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Home My WebLink AboutSW8940217_HISTORICAL FILE_19940316STORMWATER DIVISION CODING SHEET POST -CONSTRUCTION PERMITS PERMIT NO. SW8 Cj402m DOC TYPE ❑ CURRENT PERMIT ❑ APPROVED PLANS HISTORICAL FILE ❑ COMPLIANCE EVALUATION INSPECTION DOC DATE Iqq y o 31 '-p YYYYMMDD State of North Carolina Department of Environment, Health, and Natur esources 'n on Regional Office James B. Hunt, Jr., Governor DIVI OF NMENTAL MANAGE Bob Jamieson Jonathan B. Howes, Secretary Regional Manager M • h 16, 1994 Mr. Stephen Miller Gulfstream DevelopmR t Group, In 801 Paoli Court Wilmington, North Caro' 28409 bject: ERTIFICATION OF COMPLIANCE with Stormwater Regulations Stormwater Project No. SW8 940217 The Keys of Kure Beach New Hanover County Dear Mi. er: This Ce ication is pursu to the application for The Keys of Kure Beach received on February 21, 1"s, nal inform on received on March 10, 1994. Based on our review of the project plans and we It determined that the The Keys of Kure Beach stormwater control system complies with the Stormwater gulations set forth in Title 15A NCAC 2H.1003(i). The runoff will be treated in a detention pond to achieve 90 % reduction in Total Suspended Solids. Any modification f the plans submitted to and approved by this Office or further development of this site regardless ofhe fact that the modification may be less than 1 acre, will require an additional Stormwater SubmittaUpodification and approval prior to initiation of construction. Modifications include but are not limited J, project name changes, transfer of ownership,. redesign of built -upon surfaces, addition of built-u n surfaces, redesign or further subdivision of the project area. This Ce ication shall be effective from the date of issuance until rescinded. The project shall be coin tnrcted and maintained in accordance with the plans and specifications approved by the Wilmington gional Office. This Certification does not supersede any other permit or approval. The developer is sponsible for obtaining any and all permits and approvals necessary for the development of this proj t. This could include the Division of Coastal Management under CAMA requirements, the Division o vironmental Management under Wetland 401 Water Quality Certification and/or a Dredge and Fill P t and/or a Sewer Extension/Collection Permit, U.S. Army Corps of Engineers 404 Wetland Permit, DES Stormwater Permit if disturbing five acres or more, local County or Town Agency permits under their local ordinances, or others that may be required. 127 Cardinal Drive Extension, Wilmington, N.C. 28405-3845 • Telephone 910-395-3900 • Pax 910-350-2004 An Equal Opportunity A15ruutive Action Employer I Mr. Miller March 16, 1994 Stormwater Project No. SW8 940217 A professional engineer must certify that the stormwater system has been installed in accordance with the approved plans and specifications upon completion of construction. The attached certification should be received by this Office within 30 days of completion of construction. '11 If you have any questions concerning this matter, please call Ms. Linda Lewis or me at (910) 395- Sincerely, ave Adkins Water Quality Supervisor DA/arl: S:\WQS\STORMWAT\CERTIFIC\940217.MAR cc: Mr. Joseph S. Hill Mr. Sky Conklin, New Hanover County Inspections Bradley Bennett Linda Lewis Wilmington Regional Office Central Files DIVISION OF ENVIRONMENTAL MANAGEMENT PROJECT DATA Project Name: Project Number: Location: Applicant: Mailing Address: Submittal Date: Water Body Receiving Stormwater Runoff: Classification of Water Body: If Class SA, chloride sampling results: Pond Depth: Permanent Pool Elevation: Total Impervious Surfaces Allowed: Offsite Area entering Pond: Green Area entering Pond: Required Surface Area: Provided Surface Area: Provided Storage Volume: Temporary Storage Elevation: Controlling Orifice Type/Diameter: The Keys of Kure Beach SW8 940217 New Hanover County Mr. Stephen Miller Gulfstream Development Group, Inc. 801 Paoli Court Wilmington, North Carolina 28409 February 21, 1994 UT Cape Fear River "SC" U11 4.0 feet 14.4 MSL 284,725 square feet N/A 397,425 square feet 24,824 square feet 58,600 square feet 29,768 cubic feet 14.9 MSL 2.5" pipe 1. 2. 3. 4. 5. 6. WET DETENTION POND EVALUATION Yes No The design storage is for the runoff from all impervious surfaces resulting from 1-inch of rainfall and is located above the permanent pool. Yes No The permanent pool is designed for 90% total suspended solid (TSS) removal. Therefore, no vegetative filter is required. Yes No The runoff completely draws down to the permanent pool in 5 days, but not less than 2 days. Yes No The mean depth of the permanent pool is a minimum of 3 feet. Yes No The inlet structure is designed to minimize turbulence and short circuiting. Yes No An appropriate operation and maintenance plan has been provided for the system. 7. Yes No THIS PROJECT MEETS THE STORMWATER CONTROL REQUIREMENTS OF 15A NCAC 2H.1003 (g), (i), (k), and (1) (For Yes, 1 through 7 must all be highlighted Yes.) Brief Explanation: This detention pond is designed to remove 90% total suspended solids without the aide of a vegetative filter. DIVISION OF ENVIRONMENTAL MANAGEMENT SIGN -OFF Wilmington Regional Office Date Individual Evaluating Form/Plans Date RE ' nal Water Quality Supervisor cc: Applicant/Bradley Bennett/arl/WiRO/CF DIVISI4` 'OF ENVIRONMENTAL MANAGENV NT DENSITY ENGINEERED—. PROJECT DATA Project Name The Keys of Kure Beach Location (County, Township/Municipality, Address, State Road) Kure Beach Owner's Name Gulf Stream Development Group, Incorporated Mailing Address 801 Paoli Court, Wilmington, N.C. 28409 Phone Number (919)458-3979 Submittal Date Jan. 25, 1994 Brief Description (include map and appropriate drawings) Project consists of 100 townhouses on 15.66 acres with wet detention pond for stormwater management. Name of Water Body Receiving Stormwater Runoff U: T. Cape Fear River Classification of Water Body SC If SA waters, engineered system, and distance is <0.5 miles, attach report of chloride sampling results mg/1 State/Federal Permits/Approvals Required (Check appropriate blanks) CAMA Major Sedimentation/Erosion Control X 404 Permit DEM/DHS Sewage Disposal Other (Specify) CALCULATION OF BUILT UPON AREA Built upon area means that portion of a development that is covered by impervious or partially pervious cover including buildings, pavement, recreation facilities, gravel, etc., but not including wood decking. If the project includes areas draining to differentwater classifications, please note them separately below. Subwatershed Subwatershed Classification' SC Built upon area 6: 54 AC Total Project Area 15.66 AC % Built upon Area 41.87 Allowable B/U Area --- 70-7 Is the Project B/U;Area' S',the Allowable B/U Area? No (If no, an engineers % Built upon area ='(liuilt upon area / total project area) * 100 Built upon area limits for projects to meet density: SA waters — 25%, Other —30% STORMWATER COLLECTION SYSTEM Describe how the runoff will be treated runoff will be collected and e.nrad in a wet detention pond is Office use only TO�,'wlPVIT lu)ltUL ��l5�ji. IIJnU� FEB 2 1 1994 U D E M nT 46tv$ e46Z1%__ BUFFER AREA Is the built upon area at least 30 feet from mean high water of all surface waters? Yes If no, please provide a description (Note: Only boat ramps, public roads, public bridges, and walkways to water related facilities are allowed within 30 feet of the mean high water line if the project is intended to meet stormwater control requirements through density limits.) DEED RESTRICTIONS AND PROTECTIVE COVENANTS By my signature below, I certify that the recorded deed restrictions and protective covenants for this project shall limit the allowable built -upon area 001XY& to 284,725 square feet inclusive of right-of-way, structures, pavement, walkways or patios of brick, stone, or slate, not including wood decking, state that the covenants will be binding on all parties and persons claiming under them, that they will run with the land, and that benefits may be enforced by the State of North Carolina, therefore, the covenant cannot be changed or deleted without consent of the State. CERTIFICATION I, Stephen Miller , certify that the information included on this submittal form