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HomeMy WebLinkAbout20070081 Ver 2_More Info Received_20070807~. o~I-oogt ~'2 Letter of Transmi tal To: Aiken & Yelle Associates, PA AYES Professional Engineers & Land Surveyors 3755 Benson Drive Raleigh, North Carolina 27609 919-877-9992 Fax 919-877-9979 e-mail: ayes@Bellsouth.net NC ~~ ~ Date: g ~ p ~~ ~ E ><P~PSS P~,t m i ~~ y ~ ~ Fed Ex Hand Delivery : X Mail Attn.: ' _. ~ G. 1~'1 u [~ ~t Subject : ~S:_,etir 12 ~~~ Courier Pick-Up ~~ Included: ~~.~~ 1x10 j ~~ ~ maples a~ c~~eN1~ (~p~~se ~~e~ A~NFifrU ~p'r1i.y'~,~~'?~~41ltl,i~iY (~1 ~ S~-~ ~~ ~~~ ~~d `j bcc~~~ ~ eve '~,.}©~ (c8~lec~.~ e,~c,~ ccS~.ev.S~c;.~~is ~ c ,, ~f~rti~~~, ~~~ ~~ ~ a ~_ 41 ~\V 1 ~\ ~ " ~~ ~~C~i~r~~~~~ Cit~C~1 " IV~I ~~~i/l~~flC C ~,/1 V Gtill Comments: ~-~ p~- X081 V' Z. STORMWATER OPERATION & MAINTENANCE MANUAL AND BUDGET FOR BIO RETENTION AREAS IN CEDAR RIDGE SUBDIVISION PHASES 2, 3, 4 & 5 Prepared by: Aiken & Yelle Associates, PA 3755 Benson Drive Raleigh, NC 27609 ~~~~~~~~ €1`~. ~,~~C '~ ZQQ% lS~fVr'~ - Y'S'rtil`~r`4 tiaslr\i.iiY w~~o~ ~~n ~r~~~,A~~~~ bR~w~n OPERATIONS AND MAINTENACE MANUAL SECTION I- INTRODUCTION: This manual establishes procedures for maintenance and operation of stormwater in accordance with the guidelines as set forth in the NCDWQ Stormwater Management Design Manual. The NCDWQ rules require that stormwater devices be inspected annually and that they be maintained in accordance with this document. Any repairs that become necessary as a result of periodic inspections shall be completed within thirty (30) calendar days of filing the report unless written approval of and extension is obtained from the Town of Rolesville or NCDWQ. The storm water management plan for this site consists of only water quality Bio Retention areas. The Bio Retention areas are to serve as a bio-filtration to reduce the nitrogen loading from the proposed impervious surface. This development will be developed in four phases as approved by the Town of Rolesville as depicted on the preliminary site plan on file in the Town of Rolesville Planning Department. All phasesl will be developed in accordance with construction drawings entitled "Cedar Ridge Subdivision", prepared by Aiken & Yelle Associates, PA, dated August 7, 2007 and approved by Town of Rolesville Central Engineering Division. Therefore the water quality Bio Retention areas will also be installed by phases. The Bio Retention areas to be constructed by phases are as follows: A. Phase 2 Phase 2 of this development plan includes the construction of one (1) water quality Bio Retention area as shown on the "Cedar Ridge Subdivision- Phase 2, 3, 4 and 5 Construction Drawings", prepared by this firm, dated 08/07/07. Bio Retention area #1 will be constructed within a public drainage easement on Lot 111 of the proposed subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #73. The Bio Retention surface area required is be 1700 SF (approx. 95 feet in length and 18 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. B. Phase 3 Phase 3 of this development plan includes the construction of one (1) water quality Bio Retention area as shown on the "Cedar Ridge Subdivision- Phase 2, 3, 4 and 5 Construction Drawings", prepared by this firm, dated 08/07/07. Bio Retention area #11 will be constructed on Lots 65 & 66 of the proposed subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #2 (SMH#2). The Bio Retention surface area required is Page 2 o f 1-~ 2,000 SF (approx. 65 feet in length and 36 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. C. Phase 4 Bio Retention area #2 will be constructed within a designated open space area proposed for this subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #61 B (SMH#61 B). The Bio Retention surface area will be 3,000 SF (approx. 85 feet in length and 50 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Bio Retention area #3 will be constructed within a designated open space area proposed for this subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #64 (SMH#64). The Bio Retention surface area will be 950 SF (approx. 66 feet in length and 50 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Bio Retention area #4 will be constructed within a public drainage easement on Lot 100 of the subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #57 (SMH#57). The Bio Retention surface area will be 2,300 SF (approx. 