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Home My WebLink AboutSW7100908_HISTORICAL FILE_20100921STORMWATER DIVISION CODING SHEET POST -CONSTRUCTION PERMITS PERMIT NO. SW_� DOC TYPE ❑ CURRENT PERMIT ❑ APPROVED PLANS HISTORICAL FILE COMPLIANCE EVALUATION INSPECTION DOC DATE YYYYM M D D STORM WATER MANAGEMENT NARRATIVE FOR EXPRESS SEP 212010 Eastern Pride, Inc. NC ®ENR Family Dollar WASHINGTON, NC `♦♦��QPOFESSiO 9i12 2= INE fill III 9/! 4 logo PREPARED BY: PAMLICO ENGINEERING SERVICES, PLLC 128 ABBEY LANE WASHINGTON, NC 27889 252.945.2983 �' �V �[��' U`0\��19i, � /�✓`O 'VJ�O l� \ C � -:.i ifr` i! N t1 lilt '�"• .. f l F. i '`�s•i�d��t�eaV �j6��' Family Dollar Washington, North Carolina Storm Water Management Plan LOCATION: This site is located on the corner of Bonner Street and US Hwy 264, John Small Ave. Washington, Beaufort County, North Carolina. The site is currently an open grass field with one building and a concrete pad. DESCRIPTION: The site is currently a vacant field with a few trees and a concrete slab. The project shall not change the existing drainage pattern for the site. EXISTING DRAINAGE PATTERNS: Currently there are no offsite drainage structures around this project site. The site sheet drains from the corner of Bonner and John Small Ave toward Jacks Creek. This is in the general south east direction. There are no riparian buffers on this project area. PROPOSED PROJECT: This project will consist of stripping the site and grading the existing lot for construction of the building facility. All drainage shall continue in the same manner as was before construction. All drainage of the site is being treated through a proposed bio retention grass Swale. With the infiltration rates of the existing insitu soils it was determined to allow both the design storm for water quality as well as quantity be infiltrated and therefore no additional runoff will be produced by the project development. Storm Water Management Runoff from the site shall be treated through grass swales, concrete flumes and into one bio retention cell to treat the design storm event. It has been determined by the soils report the seasonal high water table is approximately 70 inches below the existing ground. With this information we were able to provide the required 2' separation between the bottom of the bio retention cell and the SHWT. Also the soil material at this location has an infiltration rate of at least 22"/hour. The ponds volume has been designed to treat the 1.5" rainfall, 3997 cf, and draw this volume down as required by the regulations. This volume was calculated using the simple method and is included in the documents. The volume of storage which is needed to be detained to meet the city's requirements for peak and post flow is 4912 cf based on pre and post development runoff calculations. The additional runoff which is to be detained for the peak runoff detention shall be stored in the grassed swales. The system has been designed for no discharge to leave the site during design rain fall events. The one year pre development flow has been calculated using the small watershed method. Attached are the calculations giving the exact figures for all of the volumes. The Charlotte Mecklenburg Design calculation method was used in design of the bio retention cell. The one year and ten year inflow hydrographs were routed through the bio retention cell using the spread sheets provided by Dr. Bill Hunt. All of the input data has been shown and the inflow hydrographs for the 1 and 10 year events have been included. Since the existing soils material is able to drawdown the cell no under drain is being used for this site. The overflow weir for the bio retention area has been placed so the water quality volume as well as the additional volume for post development