is correct, that the project will be constructed in conformance with this information, and that to the best of my knowledge, the proposed project complies with the requirements of 15 NCAC 2H.1003 (b). I authorize the below named person or firm to submit stormwater plans on my behalf, and agree to abide by the deed restriction stateffient above. Owner's Signature Date Provide authorized person or firm name and address below: Hr. _J'o�ePh 1-h ll, PE I(oo2 42 LYpUw Or. UiiIrn'ncJiOn A)G Z94-Ul I, 15, CAJJn-� ,allotary Public for the State of �org CiAmo�,Jn County of t.) Iha,.,. , do hereby certify that S4ol,e) lam: IlLi personally appeared before me this q day of fc/n sn 19 and acknowledyh��Trdue execution of the ifegoing instrument. Witness my hand and official seal, ,��Sp B. ry+'4'�.,�� Q l,, My commission expires X, zA f ' rr"" 1 A ci DIVISION OF ENVIRONMENTAL MANAGEMENT TE Regional Office Y(o MA2 94- Date, - NI /agyc 14 r�J�W Date cc: Applicani]WiRO/Bradley Bennett/Central Files 4 FEB 21 1994 FINANCIAL RESPONSIBILITY/OWNERSHIP FORM SEDIMENTATION POLLUTION CONTROL ACT LAND -No person may initiate any land -disturbing activity on one or more contiguous acres as covered by the7 Act before this form and an acceptable erosion and sedimentation control plan have been completed and approved by the Land Quality Section, N.C. Department of Environment, Health, and Natural Resources. (Please type or print and, if question is not applicable, place N/A in the blank.) Part A. 1. Project Name The Keys of Kure Beach 2. Location of land -disturbing activity: County New Hanover City or Township Kure Beach and Highway / Street Kure Village Way 3. Approximate date land -disturbing activity will be commenced: February 28 4. Purpose of development (residential, commercial, industrial, etc.) : Residential 5. Total acreage disturbed or uncovered (including oft -site borrow and waste areas) 15.66 AC 6. Amount of fee enclosed $ 330.00 7. Has an erosion and sedimentation control plan been filed ? Yes X No 8. Person to contact should sediment control issues arise during land -disturbing activity. Name Stephen Miller Telephone (419)458-3979 9. Landowner (s) of Record ( Use blank page to list additional owners.): Gulf Stream Development Group- Inc, - Name (s) 801 Paoli Court Current Mailing Address Wilmington N.C. 28409 City State Zip Current Street Address City State Zip 1625 Pa eNo. 1383 , 10. Recorded in Deed Book No. 9 p fl �p Part B. N � �."�°��R 1. Person (s) or firms (s) who are financially responsible forthis land -disturbing activity (Use the blank page to list additional persons or firms): Steohen Miller Name of Person (s)or Finn (s) 801 Paoli Court Mailing Address Wilmington N C 28409 City State' - Zip . Telephone (919)458-3979 FEB 2 1 1994 Street Address ,n1 , ,y(N0: c�% City State Zip Telephone 2. (a) If the Financially Responsible Party is a Corporation give name and street address of the Registered Agent. Bob Weinbach Name 801 Paoli Court Mailing Address Wilmington NC 28409 City State Zip (919)458-3979 Telephone Street Address City Telephone State Zip (b) If the Financially Responsible Party is a Partnership give the name and street address of each General Partner ( Use blank page to list additional oartners.): Name Mailing Address Street Address City State Zip City State Zip Telephone Telephone The above information is true and correct to the best of my knowledge and belief and was provided by me under oath. ( This form must be signed by the financially responsible person if an individual or his attorney -in - fact or if not an individual by an officer, director, partner, or registered agent with authority to execute instru- ments for the finanacially responsible person ). I agree to provide corrected information should there be any change in the information provided herein. Bob Weinbach Type or print name Signa ure President Title or Authority zly�9s� Date I, a Notary Public of the County of 44-1 do ' State of North Carolina, hereby certify that /fie 6 e". 't -ll appeared'personally before me this day and being duly sworn acknowledged that the above form was exe- cuted by,t�m,,,C t�, ��FQC��,`\`.•••••...�, tpess my hand and notarial seal, this y of fe��ab �5 19 5 -= a� • -- Z� "•' c$ei Notary My commission expires JOSEPH S. HILL, JPL AND ASSOCIATES CONSULTING ENGINEERS and PLANNERS MAI II NC ADDRESS, POSE OFFICE ROx 5592SEA1 pn�GCUy !.}NGTON. NC 2-0MIN155 " IM2 HARBOUR DRIVE MI INGWN, NORFN CAROUNA I EPIIONE910.7"-15" March 9, 1994 Ms. Linda Lewis N. C. D. E. H. N. R. 127 Cardinal Drive Extension Wilmington, North Carolina 28405-3845 Subject: Submittal of Additional Information Stormwater Project No. SW8 940217 The Keys of Kure Beach New Hanover County Dear Ms. Lewis: UI Lti 6 Ls � U L� bu MAR 1 0 1994 R IEE IV] T 7r Iffifflffl__91V291 MAR 1 a 1994 Enclosed are three (3) sets of revised plans and calculations for the Stormwater Plan for The Keys of Kure Beach. The following items have been addressed and are included in this submittal: The name, address, and telephone number of the responsible party are typed on the Operation and Maintenance Plan. The 0&M Plan is notarized. 2. The detention pond surface area provided is based on the permanent pool elevation of 14,4'. The calculations show the surface area provided both at the permanent pool elevation and at the storage pool elevation. The total volume of the pond at the storage contour (14.9') is shown in the calculations. 3. The orifice invert elevation is shown to be 14.4'. 4. As we discussed, Club Drive is an existing public street with existing storm drainage facilities. All project runoff beginning at the back of the curb along Club Drive will be routed to the stormwater pond by diversion through swales and storm sewer piping as shown on the plans. 5. The actual building footprint is 5,640 square feet. With an allowance of 160 square feet for sidewalks, the total built —upon area for each building will be 5,800 square feet. The calculations have been corrected to show a building area of 5,800 square feet (building detail enclosed). Ms. Linda Lewis The Keys of Kure Beach March 9, 1994 Page 2 6. A note has been added to the erosion control notes to require removal of sediment from the sediment storage zone of the pond. Please review this information as soon as possible. Please do not hesitate to contact me if you have any questions. Sincerely, JOSEPH S. •HII.LaL,o JR. and ASSOCIATES QI�f"'^ JSH/pat Josep S. Hill, Jr., P.E. enclosures THE KEYS OF KURE BEACH Stormwater Detention Pond Calculations Revised 3/9/94 Stormwater runoff from the project will be retained in wet detention pond. This pond will store the runoff generated by 1 inch of rainfall. The stored runoff will be discharged over a period of 4.4 days. The pond area required to remove 90% of total suspended solids was calculated using the SA/DA Percentage Chart (see chart) for North Carolina coastal regions. ff Calculations Impervious Surfaces: 25 — Buildings @ 5,800 Sq. Ft. Each = 145,000 Sq. Ft. Streets and Driveways = 130,950 Sq. Ft. Pool (including parking and walks) = 8,775 Sq. Ft. Total Impervious Area = 284,725 Sq. Ft. = 6.54 AC. Pervious Surfaces (Grassed, Landscaped areas) = 397,425 Ac. 9.12 Ac. fk� L) Li V MAR 1 'C 1994 DEm �UZ17 284,725 x 0.083' Runoff = 23,632 CF 397,425 x 0.083' Runoff x 0.2 (R.O. Coefficient) = 6,597 CF Total Runoff (1" Rainfall) = 30,229 CF = 226,113 Gallons Pond Surface area @ Storage Pool Elev. of 14.9' = 62,000 Sq. Ft. Pond Surface area @ Permanent Pool Elev. of 14.4' = 59,050 Sq. Ft. Average Pond Surface Area = 60,525 Sq. Ft. I The Keys of Kure Beach Stormwater Calculations Page 2 Pond Storage Volume = 0.5' depth x 60,525 Sq. Ft. = 30,262 CF = 226,360 Gallons Solids Settling Area Calculations Total watershed area = 15.66 Ac. Impervious % = 6.54 Ac. o- 15.66 Ac. = 41.8% Basin Mean Depth = 4.0' SA/DA % required for 90% solids removal (see chart) = 3.6% 3.6% x 15.66 Ac. = 0.56 Ac. Basin Surface area @ Permanent Pool elev. of 14.4' = 1.36 Ac. Basin is therefore adequate for 90% TSS removal. S. d ,,.,.... VA ,_.. O S� SEAL r� 8982 ✓ ... 'O GIN .; KEYSTWTR 3l9 /V 20% 30% 40% 50 % 60% 70% 80% 90% 100% THE KEYS SA/DA - 85%.TSS REMOVAL WITH 30' VEGETATIVE FILTER 3.OFT 3.5FT 4.OFT 4.5FT 5.OFT 5.5FT 6.OFT 6.5FT 7.OFT 7.5FT .9 .8 .7 .6 .5 1.7 1.3 1.2 1.1 1,0 .9 .8 .7 ".6 _ .5 . 