141 feet in length and 23 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 9 inches. Bio Retention area #5 will be constructed within a public drainage easement on Lot 94 of the subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #51 (SMH#51). The Bio Retention surface area will be 2,000 SF (approx. 100 feet in length and 27 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Bio Retention area #6 will be constructed within a public drainage easement on Lot 87 of the subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #40 (SMH#40). The Bio Retention surface area will be 850 SF (approx. 54 feet in length and 18 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Bio Retention area #7 will be constructed within a public drainage easement on Lot 80 of the subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #33 (SMH#33). The Bio Retention surface area will be 1,850 SF (approx. 64 feet in length and 39 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Bio Retention area #8 will be constructed within a public drainage easement on Lot 70 of the subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #24 (SMH#24). The Bio Retention surface area will be 2,700 SF (approx. 119 feet in length and 27 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Page 3 o f 1=~ Bio Retention area #9 will be constructed within a designated open space area proposed for this subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #13 (SMH#13). The Bio Retention surface area will be 2,050 SF (approx. 88 feet in length and 32 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. Bio Retention area #10 will be constructed within a designated open space area proposed for this subdivision. More specifically the Bio Retention area will be located down stream from storm sewer manhole #10 (SMH#10). The Bio Retention surface area will be 500 SF (approx. 36 feet in length and 17 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. D. Phase 5 Phase 5 of this development plan includes the construction of one (1) water quality Bio Retention area as shown on the "Cedar Ridge Subdivision- Phase 2, 3, 4 and 5 Construction Drawings", prepared by this firm, dated 08/07/07. Bio Retention area #11 will be constructed on Lots 156 & 164 of the proposed subdivision. More specifically the Bio Retention area will be located down stream from headwall #38 (HW#38). The Bio Retention surface area required is 1,250 SF (approx. 209 feet in length and 6 feet in width) with side slopes of 3 (H): 1'(V) and a depth of 1 foot. SECTION II- WATER QUALITY BIO RETENTION AREA MAINTENANCE REQUIREMENTS: 1. Watering: Plants should be selected to be tolerant of the bioretention facility's particular conditions. Watering should not be required after establishment (about 2 to 3 years). However, watering may be required during prolonged dry periods after plants are established. 2. Erosion Control: Inspect flow entrances, ponding area, and surface overflow areas periodically. Replace soil, plant material, and/or mulch in areas where erosion has occurred. Erosion problems should not occur with proper design except during extreme weather events. If erosion problems do occur, the following issues should be re-assessed: flow volumes from the contributing drainage area and bioretention size; flow velocities and gradients within the bioretention facility; flow dissipation and erosion protection methods in the pretreatment and in-flow areas. If sediment is deposited in the bioretention facility, immediately determine the source, remove excess deposits, and correct the problem. 3. Plant Material: Depending on plants selected and aesthetic requirements, occasional pruning and removal of dead plant material may be necessary. Replace all dead plants. However, if specific plants consistently have a high mortality rate, assess the cause and replace with appropriate species. Periodic Page =l of 1=l weeding is necessary until groundcover plants are established. Weeding should become less frequent if an appropriate plant density has been used. 4. Nutrients and Pesticides: The soil media and plant material should have been selected for optimum fertility, plant establishment, and growth within the particular conditions of each bioretention facility. Nutrient and pesticide inputs should NOT be required and will degrade the pollutant processing capability of the bioretention facility, as well as contribute to additional pollutant loading to receiving waters. By design, bioretention facilities are typically specified in watersheds where phosphorous and nitrogen levels are often elevated. Therefore, these should not be limiting nutrients with regard to plant health. If in question, have the soil analyzed for fertility. 