runoff. This elevation is set at 6.39' based on the depth of water in the bio retention cell during the 1 yr 24 hr event. Any storm event producing water to exceed this depth will overflow the site and sheet flow across the existing property as it has flowed prior to development. Engineers Certification 1, Marie U. Peedin, PF, do hereby sign this certification stating the design of this drainage system for the Family Dollar Store Washington is in compliance with the City of Washington's stormwater management ordinance. This design is also in compliance with the Tar Pam Nutrient Reduction Laws. I also assure the installed system will meet design specifications upon initial operation of the system once the project is complete and the entire drainage area is stabilized. SEAL r%rnunrr,�� ,A i 1 Q Z �99i� •,Fi�a iNE�f'• F��: u r Sep 01 10 11:35a Fred Smith 252-459-7798 p.1 FRED D. SMITH SOIL CONSULTING, INC. September 1, 2010 Mr. Selden Taylor Stocks and Taylor Construction PO Box 2147 Washington, NC 27.889 Subject: Report of a Soil Evaluation for Stormwater Treatment Ponds Family Dolly Site Washington, NC Dear Mr. Taylor, EXPRESS SEP 21 2010 NC DENR This letter concerns the soil evaluation and soil permeability testing I performed at the above mentioned site. You authorized me to perform a soil evaluation of the native soils on the site. Specifically, you wanted to know the depth to the `seasonal high water table' and in -situ soil permeabilities of soil layers to design stormwater infiltration ponds at the site ( 15A NCAC 02H .1008 (d)) . You met me at the site and showed me the area and depths of the expected stormwater design. My work consisted of hand auger borings to observe and describe physical properties such as texture, color, structure, consistency, depth to seasonal (or perched) groundwater, parent material, and restrictive horizons. The borings were advanced into the desired test depth. One boring was advanced to the depth of groundwater. The Aardvark Soil Permeameter was used to obtain constant head in -situ permeability values. The test holes were allowed to soak so that the soil pores were saturated around the boring. The result is a saturated hydraulic conductivity of the soil layer at that depth in inches per hour (in/h). The results of the testing are shown on the attached Aardvark forms for two tests. Soil Descriptions Horizon Depth Texture I Color, consistency, structure, etc. inches A 0-13 Loamy sand Reddish brown 5YR 5/3 friable, granufar E 13-24 Loamy sand Strong brown 7.5YR 5/6 very friable, granular Bt 24.40 Light sandy clay loam Strong brown (7.5YR 518) friable, weak sub. blocky B3 40-44 Sandy loam Reddish yellow (7.5YR 6/8) very friable, weak granular C 44-58 Loamy sand Reddish yellow (7.5YR 716) very friable to loose granular C2 58-70 Loamy sand Reddish yellow (7.5YR 716) with whitish streaks of 72 C3 70.78 Sandy clay loam Light yellowish brown and light gray (IOYR 6/4 wisand loam lenses ' and IOYR 7/1) we; friable, massive u ne sou descriptions are m USUA terms such as sandy loam etc. Colors are denoted using a Munsell Soil Color Chart. QViLMVIObile (252) 908a369-Fax (2S2) 459.7798 Post Office Box 1175—Nashville, Nato Carolina 27856 F � � r �. t i f .. i ..Its � ' i... � � t .. � � � � 1 � � .. .. � � �! � .. A _ „• o �� i _ _ � _ .. �1 � ,. l• �I � ' Sep 01 10 11:35a Fred Smith 252.459-7-19t3 p.[ Conclusions Free water was found at a depth of about 78 inches beneath the surface. The C2 horizon is loamy sand that generally contains bright yellow colors that show evidence of streaking in the sands. Streaking is normally considered to be caused by rapid water movement, not static water. The seasonal high groundwater table probably lies just above the static groundwater table at a depth of 70 inches. The average permeability of the upper C horizon ai a depth of 48 inches below the surface was measured to be 56 inches per hoe. The average permeability of the lower Bt horizon at a depth of 38 inches below the surface was nwasured to be 22 inches per hour_ The individual results are found on each Aardvark form. I appreciate the opportunity to work with you on this project Please contact me if you have questions or need additional information. 