sod appropriately. 2. The centipede sod should be visually inspected monthly (more •- - frequently in the summer) for disease or pest problems. If pest treatment is necessary, use the least toxic .method. All dead and diseased centipede sod considered beyond treatment should be removed and replaced. The centipede sod should be kept healthy and vibrant. If necessary, it should be over seeded (usually in the fall -September to October) at a rate of 100 lbs/acre. 3. The grass within the bio-retention area should be mowed to a height ofno greater than 8 inches. 4. During extreme heat and drought conditions, the centipede sod should be inspected for physical features of stress (i.e. wilting, yellow, spotted, loss of, or brown leaves, etc.). During these conditions, the bio-retention areas should be watered as necessary. 5. Weeds and other invasive species should be removed whenever present. B. Planting Soil Layer 1. The planting soil layer should be visually inspected for erosion/damage once a month. Evidence of erosion should be promptly repaired. If erosion is present along the drainage path within the bio-retention area, it may be stabilized using. small stones. 2. The pH of the bio-retention area should be checked twice a year. If necessary, apply an alkaline product (such as limestone) to maintain the appropriate pH. Please reference the detail sheet for the bio-retention area included in this report for the appropriate pH levels. 3. If present, accumulated trash, litter, and debris should be removed during. the monthly inspection. 4. If present, accumulated sediment .should be removed per the "Sediment Monitoring" section of this manual.