5. Mulch: Replace mulch annually in bioretention facilities where heavy metal deposition is likely (e.g., drainage areas that include commercial/industrial uses, parking lots, or roads). In residential or other settings where metal deposition is not a concern, replace or add mulch as needed to maintain a 2 to 4 inch depth at least once every two years. 6. Soil media: Soil mixes for bioretention facilities are design to maintain long-term fertility and pollutant processing capability. Estimates from metal attenuation research indicates that metal accumulation should not present a toxicity concern for at least 20 years in bioretention facilities (USEPA 2000). Further, replacing mulch where heavy metal deposition is likely provides an additional factor of safety for prolonged bioretention performance. If in question, have soil analyzed for fertility and pollutant levels. When the filtering capacity diminishes substantially (e.g., when water ponds on the surface for more than 12 hours), remedial actions must be taken. One possible problem is that underdrain pipe systems can become clogged. Annual flushing through pipe cleanouts is recommended to facilitate unclogging of the pipes without disturbing the bioretention areas. If the water still ponds for more than 12 hours, the top few inches of material should be removed and replaced with fresh material. The removed sediments should be disposed of in an acceptable manner (e.g., landfill). If that does not solve the problem, more extensive rebuilding is required. Examples of When to Perform Maintenance Thin Mulch in the Bioretention Cell Remove top layer of fill media when the pool does not drain quickly. The pool is designed to drain within 12 hours. Operation and Maintenance procedures: -Immediately after the bioretention cell is established, the plants will be watered twice weekly if needed until the plants become established (commonly six weeks). -Snow, mulch or any other material will NEVER be piled on the surface of the bioretention cell. - Heavy equipment will NEVER be driven over the bioretention cell. Page J o f 1 ~ -Special care will be taken to prevent sediment from entering the bioretention cell. - Once a year, a soil test of the soil media will be conducted. After the bioretention cell is established, I will inspect it once a month and within 24 hours after every storm event greater than 1.0 inches. Records of inspection and maintenance will be kept in a known set location and will be available upon request. Inspection activities shall be performed as follows. Any problems that are found shall be repaired immediately. Inspection and Maintenance Provisions for Bioretention Areas BMP element Potential problems How to remediate the problem The entire BMP Trash/debris is present Remove the trash/debris The perimeter of the Areas of bare soil and/or Regrade the soil if bioretention cell erosive gullies have necessary to remove the formed. gully, and then plant a ground cover and water until it is established. Provide lime and a one- time fertilizer a lication. The inlet device: pipe, the pipe is clogged (if Unclog the pipe. Dispose stone verge or swale applicable). of the sediment off-site. The pipe is cracked or Replace the pipe. otherwise damaged (if applicable). Regrade the swale if necessary to smooth it Erosion is occurring in over and provide erosion the control devices such as swale (if applicable). reinforced turf matting or riprap to avoid future problems with erosion. Stone verge is clogged or Remove sediment and covered in sediment (if clogged stone and applicable) replace with clean stone. Page 6 of 14 Inspection and Maintenance Provisions for Bioretention Areas continued BMP element::: Potential problems How to remediate the problem The pretreatment area Flow is bypassing Regrade if necessary to pretreatment area route all flow to the and/or gullies have pretreatment