2.5 2.2 1.9 .1.8 1.6 1.5 1.3 1.2 .1.0 .9 3.4 3.0 2.6 2.4 2.1 1.9 1.6 1.4 1.1 1.0 . 4.2 3.7 3.3 3.0 2..7 2.4 2.1 1.8 1.5 1.3 5.0 4.5 3.8 3.5 3.2 2.9 2.6 2.3 2.0 1.6 6.0 5.2 4.5 4.1- 3.7 3.1 2.9 2.5 2.1 1.8 6.8 6.0 5.2 4.7 4.2 3.7 3.2 2.7 2.2 2.0 7.5 6.5 5.8 5.3 4.8 4.3 3.8 3.3 2.8 1.3 8.2 7.4 6.8 6.2 5.6 5.0 4.4 3.8 3.2 2.6 SA/DA - > 90% TSS REMOVAL WET DETENTION WITHOUT VEGETATIVE FILTER IMPERA 3.OFT 3.5FT14.OFT14.5FT 10% 1.3 1.0 -8- .7 20% 2.4 2.0 1.8 1.7 30% 3.5 3.0 2.7 2.5 4�E7 40% 4.5 4.0 3.5 36.3.9 3.1 50% 5.6 5.0 4.3 60% 7.0 6.0 5.3 4.8 70% 8.1 7.0 6.0 5.5 80% 9.4 8.0 7.0 6.4 90% 10.7 9:0 7.9 7.2 100% 12.0 10.0 8.8 8.1 OFT 5.5FT 6.OFT 6.5FT .6 .5 .4 .3 1.5 1.4 1.2 1.0 2.2 1.9 1.6 1.3 2.8 2.5 2.1 1.8 3.5 3.1 2.7 2.3 4.3 3.9 3.4 2.9 5.0 4.5 3:9 3.4 5.7 5.2 4.6 4.0 6.5 5.9 5.2 4.6 7.3 6.6 5.8 5.1 .9 .6 1.1 .8 1.4 1.1 1.9 1.5 2.4 1.9 2.9 2.3 3.4 2.8 3.9 3.3 4.3 3.6 ORIFICE DISCHARGE RATE CALCULATIONS Use 2 1" diameter orifice for outlet. Calculate average discharge rate and time to lower orifice head from 0.50' to 0.45': 0.05' pond height x 60,984 Sq. ft. pond area (@ mean storage elev.) x 7.48 gal/ft3 = 22,808 Gallon Storage Average head on orifice from 0.50' to 0.45' = 0.475' Average discharge rate @ 0.475' head: Q(GPM) = (449)c A 2gh Q(GPM) = Volume discharged in gallons per minute c = discharge coefficient = 0.6 A = orifice area in square feet g = gravity = 32.2 h = head above center of orifice Q(GPM) = (449)(.6)(.0341) (2)(32.2)(0.475) Q = 50.8 GPM Time required to lower pond 0.1' @ 0.475' average head: T = 22,808 Gal. - 50.8 GPM = 449 minutes 50.8 minutes vs 449 minutes plotted on curve (See Discharge Curve). Discharge rate and time to lower head from 0.45' to 0.40' Q = 48.1 GPM T = 22,808 Gal. r 48.1' GPM = 474 minutes 48.1 GPM vs 923 minutes plotted on curve. Keys —St 4 Discharge rate and time to lower head from 0.40' to 0.35': Q = 45.1 GPM T = 22,808 Gal. o--45.1 GPM = 506 minutes 45.1 GPM vs 1429 minutes plotted on curve. Discharge rate and time to lower head from 0.35''to 0.30': Q = 42.0 GPM T = 22,808 Gal. o- 42.0 GPM = 543 minutes 42.0 GPM vs 1972 minutes plotted on curve. Discharge rate and time to lower head from 0.30' to 0.25': Q = 38.7 GPM T = 22,808 Gal. r 38.7 GPM = 590 minutes 38.7' GPM vs 2,562 minutes plotted on curve. Discharge rate and time to lower head from 0.25' to 0.20': Q = 35.0 GPM T = 22,808 Gal, o- 35.0 GPM = 652 minutes 35.0 GPM vs 3,214 minutes plotted on curve. Discharge rate and time to lower head from 0.20' to 0.15': Q = 30.8 GPM T = 22,808 Gal. = 30.8 GPM = 740 minutes 30.8 GPM vs 3,954 minutes plotted on curve. Discharge rate and time to lower head from 0.15' to 0.10': Q = 26.1 GPM T = 22,808 Gal. o- 26.1 GPM '= 873 minutes 26.1 GPM vs 4,827 minutes plotted on curve. Keys —St 5 Discharge rate and time to lower head from 0.10' to 0.05': i Q = 20.2 GPM T = 22,808 Gal. o- 20:2 GPM = 1,129 minutes 20.2 GPM vs 5,956 minutes plotted on curve. Discharge rate and time to lower head from 0.05' to 0.00': Q = 11.7 GPM T = 22,808 Gal. !- 11.7 GPM =.1949 minutes 11.7 GPM vs 7905 minutes plotted on curve. The outlet structure will discharge the total calculated runoff volume of 226,113 gallons in approximately 4.4 days (See Orifice Discharge Curve). Keys —St 6 70 60 50 40 H 30 20 THE KEYS 57-0RblV1AT`R P 0IVI) ORIFICE DISCHARGE S0.s r-pm/44q MIN.' 48.IGPM/g23 MIN, 451 GPr?/ 41.q MIN VV- Y 38.7 GPM 562 lilt(• �� 2.5"o ORIFICE WILL DISCHARGE CALCULRTED 14-MIi`1• RUWOP'EV06vl+'rE OF �35.0GPAl/ 226�II3 GALS. fh" N,P141373 MI -} 4 DAYS �361.PG 6.1 GPAV .427 111N. �2 20,2CYM/S,956 MIN. 11.7GPM/7g05 MIN. DAY I DAYI DAY? I UAY DAY 5 71,700 GALS, 5B 500 GALS, 4R 3DD rrALS :/ILS. 26,400 GALS. O ?00 20:00 30'00. 1000 5000 6'0 ,00 7P0,0. 860 9000 �q 0 THE KEYS OF KURE BEACH STORMWATER MANAGEMENjPL January 1994 Sf1V'w°-%TER /u �� L�uu� If FEB 2 1 1994 OT # 5 D- �4 zn S.f�kl_� Ey SEAL rsj 8932 iOJ GINE�J S 1102 019V Prepared By: JOSEPH S. HILL, JR. and ASSOCIATES CONSULTING ENGINEERS and PLANNERS 1602 Harbour Drive Wilmington, N.C. 28401 (919)799-1544 u 0 THE KEYS OF KURE BEACH Stormwater Detention Pond Calculations Stormwater runoff from the project will be retained in wet detention pond. This pond will store the runoff generated by 1 inch of rainfall. The stored runoff will be discharged over a period of 4.4 days. The pond area required to remove 90% of total suspended solids was calculated using the SA/DA Percentage Chart (see chart) for North Carolina coastal regions. Runoff Calculations 534$ 14-7 450 Impervious Surfaces: 125 = Bui'ld'ngs_@_2500_Sq._Ft.—Each—=-1.45,000—Sq.—Ft.2 (DZ SOO Streets and Driveways = 130,950 Sq.. Ft. Pool (including parking and walks) = 8,775 Sq. Ft. Total Impervious Area = 284,725 Sq. Ft. = 6.54 AC. Pervious Surfaces (Grassed, Landscaped areas) = 397,425 Ac. = 9.12 Ac. 284,725 x 0.083' Runoff = 23,632 CF 397,425 x 0.083' Runoff x 0.2 (R.O. Coefficient) = 6,597 CF Total Runoff (1" Rainfall) = 30,229 CF = 226,113 Gallons (Surface --areaof—detention pond at --mean elevation of-1'4-65') 60,984 Sq.Ft. in 30,229 CF i- 60,984 Sq. Ft. = 0.5' Storage Depth Required. % erdr �p / � (p S Keys —St 2 n Solids Settling Area Calculations Total watershed area = 15.66 AC. Impervious % = 6.54 AC a 15.66 AC. = 41.8% CBasin Mean Depth 4.0� Ac k,t,O� 31 is I' 5ec�k-""'+ XEa- SA/DA% required for 90% solids removal (see chart) = 3.6% 3.6% x 15.66 AC = 0.56 AC. Basin Surface area @ mean storage elev. of 14.65' = 1.40 Ac. Basin is therefore adequate for 90% TSS removal. Keys -St 3 SA/DA - 85%:TSS REMOVAL WITH 30' VEGETATIVE FILTER IMPER.% 3.OFT 3.5FT 4.OFT 4.5FT 5.OFT 5.5FT 6.OFT 6.5FT 7.OFT 7.5FT 10% .9 .8 .7 .6 .5 20% 1.7 1.3 1.2 1.1 1.0 .9 .8 .7 .6 .5 30% 2.5 2.2 1.9 1.8 1.6 1.5 1.3 1.2 1.0 .9 40% 3.4 3.0 2.6 2.4 2.1 1.9 1.6 1.4 1.1 1.0 50% 4.2 3.7 3.3 3.0 2.7 2.4 2.1 1.8 1.5 1.3 60% 5.0 4.5 3.8 3.5 3.2 2.9 2.6 2.3 2.0 1.6 70% 6.0 5.2 4.5 4.1. 3.7 3.1 2.9 2.5 2.1 1.8 80% 6.8 6.0 5.2 4.7 4.2 3.7 3.2 2.7 2.2 2.0 90% 7.5 6.5 5.8 5.3 4.8 4.3 3.8 3.3 2.8 1.3 100% 8.2 7.4 6.8 6.2 5.6 5.0 4.4 3.8 3.2 2.6 THE KEYS SA/DA - > 90$ TSS REMOVAL FOR WET DETENTION WITHOUT VEGETATIVE FILTER IMPER.$ 3.OFT 3.5FT 4.OFT 4.5FT S OFT 5.5FT 6.OFT 6.5FT 7.OFT 7.5FT 10% 1.3 1.0 .7 .6 .5 .4 .3 .2 .1 20% 2.4 2.0 1.8 1.7 1.5 1.4 1.2 1.0 .9 .6 30% 3.5 3.0 2.7 2.5 2.2 1.9 1.6 1.3 1.1 .8 4177 40% 4.5 4.0 3.5 3'63.9 3.1 2.8 2.5 2.1 1.8 1.4 1.1 50% 5.6 5.0 4.3 3.5 3.1 2.7 2.3 1.9 1.5 60% 7.0 6.0 5.3 4.8 4.3 3.9 3.4 2.9 2..4 1.9 70% 8.1 7.0 6.0 5.5 5.0 4.5 3.9 3.4 2.9 2.3 80% 9.4 8.0 7.0 6.4 5.7 5.2 4.6 4.0 3.4 2.8 90% 10.7 9:0 7.9 7.2 6.5 5.9 5.2 4.6 3.9 3.3 100% 12.0 10.0 8.8 8.1 7.3 6.6 5.8 5.1 4.3 3.6 0 ORIFICE DISCHARGE RATE CALCULATIONS Use 2 z"' diameter orifice for outlet. Calculate average discharge rate and time to lower orifice head from 0.50' to 0.45': 0.05' pond height x 60,984 Sq. ft. pond area (@ mean storage elev.) x 7.48 gal/ft3 = 22,808 Gallon Storage Average head on orifice from 0.50' to 0.45' = 0.475' Average discharge rate @ 0.475' head: Q(GPM) = (449)c A 2gh Y Q(GPM) = .Volume discharged in gallons per minute c = discharge coefficient = 0.6 A = orifice area in square feet g = gravity = 32.2 h = head above center of orifice Q(GPM) = (449)(.6)(.0341) (2)(32.2)(0.475) Q = 50.8 GPM Time required to lower pond 0.1' @ 0.475' average head: T = 22,808 Gal. o- 50.8 GPM = 449 minutes 50.8 minutes vs 449 minutes plotted on curve (See Discharge Curve). Discharge rate and time to lower head from 0.45' to 0.40': Q = 48.1 GPM T = 22,808 Gal. r 48.1' GPM = 474 minutes 48.1 GPM vs 923 minutes plotted on curve. Keys —St 4 Discharge rate and time to lower head from 0.40' to 0.35': Q = 45.1 GPM T = 22,808 Gal. r.45.1 GPM = 506 minutes 45.1 GPM vs 1429 minutes plotted on curve. Discharge rate and time to lower head from 0.35' to 0.30': Q = 42.0 GPM T = 22,808 Gal. f 42.0 GPM = 543 minutes 42.0 GPM vs 1972 minutes plotted on curve. Discharge rate and time to lower head from 0.30' to 0.25': Q = 38.7 GPM T = 22,808 Gal. r 38.7 GPM = 590 minutes 38.7' GPM vs 2,562 minutes plotted on curve. Discharge rate and time to lower head from 0.25' to 0.20': Q = 35.0 GPM T = 22,808 Gal. o- 35.0 GPM = 652 minutes 35.0 GPM vs 3,214 minutes plotted on curve. Discharge rate and time to lower head from 0.20' to 0.15': Q = 30.8 GPM T = 22,808 Gal. = 30.8 GPM = 740 minutes 30.8 GPM vs 3,954 minutes plotted on curve. Discharge rate and time to lower head from 0.15' to 0.10': Q = 26.1 GPM T = 22,808 Gal. t 26.1 GPM '= 873 minutes 26.1 GPM vs 4,827 minutes plotted on curve. Keys —St 5 Discharge rate and time to lower head from 0.10' to 0.05': Q = 20.2 GPM T = 22,808 Gal. r 20.2 GPM = 1,129 minutes 20.2 GPM vs 5,956 minutes plotted on curve. Discharge rate and time to lower head from 0.05' to 0.00': Q = 11.7 GPM T = 22,808 Gal. r 11.7 GPM = 1949 minutes 11.7 GPM vs 7905 minutes plotted on curve. The outlet structure will discharge the total calculated runoff volume of 226,113 gallons in approximately 4.4 days (See Orifice Discharge Curve). Keys —St 6 70 THE KEY5 5r0Rf1b•1ATE S POND ORIFICE DISCHARGE 60 50.BGPf7/449 MIN.; i I i 48•IGPM/923 MIN, °O 45.1 GPM/I429 MIN. r;t,O CrPM f 177 2 14; P,- y 38.7 GPAI'1 562. (YIP; 2,5"{!i ORIFICE WILL DISCHARGE CALCULRTED 40 RUfJO! F, VOLJ1irE OF \ S35•0GPId11214• MIN. 226�1'13 GALS, (A' CL:w z e�- 1' 30.?GP1e�1R5'4 MIN v 30 �2 L.1 GPAV; 927 HIN. 2o,2FPM/5956 MIN. 20- LI'�,7GPM/790'SM/N. I L' i DAY 1 DAY 2 DAY 3 DAY + DAY 5 71,700 GALS, 5B,500 GALS, 4 E?,300 rAL 5 I u, 'o;) 6:AL5. 