area. formed. Restabilize the area after radin Sediment has Search for the source of accumulated to a depth the sediment and greater than three remedy the problem if inches. possible. Remove the sediment and restabilize the retreatment area. Erosion has occurred. Provide additional erosion protection such as reinforced turf matting or riprap if needed to prevent future erosion roblems. Weeds are present Remove the weeds, preferably by hand. The bioretention cell: Best professional Prune according to best Vegetation practices professional show that pruning is practices. needed to maintain optimal plant health. Plants are dead, Determine the source of diseased or the problem: soils, dying. hydrology, disease, etc. Remedy the problem and replace plants. Provide aone-time fertilizer application to establish the ground cover if a soil test indicates it is necessa Tree stakes/wires are Remove tree stake/wires present (which can kill the tree if six months after not removed). plantin . Page 7 o f 14 The bioretention cell: Mulch is breaking down Spot mulch if there are soils and mulch or only random void areas. has floated away. Replace whole mulch layer if necessary. Remove the remaining much and replace with triple shredded hard wood mulch at a maximum depth of three inches. The bioretention cell: Soils and/or mulch are .Determine the extent of soils and mulch clogged with sediment. the clogging-remove and replace either just the top layers or the entire media as needed. Dispose of the spoil in an appropriate off-site location. Use triple shredded hard wood mulch at a maximum depth of three inches. Search for the source of the sediment and remedy the problem if possible An annual soil test Dolomitic lime shall be shows that applied as pH has dropped or recommended per the heavy soil test and toxic soils metals have shall be removed, accumulated in disposed of properly and the soil media. replaced with new plantin media. The underdrain system Clogging has occurred Wash out the underdrain (if applicable system The drop inlet Clogging has occurred Clean out the drop inlet. Dispose of the sediment off-site. The drop inlet is Repair or replace the damaged drop inlet. The receiving water Erosion or other signs of Contact the NC Division damage have occurred of Water Quality 401 at the outlet. Oversight Unit at 919- ~ 733-1786. Page 8 of 14 SECTION V: OPERATION A. Record Keeping Operation of the storm water maintenance device should include recording of the following: • Annual Inspection Reports- Inspections should be conducted. A professional engineer or his/her representative should conduct the inspection. Reports should be kept on file with the Homeowner's Association and a copy given to the Central Engineering Division of the Town of Rolesville. • Observations- All visual observations should be recorded. Where periodic visual inspections are performed following significant rainfall events (2" of rainfall in 24 hours or greater event), these inspections should be logged into the Periodic Inspections, Operation & Maintenance Form in Section X of this manual. • Maintenance- Written reports of maintenance and/or repairs should be recorded on the Periodic Inspections, Operation & Maintenance Form in Section X of this manual. B. Other Operational Procedures The Owner's Association should maintain a complete and up-to-date set of plans (as-built drawings) and all changes made to the storm water maintenance devices over time should be recorded on the as-built plans. SECTION VI: BUDGET A. Annual Budget- Water Quality Bio Retention areas 1-12 Annual Inspection & Report Registered Engineer 1 visit @ 8hrs/visit x $90/hour= $ 800.00 Miscellaneous Visits= $ 500.00 Maintenance Cost for mowing, seeding fertilizing And trash removal (2xs annual) $ 600.00 Sediment cost removal (every 5 years) annualized cost $ 600.00 Total Annual Budget (Water Quality Grass Lined Bio Retention areas= $2,500.00 Page 9 o f 14 B. Total of Construction Cost for Water Quality Grass Line Bio Retention areas. Water Quality Bio Retention areas Bio Retention areas 12 @ $6,000/per = $ 72,000.00 Seeding 664 LF (a, $ 0.50/LF = $ 332.00 Sub-total = $ 72,332.00 Total Construction Cost for Water Quality Grass Line Bio Retention areas: $72,332.00 Page 10 of 1;~ WATER QUALITY BIO RETENTION AREA INSPECTION CHECKLIST CEDAR RIDGE SUBDIVISION INSPECTOR/(S): WEATHER: DATE: TIME: o WATER QUALITY BIO RETENTION AREA ~ ~- U r~ v ° CHECK/CIRCLE ~ ~ CONDITION NOTED OBSERVATION U Bio Retention area # Location: Vegetation Erosion Sediment Trash Bio Retention area # Location: Vegetation Erosion ACTION F d ~ C7 ~ rr O t-- "' a °z ~ ~ ~ Sediment Trash Bio Re tention area # Location: Vegetation/ cover Erosion Sediment Trash Bio Ret ention area # Location: Vegetation/ cover Erosion Sediment Trash Bio R etention area # Location• Vegetation/ cover Erosion Sediment Trash Bio R et ention area # Location: Vegetation/ cover Erosion Sediment Trash GENERAL COMMENTS, SKETCHES & FIELD MEASUREMENTS: Page 11 o f I -1 CEDAR RIDGE SUBDIVISION WATER QUALITY BIO RETENTION AREAS PERIODIC INSPECTION, OPERTIAON AND MAINTENANCE REECORDS DATE TIME RAIN (in.) WEATHER CONDITIONS GENERAL OBSERVATIONS OR COMMENTS RECORDED BY DATE MAINTENANCE PEIU"ORMED COiVIMENTS RECORDED BY Pc~~ge 12 o f ~ 1-l MAINTENANCE AGREEMENT Project: Cedar Ridge Subdivision Responsible Party: Cedar Ridce Subdivision Homeowners' Association Address: 8804 Albright Drive Ralei h North Carolina 919-614-1733 Monthly Inspection- A. Visual inspection for signs of erosion after aone-inch or more rainfall event over a 24-hour period to determine if any appreciable damage occurred which would require repair to the stormwater device. B. Remove thrash and debris from inlets and outlets, emergency spillways and Bio Retention areas. II. Quarterly Inspections and Maintenance: A. Same as the monthly described above. III. Semi-Annually and Maintenance: A. Same as quarterly inspection B. Grassing and mowing as required. C. Reseed or re-vegetate disturbed vegetative areas. IV. Annual Inspection and Maintenance: A. Same as quarterly and semi-annual inspections. B. Registered Engineer inspects and confirms that the stormwater devices are operating properly and are in good physical condition. A copy of the inspection reports in Section X of this report shall be submitted to the Central Engineering Department of the Town of Rolesville. The date set as a deadline to perform this annual inspection is one year after the date the as-built drawings were first certified to the Town of RntPC~,;ttP C. Sediment shall be removed if it is impeding the water flow. Page 13 o f 1=~ V. General Maintenance: A. Mowing of Bio Retention areas according to the season. Maximum grass height of 4-6 inches. B. In case the ownership of the Impoundment transfers, the current owner shall within thirty (;0) days of transfer of ownership, notify the Town of Rolesville Engineering Department, Stormwater Management Division of such ownership transfer. C. This property and impoundment is also subject to the Stormwater Operation and Maintenance Manual and budget filed relative to this project. D. All trash and debris removal should occur as needed. Bioretention areas should be inspected for trash and debris monthly. I, I~-o~?~~ Qp~G.vt c e~ ,for _ ~ `'cat Li~~.2~1T Qt~~,~o ~tyt~~~r4 Q ~~( hereby acknowledge that I, or my assigns, are the financially responsible party for maintenance of these water quality Bio Retention areas. I or my assigns will perform the maintenance as outlined in this document. •,~'~ r Signature: ~L(, ~`~"~'t- ~Q Date: 1. ~I/ d Company/Partnership: C~~1 f ~v'~ , I> ~`vfz` ~ ~ .. Q ~,~t~, a Notary Public for the State of (~ ~ ,County of __~ ~ ~Q~ , do hereby certify that ~ ~b r.~ Q o~ d„ ~. personally appeared before me this ~ Qday of ~V,, , 200!1, and acknowledge the due execution of the foregoing instrument. Witness my hand and official seal, (SEAL) KELLY E. PIERCE NOTARY PUBLIC WAKf~ COUNTY, N.C. My Commissbn Expires 4-1$-2i)12. Notary My commission expires y ~ ( ' ~ 0 ~ oL Page 1 ~ o f l -~ ~.xp o'1 - 0 0 8 ~ v ~ Aiken & Yelle Associates, PA AYES Professional Engineers & Land Surveyors 3755 Benson Drive Raleigh, North Carolina 27609 Phone: (919) 877-9992 Fax: (919) 877-9979 August 7, 2007 NC Division of Water Quality 401 Oversight and Express Permits Unit Attn: Express Review Staff 2321 Crabtree Blvd Suite 250 Raleigh, NC 27604-2260 Re: Cedar Ridge Subdivision PCN Submittal Wake County, North Carolina Dear Staff: We have modified the Cedar Ridge Drawings in the following manner: 1 • We have revised Grassed Swale 1 to Bioretention Area 12 per our conversations with Annette Lucas on August 6`h and 7`i'. We have included in this submittal the bioretention worksheet with calculations and a revised maintenance manual. 