26,400 GALS. 0 0'00 2000 3600 40;00 000 6'000 700,0. BOiO,b 90;o0 State of North Carolina Department of Environment, Health, and Natural Resources Wilmington Regional Office James B. Hunt, Jr., Governor DIVISION OF ENVIRONMENTAL MANAGEMENT Bob Jamieson Jonathan B. Howes, Secretary Regional Manager March 1, 1994 Mr. Joseph S. Hill, P.E. Joseph S. Hill and Associates 1602 Harbour Drive Wilmington, North Carolina 28401 Subject: ADDITIONAL INFORMATION Stormwater Project No. SW8 940217 The Keys at Kure Beach New Hanover County Dear Mr. Hill: The Wilmington Regional Office received a Stormwater Submittal for the The Keys at Kure Beach on February 21, 1994. A preliminary review of that information has determined that the submittal for the subject project is not complete. The following information'is needed to continue the stormwater review: 1. Please print or type the name, address, and phone number of the responsible party on the Operation and Maintenance Plan. The O & M Plan must be notarized by a notary public, not witnessed. 2. The surface area provided must be based on the surface area at the permanent pool of 14.4, not the mean pool of 14.65. I am unfamiliar with the term mean pool elevation. This Office requires only a permanent pool and a storage pool elevation. The calculations also do not address the surface area and volume provided at the storage contour (14.9) for the 1" volume; they only address the required volume. 3. Three (3) sets of plans are required for all first time submittals and subsequent revisions. 4. If you place the center of the orifice at 14.4, then the water will actually draw down to 14.3 based on a 2.5" orifice. Please revise the detail to indicate that the invert of the orifice is 14.4. 127 Cardinal Drive Extension, Wilmington, N.C. 28405-3845 • Telephone 910-395-3900 • Fax 910-350-2004 An Equal Opportunity Affirmative Action Employer _r Mr. Hill March 1, 1994 Stormwater Project No. SW8 940217 5. Has the off -site runoff on Kure Village Way been accounted for or routed around the pond? How will the runoff on Club Drive reach the pond? It appears that an existing piped system is collecting that runoff ancj�transporting it to the existing 30" CMP at the west end of Club Drive. W PaCi 5 i�� 6. Please provide a standard building dimension detail. My calculation of building area is 5,898 square feet per building, not 2,500 as you indicate. Please revise your calculations to reflect the actual building footprint - (2,500 x 25 = 62,500 not 145,000). My calculation of total impervious area is approximately 4,000 square feet more than yours. Providing the building detail should clear up the difference. Please note that this request for additional information is in response to a preliminary review. The requested information should be received by this Office prior to April 1, 1994, or the submittal will be returned as incomplete. If you have any questions concerning this matter please feel free to call me at (910) 395-3900. 1. 41d, ndq- 5{Ur2ye.. (J Sincerely, v Ms. Linda Lewis Environmental Engineer DA/arl: S:\WQS\STORMWAnADDINFO\940217.MAR cc: (2) Linda Lewis Central Files JOSEPH S. HILL, JR AND ASSOCIATES CONSULTING ENGINEERS and PLANNERS IW2 HARBOUR DRIVE W INGWN, NORM CAROIINA TTlEPHONE910.99A15" Fdbr,uary 211, 1994 Ms. Linda Lewis N.C.D.E.M. 127 Cardinal Drive Extension Wilmington, North Carolina 28405 Subject: The Keys of. Kure Beach Stormwater Management Plan New Hanover County Dear Ms. Lewis: MAILNGADDnccG POST OT}mC BOX 559LSTA.1 WIU&NGTON, NC ]8 155 I a��seIra V R % 4z" V r Ff B 211994 U Enclosed are two (2) copies of the stormwater management plan for The Keys of, Kure Beach. This project is a townhouse development. It is located adjacent to an existing drainage ditch discharging to the Cape Fear River, which is classified SC. The project built —upon area is calculated to be 41.7%. Storm drainage piping, catch basins, and asphalt curbing will be used to collect and channel runoff. Therefore, a wet detention pond will be constructed to treat stormwater prior to discharge. The following items are included: 1. Site plan indicating built —upon surfaces. (2 copies) 2. Computations showing percentage of built —upon surfaces. (2 copies) 3. Completed and signed stormwater submittal form, (original) Please review this plan .as soon as possible. Copies of the plan have also been sent to the New Hanover County Engineering Department for their review with regards to erosion control. Pleaseludo noit hes�ita.te to contact me if you have any questions or need additional i�flo.g`S`Iww'?9 �E iii, FEB 2 1 1994 OEM nT #Scl4oZf7 JSH/pat cc: Mr. Jim Craig Sincerely, JOSEPH S. HILL, JR. and ASSOCIATES 9"Y !JQ Joseph S. Hill, Jr., P.E. 2 The Iles of Kure Poeeob 5w's g4-oZ7 lease or /-4/ve n2me-j 2 dress " pha� e 4r- o-f re spa s; 1 le Per Imo, musf be noior',-zed b �a �f (Ju�'J�iGr ✓)C>�" WI I Y12SSeC�. II y �l 90 % T55' Z 2, CaIGS o10 rnof- prove% a checla Fcr 5hya-- je C2ff _ Cl i 5�1� or ,elevzho� Fes. ProfJose� 1ii -runoff. T 4. F/o?5 CoIC 5 017cl da Civf m olch - 5 5 ce 5- 5 bw SA b2secl o� 1-2 r✓I O—f Ci'l fYe l4. -T-( C2/17"eK r s ac PC /7(.Zo83� 14, 3' � c/ue5 mean of elevoe'=m5Z _ SPeor ,& 3 s s oll clef�i -- 1',�_' _- - - _ -- - -- --- ,, __ 1-. -- � --- --, --_ _--- -_ __ ,�� -- _,_ __- -- -- _ �_ -- _- - �. - -L -- �_ _. _ ;mod 2f 2a,c uea�cJ o 9�gS = �I C7' �S Ie4o-L + (Sx oL c-17 � L S �12�C0) X,Sx0)tIZ� fi CZX OZ 7Ze) f CCV ' 2bSZ. x -b2 I - SL/,P� 081�2 J0 ogL aue� s,al 2 — OL�=lI sus ' J155, 0, 000 Sj7l -� nu 9Q52� = S2 oos2 '00sz q Vne -gig jt� . 86gs f 1 Z �vod rt� �af�zi/o Z r�2n�1 �vcl sxa � a'/lUG G�(��Si_ - DLP�S / nrnlr% Z foafWoC una of s _.1.g a� �� i _ �'� _- �'� _ -_ �- ` �� s .. .. Y . . �. _� �. r THE KEYS OF KURE BEACH EROSION CONTROL PLAN I'1 141 FEB 21 1994 LAND QUALITY SECTION 111J:'iHNGTO'N REGK)iNAL OFFiClr �To, R :E: U� FEB 2 1 199A U EM January 1994 ^T # gDWa6)40Z11_. S. 0 .� ry _ SEAL 9t; t 8432 j d`i e S.Yo.• 11 Zo lq4 Prepared By: JOSEPH S. HILL, JR. and ASSOCIATES CONSULTING ENGINEERS and PLANNERS 1602 Harbour Drive Wilmington, N.C. 28401 (919)799-1544 THE KEYS OF KURE BEACH Runoff Calculations 2. Drainage Channel Calculations 3. Outlet Protection Design 4. Sediment Basin Design 5. SECTION 1600 — Landscaping 6. SECTION 2400 — Storm Sewers THE KEYS OF KURE BEACH Calculations for Erosion Control Plan Runoff Calculations Storm Sewer Design For calculation purposes, the site was divided into specific drainage areas. The various project drainage structures and channels were then sized to handle runoff generated by a 10—year, 24—hour storm, using the rational formula (Q = CiA). Q = Runoff. Volume C = Runoff Coefficient (Varies according to slope, ground cover, water surface area) i = Intensity, inches per hour (varies according to Tc) A = Contributory Area, Acres Storm intensity (i)'was derived for each area by determining the time of concentration (Tc) for the various drainage structures and applying Tc to a storm frequency chart (attached) for the Wilmington Area. Tc was determined by adding overland flow (see attached overland flow nomograph) times, pipe flow velocities (see attached pipe flow graph), and channel/swale velocities to and through the various drainage structures. Channels and swales were designed using methods developed by H. Rooney Malcom (see attached design discussion). The resulting project channels were then checked for velocity using the Manning Equation: V = 1.49 x r2/3 x S1/2 n Keys —Er 1 THE KEYS OF KURE BEACH Runoff Calculations AREA #1 Tc = 10 min. (to Catch Basin) C = 0.30 i = 5.2 in/hr. A = 1.33 AC. Q = 0.30 x 5.2 x 1.33 = 2.07 CFS Provide 15" diameter RCP @ 0.2% CFS. AREA #2 Tc = 15 min. (to Catch Basin) C = 0.30 i = 4.8 in/hr. A = 1.11 AC. Q = 0.30 x 4.8 x 1.11 = 1.60 CFS Runoff from Area #1 = 2.07 CFS Total Runoff = 3.67 CFS This pipe is capableof transmitting 3.0 Provide 18" diameter RCP @ 0.2%. This pipe will transmit 5 CFS. Keys —Er 2 AREA #3 Tc = 10 min. (to Catch Bain) C = 0.30 i = 5.2 in/hr. A = 1.33 AC. Q = 0.30 x 5.2 x 1.33 = 2.07 CFS Provide 15" diameter RCP @ 0.2% as shown. This pipe will transmit 3 CFS. AREA #4 TC = 10 Min. (to Catch Basin) C = 0.30 i = 5.2 in/hr. A = 1.62 AC. Q=0.30x 5.2 x 1.66=2.59CFS Runoff from Area #3 = 2.07 CFS Total Runoff = 4.66 CFS Provide 15" 0 RCP @ 0.5%. This pipe will transmit 5 CFS. Keys —Er 3 AREA #5 Tc = 15 min. (to Catch Basin) C = 0.30 i = 4.8 in/hr. A = 0.87 AC. Q = 0.3 x 4.8 x 0.87 =.1.25 CFS Runoff from Areas #1 & 2 = 4.66 CFS Total Runoff = 5.91 CFS Provide 18" 0 RCP @ 0.3%. This pipe will transmit 6.5 CFS. AREA #6 T c = 10 min. (to Catch Basin) C = 0.30 i = 5.2 in/hr. A = 1.05 AC. Q = 0.30 x 5.2 x 1.05 AC = 1.64 CFS Provide 15" 0 RCP @ 0.2%. This pipe will transmit 3 CFS AREA #7 Tc = 10 min. (to Catch Basin) C = 0.30 i = 5.2 in/hr. A = 1.26 AC. Keys —Er 4 Q = 0.30 x 5.2 x 1.26 = 1.97 CFS Runoff from Area #6 = 1.64 CFS Total Runoff = 3.61 CFS Provide 15" 0 RCP @ 0.3%. This pipe will transmit 4 CFS. AREA #8 Tc = 15 min. (to Catch Basin) C = 0.30 i = 4.8 in/hr. A = 1.33 AC. Q = 0.30 x 4.8 x 1.33 = 1.91 CFS Runoff from Area #6 & 7 = 3.61 CFS Total Runoff = 5.62 CFS Provide 18" 0 RCP @ 0.3%. This pipe will transmit 6.5 CFS. AREA #9 Tc = 5 min. (to inlet to sediment basin) C = 0.30 i = 6.5 in/hr. A = 0.39 AC. Q = 0.30 x 6.5 x 0.39 AC = 0.76 CFS Provide 15" 0 RCP @ 0.2%. This pipe will transmit 3 CFS. Keys —Er 5 DRAINAGE CHANNEL CALCULATIONS A stormwater detention pond will act as a sediment basin during construction. Design outfall channel from stormwater pond discharge. I. Design drainage swales.with "best" hydraulic section.. Use 100 year flow from stormwater pond outlet pipe (33 CFS + 20 CFS for offsite drainage). Maximum Permissible Velocity (bare soil) of 2.5 FPS. Refer to "Design Approaches . . ." by Rooney Malcom, Page 2-2 thru 2-5 attached. �4 W �. M T - 0 5' - 1.0' F.B. n = 0.03 s = 0.05 = .05/100 = .0005 , (EQ. 2-5) B = 2y ( 1 + M2 — M) (EQ. 2-6) K = 2 (-M-, + 1 — M) The depth of the best hydraulic section is defined by Manning: (EQ. 2-7) Y = Qn(K + 2 MV ` + 1)2/3 _ 3/8 1.4947(K + M)5/3 and the bottom width is: (EQ. 2-8) B=Ky the cross —sectional area of the resulting channel is: (EQ. 2-9) A = By + My Keys —Er 6 and the velocity of flow is: (EQ. 2-10) V = Q/A Size drainage channel along west property line downstream from sediment basin outlet: Q=5.5CFS M=3 .375 Y = (53)(.03)(.47.+ 2 10)'67 and K = 2(10-3) [.49 0005 (.32 + 2) 1.67 K = 0.32 y = 4 B = Ky = 1.28' (Say 2.0') A = 2(4) + 3(4)2 A=56 V (Manning) = 1.49 x r2/3 x S1/2 = 1.49 x 2.052/3 x .0005112 = 1.8 FPS n .03 Conclusion: Velocity is non —erosive for bare soil and seeded grass cover. Provide drainage ditches with bottom slope of 0.05% or less constructed to dimensions shown on ditch section detail. Keys —Er 7 DESIGN APPROACHES FOR STORMWATER MANAGEMENT IN URBAN AREAS by H. Rooney Malcom, Jr. Assistant Professor of Civil Engineering and Vernon E. Nev Teaching and Research Assistant North Carolina State University Raleigh, 'North Carolina May, 1975 9 2-2 Trapezoidal Channels Design Objective: The objective is to select a trapezoidal channel section.which will minimize the total cost of channel installation, consistent with the constraints of containing the design flow at an erosion -resistant .. velocity. Definition Sketch: W �� Design Variables: Normally, flow, q, and slope, s. are invariant. Variables under the control of the designer are the channel width, B or W, the side slope, M, and to some extent the depth, y. The maximum permissible velocity, Vmax, and the Manning roughness coefficient, n, are properties of the channel lining under consideration. Cost Sources: Channel installation costs accrue chiefly from three sources: land taken by the channel, excavation required to provide the specified cross-section, and the installed cost of the channel lining. The cross-section for which the sum of these three costs is minimized is the optimum channel section. Hvdraulic Functions: Most channels of significant length can be assumed to behave as if flow were uniform, in which case the Manning equation applies. Stated to yield both velocity and flow, the equations are: Q 1.49 AR2/3 sl/2 (2-1) n V . 1.49 R2/3 sI/2 n 2-2 where Q - Channel flow (cubic feet per second) V - Cross -sectional average velocity (feet per second) A.- Cross-sectional.area of flow (square feet) R a Hydraulic radius (ft) s Water surface slope (ft per ft) n - Manning roughness coefficient (dimensionless) The hydraulic radius, R, is found by dividing the cross -sectional area of flow, A, by the wetted perimeter. The wetted perimeter is that part of the channel lining in contact with water flowing in the channel. The "Best" Hydraulic Section: It can be shown (9) that of all possible combinations of channel depth, width and side slopes, which will just carry the design flow, the best section is,the one which minimizes the wetted perimeter. That section uses the least crass -sectional area, thus requiring the least excavation, and it requires the least channel lining. If land costs are not extremely high, this channel will almost certainly be the most economical channel. In the event that land value is extremely high, it is quite probable that complete enclosure of the channel in pipe is the most economical approach. It oan also be shown that the optimum side slope is at an angle of 60' with the horizontal (9), or in common slope terms, 0.58 to I. Soil stability considerations, however, usually require side slopes to be placed at 1 to 1 or flatter, except for some concrete channels. Given that the desired side slope, M to one, has been selected for a given channel, Streeter (9) shows that the minimum wetted perimeter, P, exists when P - 4y 1 + MZ - 2 My (2-3) U 2-3 (See the Definition Sketch). From the geometry of the channel cross-section. it is also true that P - B + 2y 1✓ + M` (2_4) By equating the two expressions, the relationship between.bottom width, B, and depth, y, for the best hydraulic section is determined to exist when B + M2 (2-5) Further, it can be shown that maximum hydraulic efficiency (best hydraulic section) occurs when the hydraulic radius, R, is equal to half the depth, y. Thus, the properties of the best trapezoidal channel are established: that the width and depth are in a specific relationship, and that the hydraulic radius equals the half -depth. Making use of these properties and applying the Manning equation in the flow fors yields two very powerful design equations, which eliminate the need for trial -and -error solutions to determine the most economical channel. The first defines a new quantity, k, which merely simplifies the form of the second equation: k . 2' ( M� ` + 1 - M) (2-6) Then, the depth of the best hydraulic section is defined by 0/ - _n C + 2 M+ 3/ 112/3 8 y (2-7) 1.49 rs fk + The associated bottom width is simply B -ky . (2-8) The cross -sectional area of the resulting channel is A - By + My (2_9) 2-4 and the velocity of flow is V A (2-10) .... . Once the parameters are determined, the bottom width, B, and the channel.'