2. We have modified the detail to show that the dissipation pads are not to be included within surface area of the bioretention cell. Thank you. If you have any questions regarding the above information please call us at 877-9992 Sincerely Andrew Klinksiek Associate Engineer Aiken & Yelle Associates, PA ~ "'' Vf ~ r ~il~ ~ 2aq~ ~, nN~ ~,~„m,,r};,~rca~gp,,,~ch BIORETENTION AREA TOTAL AREA (sq ft) IMP (sq ft) la Rv WQV (cu ft) 1 82,900 17,500 0.21 0.240 1,658 2 90,300 34,000 0.38 0.389 2,926 3 52, 700 9, 200 0.17 0.207 910 4 72,100 26,100 0.36 0.376 2, 258 5 82,800 21,800 0.26 0.287 1,980 6 27,900 9,600 0.34 0.360 836 7 33,100 22,600 0.68 0.665 1,833 8 75,800 21,200 0.41 0.420 2,656 9 54, 900 24, 000 0.44 0.443 2, 029 10 18, 700 5, 400 0.29 0.310 483 11 65, 800 22,100 0.34 0.353 1, 935 12 52,600 13,500 0.26 0.281 1,232 Permit No. ~XP L ~ ' UO~ ~ Y~ (to be provided by DWQ) State of North Carolina Department of Environment and Natural Resources Division of Water Quality STORMWATER MANAGEMENT PERMIT APPLICATION FORM BIOKETENTION BASIN SUPPLEMENT This form may be photocopied for erne as an original. DWO stormwater Management Plan Review A complete stormwater management plan submittal includes a stormwater management permit application, a bioretention area supplement for each proposed system, sealed design calculations, a detailed soils report and 2 sets of plans and specifications showing all stormwater conveyances and system details. I. PROJECT INFORMATION Project Name : (~ ~ L(tin~' ~ i is ~ e Contact Person: _~c.~~l G~ ~e[I~` Phone Number: For projects with multiple basins, specify which basin this worksheet applies to: ~ ~Z- (must match the DA # on the application & plans) II. DESIGN INFORMATION Attach supporting calculations/documentation. Provide a written soils report based on actual field investigations conducted by a qualified individual. The soils report should include informational references to the County soils maps when available. All elevations shall be in feet mean sea level (fmsl). Soils Report Summary In-Situ Soil Type In-Situ Soil Infiltration Rate SHWT Elevation Planting Soil Texture Planting Soil Infiltration Rate Basin Design Parameters Draia:age rurea Impervious Area Design Storm Design Volume Inlet Velocity Drawdown Time Basin Elevations Temporary Pool Elevation Planting Elevation Bottom Elevation Basin Dimensions Basin Size Basin Volume Provided SWU-]OS 4.07 l~ ~ ~' ~ in./hr. (the most restrictive soil layer) ~ ~ 'I` ft. (Seasonal High Water Table elevation) t~Cam ~G"flLl (mzrst be a sturdy loam, lomny sand, or loam texture) Z ~ L in./hr. - ~ q. ~u .-Site ciilu u~wuc uruutu~c tG iice VuSciij ~ 3t ~ G sq.ft. (on-site and off-site drainage to the basin) 1 inch (1.5 inch event for SA waters, 1 inch event for others) ~Z~2 _ c.f. (storage voltnne required) 1. ~ (~,,_ fps ~{ t `~ hours 1 Ali [~ ~~yy ~~~~f+=~gql~lt! -~~~ln.,'l+i''~!~ t;'t~.jF~~.i T119Y9 ~r1::1°Y'IVQ ~;i~V ,ri~i~~f''',;t'fA,*f»7'.,'. R~l!t~rli `z~ Z' ~ fmsl (elevation of the bypass/oartlet structcn-e) ~ ~ I i G fmsl (elevation of the grocuzd surface bottom) ~~ cl ~ u fmsl (elevation of the bottom of the planting media) ~U~~ ft. x ~', ft. = rZ~G sq. ft. (suzfcrce area nt basin bottan) I ~ ~ ~ c.f. Page I of 4 Basin Plantings ,~ d Number of plantings required d ~ ~ Stems (400 sterns per acre of bioreterztion area is required at a minimaun Total No. of plantings provided ~,}~,} t' ~k -Trees hr' + Shrubs S+t I (nt least 1 tree for every 3 shrubs) This system (check one) does does not incorporate the use of an under-drain. (Under-drains are not allowed for those projects that drain to class SA waters.) III. REQUIRED ITEMS CHECKLIST The following checklist outlines design requirements per the North Carolina Stormwater Best Management Practice Manual and Administrative Code Section: 15A NCAC 2H .1000. These requirements are subject to change in accordance with the manual and rules. Initial in the space provided to indicate that the following design requirements have been met and supporting documentation is attached. If a requirement has not been met, attach written justification. An incomplete submittal package will result in a request for additional information and will substantially delay