. depth, y, can be rounded to the next higher convenient values for inclusion in construction drawings. Velocitv Limitations: For given design conditions, the hydraulically efficient channel may result in flow at excessive velocity. High velocity flow enlarges the channel by attacking the banks, causing the channel to become wider and shallower with consequent damage both alongside the channel and downstream, where the dislodged material will choke streams and contribute to the filling of lakes. The computed velocity for the best hydraulic section, being subjected to design flow, should be compared to the maximum permissible velocity for the channel lining. The method which uses the concept of a maximum permissible cross - sectional velocity is based on the premise that each channel lining is sensi- tive to some average velocity of flow, above which it will be eroded, and below which it will be stable. The premise is tenuous, because the force. which damages the channel lining is a shear force which results from the severe velocity gradient along the channel walls. The magnitude of the shear force, also called the tractive force, :s a complex function of flow, channel shape, channel alignment, the nature of the channel lining, and other factors. (For a more detailed discussion of erosion -resistant channels, see Reference 7.) These effects have been lumped together in a concept which treats the average cross -sectional velocity as the most important influence on channel degrada- tion, and experiential values have been determined for many channel linings. Some of these are presented in Table 3. Stone -lined channels are frequently used. Values for Manning's n and maximum permissible velocities are shown in Chart 6. 2-3 El m H (ft) N t0 O L m C m E M E X Cu L (ft) 10000 1000 500 I A 10 Note: Use nomograph To for natural basins with well-defined channels, for overland flow on bare earth, and for mowed -grass roadside channels. For overland flow, grassed surfaces, multiply Tc by 2. For overland flow, concrete or asphalt surfaces, multiply To by 0.4. For concrete channels, multiply To by 0.2. Figure 8.03a Time of concentration of smell drainage basins. j 1 8.03.4 Appendices 20 15 10 8 Q 0.4 0.2 Imi 10 20 40 .60 2 3 4 6 8 12 18 24 Minutes Hours Duration Figure 8.03b Rainfall intensity duration curves —Wilmington. 5 10 20 40 60 Minutes Duration Figure 8.03c Rainfall intensity duration curves —Hatteras. 2 3 4 6 8 12 18 24 Hours 8.035 THE KEYS OF KURE BEACH Erosion Control Plan Outlet Protection Design 18" and 15" Diameter Pipe Outlets Use attached Nomograph to determine rip rap size and rip rap apron configuration for all 18" and 15" diameter RCP discharging to sediment basin. - Desion Criteria: 1. Flow = 6 CFS; 18" 0 outlet pipe. 2. Assume maximum tailwater conditions; well—defined channel. Pipe Diameter = Do = 1.5' Apron Length = La = 10' (from Nomograph) Upstream Apron Width = Wu = 3 x Do = 3 x 1.5' = 4.5' Downstream Apron Width = Do.+ La = 1.5' + 10' = 11.5' min. Median Stone Size = d50 = 0.4' min. (from Nomograph) (See attached Rip Rap Blanket Configuration — Plan View) Select "Class B" Stone (minimum) 5" — 15" Apron Thickness = 1.5 x dmax = 27' Keys —Er 8 7.54 Erosion and Sediment Control Handbook Wa Do` .. '1 Ouoet F pipe L. aPto� 25 to diameter 0o ar of ca" on`aeo9 of aFto 70 M �`m 20", ten` fi0 Lq r /0 r 5- 40 m`mm o ry ^ I II _m _a_m a a yp dgti o' rya0 om m `m O111 a5 d m d. t2 d c o m 9a V P 3 5 I 10 20 50 100 200 500 1000 Discharge. fts/sec .. � . 0.7 0.2 0.3 0.4 0.6 0.8 1 2 3 3 4 55 78 fi 7 8 10 15 20 25 ' Discharge, ma/sec Fig. 7.45 Design of riprap outlet protection from a round pipe flowing full; minimum tailwater conditions. (6, 14) to find the riprap size and apron length. The apron width at the pipe end should be 3 times the pipe diameter. Where there is a well-defined channel immediately downstream from the apron, the width of the downstream end of the apron should be equal to the width of the channel. Where there is no well-defined ch m- nel immediately downstream from the apron, minimum tailwater conditions apply and the width of the downstream end of the apron should be equal to the pipe diameter plus the length of the apron. EXAMPLE 7.4 Riprap Outlet Protection Design Calculation for Minimum Tailwater Condition Given A flow of 6 fts/sec (0.17 ms/sec) discharges from a 12-in (30-cm) pipe onto a 2 percent grassy slope with no defined channel. Find: The required length, width, and median stone size d, for a riprap apron. THE Na5 I $ '-� ctn d 15 "0 Ovflof-s ds, _ O. I- Water Conveyance and Energy Dissipation 7.57 sent. However, to simplify our calculations, we will assume that both i and A remain constant. Therefore, the postdevelopment runoff is 0.6 0.3 (20 ft'/sec) = 40 ft'/sec 1 �.3 (0.57 ms/sec) — 1.14 mr/sec This flow will exceed the natural capacity of the stream. It may erode the streambank and cause flooding problems. STEP 3. Determine how to accommodate the postdevelopment flow in a nonerosive man. ner. There are several ways we could handle the increased flow. We could further divide the subdivision so that approximately one-half drains into the stream and one-half Fig. 7.47 Riprap blanket configuration for outlet protec- tion; see the reference for design details. (2) THE KEYS OF KURE BEACH Erosion Control Plan Outlet Protection Design 36" 0 Pipe Outlet Use attached Nomographs to determine rip rap size and rip rap apron configuration for 36" 0 pipe outlet from sediment pond. Use "worst" case flow; 34 CFS. Desian Criteria: 1. 36" D RCP outlet pipe with 34 CFS discharge. 2. Assume maximum tailwater conditions; well—defined channel. Pipe Diameter = Do = 3.0 Apron Length = La = 14' (from Nomograph) Upstream Apron Width = Wu = 3 x Do = 3 x 3.0' = 9.0' Downstream Apron Width = Do + .4La = 3.0 + 5.6 = 8.6' min. (must extend channel width @ 3.5' depth) Median Stone Size = d50 = 0.20' min. (from Nomograph) (see attached Rip Rap Blanket Configuration — Plan View) Select "Class B" Stone (minimum) 5" — 15" Apron Thickness = 1.5 x dmax = 27" Each rip rap apron shall extend up channel side slopes 1' above the maximum flow.level. Keys —Er 9 Water Conveyance and Energy Dissipation 3 D, OutO utlet 1 5 1 yra . D, t 0.4 L, diameter 1 �— DeFL,� 1 35 I10 0 `�' 30 � 100 °� oka9 oc 90 aQ qvr 25 0 80 \ac C of �e°q 70 20 \�oF _ cn 5 50 40 r 10 30 16 .ham°arya 20 a o' Lq=� 5_ 10 0 0 7.55 m;Z�m-•- 7.0 p p 0.9 n n 0.8 5 ` 0.7 z a . a.6 a 3 5 10 20 50 100 200 3`f GGS 1/ Discharge, fta/sec 10.4 8. 0.3 n �0.2 0.1 SO .1 .2 .3 .4.5.6.7.8.9 2 3 4 56 7810 15 2025 Oischarge, m3/sec Fig. 7.46 Design of riprap outlet protection from a round pipe flowing full; maximum tailwater conditions. (6, 14) Solution: Since the pipe discharges onto a flat area with no defined channel, a mini- mum tailwater condition`✓:an he assumed. By Fig. 7.45, the apron length La and median stone size dse are 10 ft (3 m) and 0.3 ft (9 cm), respectively. The upstream apron width W. equals 3 times the pipe diameter Do: W =3XD, = 3(1 ft) = 3 ft [3(0.3 m) = 0.9 mj The downstream apron width W4 equals the apron length plus the pipe diameter: We=D,+L, =ift+loft=lift (0.3m+3.0m=3.3 m) Note: When a concentrated flow is discharged onto a slope (as in this example), gul- lying can occur downhill from the outlet protection. The spreading of concentrated flow THE KEYS 36 r,Q Ovfief Water Conveyance and Energy Dissipation 7.57 ment. However, to simplify our calculations, we will assume that both i and A remain constant. Therefore, the postdevelopment runoff is 0.6 0.3 (20 fts/sec) = 40 ft'/sec I L-3 (0.57 mt/sec) = 1.14 m'/sec I This flow will exceed the natural capacity of the stream. It may erode the streambank and cause flooding problems. STEP 3. Determine how to accommodate the postdevelopment Bow in a nonerosive man- ner. There are several ways we could handle the increased flow. We could further divide the subdivision so that approximately one-half drains into the stream and one-half D, = 3 3 D, = q 3I- E J W (ma.. TNI = W'(min. TW) Fig. 7.47 Riprap blanket configuration for outlet protec- tion; see the reference for design details. (2) FIGURE 6 SIZES FOR RIP SAP AND EROSION CTITROL STONE N.C. Department of Transportation Specificaticns - RIPRgP 8«}NKE75 1.uc Ve" 1 F n TRni p S OP,1 nF CSu'yt S�e wl,� Cass Class Class Class 1 2 A B Percer. 5 to 200 lbs. 25 to 250 lbs. 2" to 6" 5" to 15"I Z0 PasSin; (15 to E" 90-1CO - 30Z shall - 60Z shall 300 l::s. 30- 70 weigh a minimum weigh a minimum O- of 60 lbs. each of 100 lbs. each 3/4" 0- 5 - No more than - No more than _10Z tolerance Or use 1OZ shall 5Z shall weigh top b No. 4 stone, bottom i.e., 1Y" to weigh less _ less than 50 lbs. sizes 3/4" than 15 lbs. ea. each. - No grada- -No grada- tion tion specified specified Also, r i a ss ., 2-6', *Nctan NC -DOT Standard Specification NORTH CAROLINA AGGREGATES ASSOCIATION P. O. BOX ]0607 • RALEIGH. NC 27677 PHONE Jug) 787.7055 Page 17 THE KEYS OF KURE BEACH Sediment Basin Design Calculations A stormwater detention pond will be used as a sediment basin to prevent off — site transportation of sediment during construction. The sediment basin is designed to function during a 10—year storm. Disturbed Area Entire site will be graded Site Area = 15.66 AC. Basin Dimensions Area = 1.40 AC. Top of Dam Elev. = 17.0' Top of Riser = 14.9' Riser Inv. = 14.0' Riser Diameter = 48" 0 Conduit Pipe = 36" 0 Basin Bottom Elev. = 10.4' Storage Volume Calculations Provide 0.5 Ac—in. storage depth per disturbed acre 15.66 AC. x 0.5 Ac—in. = 7.8 Ac/in. Top of Riser = 14.9' Basin Bottom Elev. = 10.4' Basin Storage Depth = 4.5' 7.8 Ac/in. = 54" = 0.15 Acres required basin area Basin dimensions (Actual) = 1.40 Acres Keys —Er 10 Runoff Calculations Use Rational Formula to estimate runoff generated by 10 year event. Q = CiA Q = Runoff Volume = ? C = Runoff Coefficient = 0.3 i = Rainfall intensity = 4.8 in/hr. A = Area = 15.66 AC (includes allowance for off —site runoff) Q = 0.3 x 4.8 x 15.66 Q = 22.60 CFS Spillway Provide 36" 0 conduit pipe at 0.4% slope from sediment basin to ditch as shown. Provide rip rap at locations shown for energy dissipation. Provide 48 0 riser with stormwater dewatering orifice. This outlet structure will retain the total runoff volume generated by a 10—year storm event and gradually release this volume over a 3 to 5 day period. Since the sediment basin will remain as a permanent stormwater management pond, the spillway must transmit 100% of flow generated by a 100 year event. Q = 0.3 x 7.0 x 15. 66 Q = 33.88 CFS Conduit pipe will transmit 45 CFS. Dam Design Provide l' (min.) freeboard above top of riser: Min. Pond Rim Elev. = 17.0' Top of Riser = 14.9' Freeboard = 2.1' Provide 3:1 side slopes on pond banks and outfall ditch. Keys —Er 11 SECTION 1600 - LANDSCAPING - EROSION and SEDIMENT CONTROL A. General The Contractor shall provide all labor, materials, equipment, tools, and perform all work and services necessary for or incidental to landscaping as required by these specifications and/or shown on the plans. All supplementary or miscellaneous items, appurtenances or services necessary for a complete job. shall be furnished as a part of this work, although such work shall not necessarily be shown or specified. All work shall comply with. the regulations of the North Carolina Sedimentation Control Act of 1973. All erosion control devices shall be installed and maintained as required by the North Carolina Department of Natural Resources and Community Development. Such measures may consist of berms, dikes, drains, and sediment basins, or use of fiber mats, woven plastic filter cloths, gravel, mulches, bituminous spray, and other erosion control devices or methods. All erosion and sediment control devices shall be approved by the Engineer prior to installation. B. Landscaping 1. The work includes seedbed preparation. liming, fertilizing, seeding, and mulching of all disturbed areas. The work also includes those areas inside or outside of limits of construction that are disturbed by the Contractor's operation. 2. The ground surface shall be clear of stumps, stones, roots,. cables, wire, grade stakes, and other materials that might hinder proper grading, tillage, seeding or subsequent maintenance operations. 3. Where lawns are to be planted in areas that have not been altered or disturbed by excavating, grading, or stripping operations, prepare soil for lawn planting as follows: Till to a depth of not less than 6". Apply soil amendments and initial fertilizers as specified. Remove high areas and fill in depressions. Till soil to a homogenous mixture of fine texture, free of lumps, clods, stones, roots, and other extraneous matter. 4. Grades on the area to be seeded shall be maintained to a true and even condition. Maintenance shall include any necessary repairs to previously graded areas. 5. All graded areas shall be thoroughly tilled to a depth.of at least four 0) inches by plowing, disking, harrowing, or other approved methods until the condition of the soil is acceptable. On sites where soil conditions are such that high clay content and excessive compaction cause difficulty in getting clods and lumps effectively pulverized, the Contractor shall use the rotary tillage machinery, until the mixing of the soil is acceptable and no clods and clumps remain larger than 1 1/2 inches in diameter. A firm and compact seedbed is required, and after being graded, the seedbed shall be lightly compacted with a land roller such as a cultipacker before and after seeding. 6. Limestone shall be dolomitic agricultural -ground limestone containing not less than 10 percent magnesium oxide and uniformly applied at a rate of 2000 pounds per acre prior to preparation of seedbed. 7. Fertilizer shall be the standard commercial product uniformly applied at a rate of 1000 pounds per acre of 10-10-10 analysis. 8. The fertilizer shall be incorporated into the upper three or four inches of prepared seedbed just prior to the last tillage operation, but in no case shall be applied more than three days prior to seeding. Fertilizer shall be used immediately after delivery or stored in a manner that will not permit.it to harden or destroy its effectiveness. When hydroseeding equipment is: used for seeding, fertilizer shall be applied simultaneouly with seed, using the above rates of application. 9. Seed shall be certified seed or equivalent based on North Carolina Seed Improvement Association requirements for certification. All seed shall be furnished in sealed standard containers. Seed which has become wet, moldy, or otherwise damaged prior to seeding, will not be acceptable. 10. Seeding shall be accomplished with. power -drawn planters and land packer or hydroseeding equipment at the rate of: From September 15 to April 15; 75 pounds per acre of Tall Fescue, Kentucky 31 or Alta Tall Fescue. 100 pounds per acre Unhulled Bermuda. From April 15 to September.15: 75 pounds per acre of Hulled Bermuda. 75 pounds per acre of Tall Fescue, Kentucky 31, or Tall Fescue. 1% maximum weed seed content permitted. 11. When conditions are such, by reason of drought, high,wi,nds, excessive moisture or other. factors where satisfactory results will not be obtained, the work shall be stopped and resumed only when conditions are favorable. 12. Apply 4,000 - 5,000 lb/acre grain straw or equivalent cover of another suitable mulching material. Anchor mulch by tacking with asphalt, roving, or netting. Netting is the preferred anchoring method on steep slopes. 13. Method used to apply the mulch shall be mechanical type equipment and shall obtain a uniform distribution. to permit sunlight to penetrate to the ground surface. 14. Provide and maintain temporary piping, hoses, and lawn watering equipment as required to convey water from water sources and to keep.lawn areas uniformly moist as required for proper growth. Maintain lawns by watering, fertilizing, weeding, mowing, trimming, and other operations such as rolling, regrading, replanting as required to establish a smooth, acceptable lawn, free of eroded or bare areas. Remulch with new mulch in areas where mulch has been disturbed by wind or maintenance operation sufficiently to nullify its purpose. Anchor as required to prevent displacement. Replace bare areas using same materials specified for laNms. SECTION 2400 - STORM SEWER A. General i. 1. Description - This item shall consist of all reinforced concrete plus other storm pipe of the sizes and dimensions called for on the plans, furnished and installed at such places as are designated on the plans or by the Engineer with the lines and grades given and in conformity with these specifications. 