final review and approval of the project. Applicant's Initials ~_ a. System is located 50 feet from class SA waters and 30 feet from other surface waters. _ b. No vertical sand bed is proposed. ~ ~~ c. The bioretention area is at least 15 feet wide by 40 feet long. Stier 21ra~tr~tQ t'frR 1vi..0~N~13h1P Y11l~~~; ~~Q,~ d. A grass buffer strip and sheet flow conditions are provided at the inlet~~ ~~L~ Z ~ ~~ 7 ~~_ e. Seasonal High Water table depth is at least 2 feet below the planting elevation surface. ~_ f. Ponding depth of 6-12" is provided. g. In-situ soils have a minimum hydraulic conductivity of 0.52 inches per hour. ~~ l~ h. An in-depth soils report is provided. (report should include soil t es boring loR, , .ten suitability for placement of the control system, seasonal high water table, infiltration ate, etc.) ~~ i. The planting soil has a minimum hydraulic conductivity of 0.52 inches per hour. The type and placement specifications of the planting media are noted on the plans. ~-~~ j. The planting soil meets minimum soil specifications per the latest version of the NCDENR Stormwater Best Management Practices Manual, including a low phosphonis content to promote phosphorus removal. (P-Index of 20 to 40 is optimal.) Include a soils test, indicating ~~~~ P-Index, from a certified lab for those projects draining to Nutrient Sensitive Waters. --~_.__ k. System is designed to draw down the design storage volume to the proposed bottom elevation under seasonal high water conditions within 24 hours. Draw down calculations are attached. - ~1~~_ 1. A detailed planting plan, prepared by a qualified individual, is provided on the plans. This lan shall indicate a variety of suitable species, location, s acing, ~ p requirements, installation procedures, constniction schedule, eocl preparation, fertilizer SWU-108 4.07 Page ? of 4 -_• .°• ~ _ m. Type of mulch layer and depth is specified on the plans. ~~`~ n. Plan and section details for the bioretention area are provided. (including dimensions and elevations) ~~~ o. Plan details for the inlet and outlet structures are provided. (including dimensions and elevations) ~~ p. All side slopes stabilized with vegetated cover are no steeper than 3:1 (H:V). =~_ q. A benchmark is provided to determine the sediment accumulation in the basin area. ~_ r. Vegetated filter is provided for overflow and detail is shown on plans (Required minimum ~.,~~~ length is 50 feet for SA waters, 30 feet for other waters). `-~_ s. Runoff in excess of the desi n volume b g ypasses off-line systems (bypass detail provided). ~_ t. Plans ensure that the installed system will meet design specifications (constructed or restored) upon initial operation once the project is complete and the entire drainage area is stabilized. IV. BIORETENTION BASIN OPERATION AND MAINTENANCE AGREEMENT Records of maintenance items to include dates, inspector's name, type of maintenance, etc. shall be kept and made available to Division staff upon request. Maintenance activities shall be performed as follows: 1. Inspect the bioretention area system for soil and mulch erosion, vegetated cover, and general condition after every significant runoff producing rainfall event and at ]east monthly. Remove trash as needed. 2. Repair eroded areas immediately, re-seed, re-plant, and re-mulch as necessary to maintain good vegetative and mulch cover. Remove accumulated sediment as needed to maintain good infiltration. When the filtering capacity diminishes substantially (e.g., when water ponds on the surface for more than 24 hours), the top few inches of material must be removed and replaced with fresh planting soil material. Regardless of infiltration capacity, accumulated sediment in the bioretention basin shall be removed when the depth is reduced to 75% of the original design depth. ,The system shall be restored to the original design depth without over-excavating. Over-excavating may cause tnc required water table separation to be reduced and may compromise the ability of the system to perform as designed. Removed sediment shall be disposed of in an appropriate manner and shall not be handled in a manner that will adversely impact water quality (i.e. stockpiling near a stormwater treatment device or stream, etc.). 4. Replace, or add additional mulch as needed. Removal of the old mulch layer before applying the new layer is recommended every 2 to 3 years. 5. Pnme trees and shrubs and remove debris on an annual basis. Grassed vegetation should not exceed 6 inches in height. 6. Treat all diseased trees and shrubs whenever needed. Remove and replace all dead and diseased vegetation considered beyond treatment every 6 months. 7. Replace support stakes yearly (in the spring). Replace deficient stakes or wires whenever needed SWU-108 4.07 Pace 3 of ~ 8. Soil testing shall be conducted annually to determine pH and any accumulation of toxins in the planting media. Lime or other alkaline substances shall be applied as recommended per the soil test and toxic soils shall be removed, disposed of properly and replaced with new planting media. 9. All components of the bioretention area system shall be maintained in good working order. 10. If the Division determines that the system is failing, the system will immediately be repaired to original design specifications. If the system cannot be repaired to perform its design function, other stormwater control devices as allowed by NCAC 2H .1000 must be designed, approved and constructed. I acknowledge and agree by my signature below that I am responsible for the performance of the ten maintenance procedures listed above. I agree to notify DWQ of any problems with the system or prior to any changes to the system or responsible party. Print name: _~c~ber+ Pol~nco Title: ~c'eS`~G~e~t Address:_gS09 1~fbnc,~,~- t7ri~e -2al~,t~h Nc, 2~1~12 V Phone: ~~ ~ ~p~ q 1~ 3 3 ~, Signature:' ~( ,,,rte !~/~~~ ~~ i Date: Note: The ega]]y responsible party should not be a homeowners association unless more than 50% of the lots have been sold and a resident of the subdivision has been named the president. h ___~ . P ~ Q~`C~Q~. , a Notary Public for the State of ~~~~'~~ o~C'd,~tRCJ4. County of ~ ~ ~~P ~ , do hereby certify that _ ~ ph~n~ ~ ~~~ ~~ n personally appeared before me this ~_day of ¢D~ / ,and acknowledge the due execution of the forgoing bioretention basin maintenance requirements. Witness my hand and official seal, KELLY E. PIERCE NOTARY PUBLIC WAKE COUNTY, N.C. My C®mmission Expires 4-18-2072. SEAL My commission expires ~ ~ ~ ~b` SwU- 108 4.07 Page 4 of 4 BI012 Date: OS-07-2007 Project: CEDAR RIDGE Description: Bioretentin Area 12 Hw#38 - Inlet vel ocity Side slope (H/lv)ha3nel Flow - Trapezoidal Cross Section J°~ ---------------------- Discharge Ave. Depth Area (cfs) vel. (ft) (sq ft) ------ --------- Top Froude width -------------- Slope n ------- Bottom (ft/s) No. (ft) (ft/ value ft) width ---------------- -------- - (ft) -----3_12- 1.46 0.31 2.14 ------------ ---- --- 7.85 0.49 ---------------- ------------- .00500 .0300 ------------- ------- 6.00 ------- Page 1 Bioretention Area 12 RECARGA 2.X Date: 07-Aug-2007 13:38:25 Output File: Bioretention Area 12.txt Number of time steps= 289 CPU elapsed time (s)= 0 INPUT TERMS %Impervious= 26 Pervious CN= 74 Facility Area (sf)= 1250 Trib. Area (AC)= 1.21 RATIOimp2rg= 10.9632 RATloperv2rg= 31.2029 LAYER DEPTH (in) Ksat (in/hr) TEXTURE Depression 12 --- --- Root Zone 24 4.14 1 storage 4 10.00 1 Native --- 1.28 3 Init. Cond.: suction head (in)= -39 Max. underdrain flow (in/h r)= 0. 008 underdrain diam (in)= 4.003 WATER BALANCE TERMS volume(ac-ft) Depth (in) %of Inflow Inflow 0.10 1.01 100.00 Runoff 0.01 0.06 6.33 Recharge 0.05 0.50 49.78 Evaporation 0.00 0.01 0.54 underdrain 0.05 0.50 49.37 Storage -0.01 -0.06 -6.02 Infiltrated 0.10 Precip. 2.37 Imp. Inflow 0.05 2.23 48.50 Perv.Inflow 0.03 0.54 33.18 Basin Stayon(in) -42.25 Total Stayon(in) 1.81 Mass Balance Checks: vinsoil=input-roff-dvh vinsoil (ac-ft)= 9.732047e- 002 vinf difference (%)_ -0.0 vrechargl=inf-et-dsws vrechar~l (ac-ft)= 5.171609e- 002 vrech difference (%)_ -0.0 dvsoil=inf-rech-et dvsoil= 4.503863e-002 dvsfce (ac-ft)= O.000OOOe+000 dvs2=input-roff-inf dvs2 (ac-ft)= 4.608371e-017 PLANT SURVIVABILITY TERMS total time ponded (h)= 7.5 max time ponded (h)= 7.5 total time Rz saturated (h)= 7.8 total time Rz at wilting point (h)= 0.0 total time Tz saturated (h)= 8.8 max time Rz saturated (h)= 7.8 max time Rz at wilting point (h)= 0.0 max time Tz saturated (h)= 8.3 near saturated times for simulation = 2 19.0 7.8 20.3 0.0 wilting point times for simulation= 0 0.0 0.0 ponded times for simulation= 1 19.0 7.5 overflow times for simulation= 0 Page 1