2. This item 'shall also include the furnishing and construction of such joints and connections to other pipes, boxes, storm manholes, junction manholes, catch basins, etc., as may be required to complete the work as shown on the plans. All snoplLmnentary or miscellaneous items, appurtenances and devices incidental to or necessary for a sound, secure and complete storm drainage system, shall be furnished and installed as part of this work, although all such work may not be specifically shown or identified. The Contractor shall check all drawings relative to dimensions, elevations, sizes, and locations of all work. Any discrepancies shall be adjusted prior to proceeding with the work. 3. Materials- All materials shall be free from any defects and in general be in accordance with the plans and all applicable ASTM or other standards. 4. All reinforced concrete storm pipe used in this project shall be manufactured in accordance with and shall meet the test requirements and conditions set forth in specifications for reinforced concrete sewer pipe, of the ASTM, serial designated C 76 (latest revision), and C 507 (latest revision). Class III pipe shall be used except where Class IV pipe is specifically called for on the plans. Gaskets shall be RAM-NEK as manufactured by K.T. Synder Company, Inc. of Houston, Texas, and meet or exceed all requirements of ASTM C-443 and Federal Specifications SS-50002I0, or equal as provided by Engineer. 5. Ali vitrified clay used in this project shall comply with ASTM Designation C-700 (latest revision). A11 clay sewer pipe shall be extra strength pipe and each length of pipe shall bear the initials or name of the manufacturer, the location of the plant and the words, "Extra Strength" or the symbol "ES". Joints for Vitrified Clay SelT and Spigot Pipe shall comoTy with ASTM Designation C 425 (latest revision). The spigot may be formed from an isophthalic polyester casting bonded to the clay pipe and designed to receive a high quality " " 0 ring gasket. 6. All ductile iron pipe and fittings used in this project shall be bituminous cpated and shall be in accordance with the latest re- visions of the following: "American Standards Association" Standards ASA-A 21.4; ASA-A 21.10, ASA-A 21.11; ASA-A 21.50 (Class 51); and ASA-A 2T.51 (Class 51). All fittings-shaTT be Class T50 in accordance with ASA-A 27.10, latest revision. 7. Concrete poured in place shall be 4000 psi (28 day strength) unless otherwise specified. Precast concrete shall be in accordance with the applicable ASTM. 8. Reinforcing Steel - Reinforcing steel shall comply with ASTM A675, Grade 60 unless otherwise shown or specified. TM 9. Casting - Castings for catch basins, manhole covers, downspout boots and the like shall be of tough, even grained ductile iron, free from warp, projections, sand holes, burnt -on sand, and other injurious defects, and of the type and dimensions shown by the draw.ings. Ail such iron frames and covers shall be machined sufficiently to prevent rocking. Before leaving the foundry castings shall be thoroughly cleaned, subjected to hammer test for soundness, and given two coats of coal tar pitch varnish. 10. Cleanout - Cleanouts are required as designated on plans. B, hatch Basins and Oroo inlets 1. Materials shall conform to the requirements of the N.C. Department of Transportation Saecifications. 2. Brick - Brick used in catch basins and/or drop inlets shall be in conformity to NCDOT Standard Specifications for Roads. and Structures 1978 and shall be laid with full shove joints; ail joints shall be thoroughly filled with mortar and the thickness of joints on the inside of the wall must not be more than three -eights (3/8) of an inch. 3. Concrete Block- Solid concrete block shall be made by a manufacturer approved by the Engineer and shall be tested and certified. by a reputable Testing Laboratory approved by the Engineer. 4. Concrete - Shall be 4000 psi (28 day strength) unless otherwise specified. Precast concrete shall be as required by the applicable ASTM. n 5. Manholes - Manholes shall be in accordance with the plans and general specifications under Section 0300-"Planholes". Precast manholes shall be in accordance with the applicable ASTM. 6. Castings - Shall be in accordance with specifications in other sections and as shown on plans. 7. Contractor shall examine the substrate and the conditions under which concrete formwork is to be performed. Do not proceed with the work until unsatisfactory conditions have been corrected. 8. Unless otherwise shown or specified, design, construct, erect, maintain and remove forms and related structures for cast -in - place concrete work in compliance with the American Concrete Institute Standard ACT 347, "Recommended Practice for Concrete Formwork". 9. Allowable Tolerances - Construct formwork to provide completed concrete surfaces complying with the tolerances specified in ACI 347 after removal of forms and prior to -patching and finishing of cast -in -place formed surfaces. 10. Design of Formwork (a) Design and construction of formwork is responsibility of Contractor.' (b) Design, erect, support, brace, and maintain formwork and shoring to safely support all superimposed concrete and con- struction loads placed on them. Transmit loads to ground by formwork system and in -place construction that has attained d adequate strength for that purpose. Construct formwork to provide concrete members and structures of correct sizes, shape, alignment, elevation and position. (c) Design formwork to be readily removable without impact, shock, or damage to cast -in -place concrete surfaces and adjacent materials. II. Form Construction - General (a) Construct forms to comply with ACI 347, to the exact sizes, shapes, lines and dimensions shown, and as required to obtain accurate alignment, location, grades, level, and plumb work in finished structures. Provide for openings, Offsets, sinkages, keyways, recesses, moldings, rustications, reglets, chamfers, blocking, screeds, bulkheads, anchorages, and inserts, and other features required. 12. Accessories and Embedded Items (a) Installation of Embedded Items --Set and build into the work anchorage devices and other embedded items required for work of other trades that is at -',,ached to, or supported by, concrete. Use setting drawings, diagrams, instructions and directions provided by suppliers of items to be attached thereto. Care- fully coordinate and accurately locate embedded items. 73. Concrete Reinforcement - Fabrication (a) Detail and fabricate reinforcing bars in compliance with. ACI Manual of Standard Practice for Detailing Reinforced Concrete Structures (ACI-315) and Chaoter 7 "Details of Reinforcement" ACI Building Code (ACI 318). In event of fabricating errors, do not rebend or straighten bars in any manner that will injure or weaken material. Cold bend all bars. (b). Do not use any reinforcing having any of following defects: 1. Bar lengths, depths and bends exceeding specified fabrication tolerances. 2. Bends not indicated on project drawings or approved shop drawings. 3. Cracks or splits occurring at bends. 4. Bars with reduced cross-section due to excessive rusting or other causes. 14. Placing Reinforcing - Comply with CRSI "Placing Reinforcing Bars", and with ACI Building Code (ACI 318), Chapter 7 "Details of Reinforcement". 15. Do not place concrete an reinforcing which has ruse, mill scale, form oil, earth, ice, and other materials which will reduce or destroy bond. 16. Accurately position, support, tie and secure reinforcement against displacement by construction operations drawings. Where not shown, provide concrete cover as specified in paragraph 7.14 of ACI 318. 17. Space and locate reinforcing. bars as shown, on drawings and within placement tolerances stated in CRSI "Placing Reinforcing Bars". ,- 0 Maintain minimum clear distances between bars as stated in paragraph 7.4 of ACI 318. When reinforcing cannot be placed in its indicated locations within specified placing tolerances, or with specified minimum clear distances between rebars, notify Engineer immediately. Do not pour concrete until corrective action has been determined by Engineer. 18. Provide lap splice lengths as indicated an drawings. Where not indicated, provide top bar class C tension lap splice lengths as specified in paragraph 7.6 of ACI 318. Place lap spliced ends of bars in contact with each other and tightly wire together. 19. Refer to other applicable sections of the contract documents re- garding concrete, etc. 0 0