9)9dially, Fred D. Smith Licensed Soil Scientist Percolation or Ksat Rates using Aardvark Soil Permeameter Perc Rate: min/in Ksat: 561n1h LR: gdsf Site: FAMILY DOLLAR Date: 8I3112010 Operator: FOS Boring Number: Soil Series: UNKNOWN Soil Horizon: C Boring Depth (In) i 48 Diameter of Hole(in): 3 Water Column Height (in): 0 Head Conversion Factor (HCF): 5 Boring Conversion Factor BCF : 2. Design Loading Rate a Kast 14.9a'eafety factor of 0.05 to 0.5 system dependent Boring Conversion actor (B ) _ (rad)squarecl/5.05 for Aardvark eservo r BCF of 4 in auger is 4.25 in diameter boring = 1 BCF of 3.25 In auger Is 3.6 In diameter boring = 1.65 BCF of 2.75 In auger Is 3.0 In diameter boring = 2.25 Head Conversion Factor (HCF) = Water Column HI Inches 18 inches, or Htcm/15cm Example is 3.5in boring with 7 in water column in boring, 0.5 in head drop over 45 minutes in a structuredclay loam soil F Value (Radcliffe and West, 0 Borehole diameter Texture 3.5 in 1 4.0 in 3.0 in Sands 0.107 0.124 0.09 Structured foams and clays 0.082 0.096 0.068 Unstructured looms and clay 0.048 0.067 0.041 Time TO Time x nme Hours Reservoir Reservoir Reservoir Percolation BCF lHCF I Percolation F value Ksot Design Loading 2400 hours 2400 hours Elapsed Elapsed Reading, in Reading In Change Rate minlin Rate from table = F 11P Rate Qdsf ti t+1 tN1)•ti dtleominthr hi h+1 h+1 hl dtldh Adjusted with a 0.10 dt dh P'HCFyBCF Safety Factor initial next initial neat P A P of Kest min hr In in In minlin minlin In/hr daf Example 0 : 0 8:43 45 0.75 14.5 14 0.5 90 1. 5 1.17 0.082 0.08 0.12 0 0 7.5 7.5 0 2.25 0.5 0 0.09 0.00 1 0.016667- 7.5 4,8 2.7 0.37037037 2.25 0.5 0 0.09 65.61 0.00 1 0.0166 7 4. 2. 2.1 0.476190476 2.25 0.5 0 0.09 51.03 0.00 1 0.016667 2.1 0 2.1 0,476190476 .25 0.5 0.09 51.03 0.00 0 0 0 2.25 0.5 0 0.09 0.00 0 0 2.25 0.5 0 0.0 0.00 0 _ _ _ _ _ 0 - 2.25 0.5 0- 0,09 0.00 - 0 2.25 0. 0 .0 0.00 0 2.25 0.5 0 0.09 0.00 STEADY STATE ARITHMETIC AVERAGE of last 3 readings 2.25.5 ::GI: 0.09 Pedon Description Depth lHorIzon Color Texture Structure Horizon Notes Site Notes: _ r, Percolation or Ksat Rates using Aardvark Soil Permeameter Perc Rate: min/in Ksat: 221N/H LR: gdsf its: FAMILY DOLLAR Date: 813112010 Operator: FDS Boring Number. 10=1 Soil Series: UNKNOWN Soli Horizon: C Boring Depth (in) : i 38 Diameter of Hole(in): 3 Water Column Height (in): O Head Conversion Factor (HCF): 1 0.5 Boring Conversion Factor BCF ; Deal n Leadin Rate - KsaN14.e0"safety factor of 0.03 to 0.8 system dependent Borng onversion Fac or C = ra squared! . or a vark Reservoir BCF of 4 in auger is 4.25 in diameter boring = 1 BCF of 3.25 in auger Is 3.5 in diameter boring = 1.65 BCF of 2.75 In auger Is 3.0 In diameter boring = 2.25 Head Conversion Factor (HCF) = Water Column Ht Inches /6 inches, or Htcm/15cm Example Is 3.5in boring with 7 In water column in boring, 0.5 in head drop over 46 minutes in a Structured ed clay loam soil a ue adclt a an est, 2000) Borehole diameter Texture 3.6 in 4.0 in 3.0 in Sands 0.107 0.124 0.09 Structured Ieams and clays 0.082 0.096 0.068 Unstructured foams and clay 0.048 0.057 0.041 Time TO Time x Time Hours Reservoir Reservoir Reservoir Pemolation BGF HCF Percolation F value Keel Design Loading 2400 hours 2400 hours Elapsed Elapsed Reading, In Reading In Change Rate (miMn) Rate from table - F(1113) Rate qdsf d t+1 tI+1)-tl dV00minlhr hl h+1 (h+1)-hi dt/dh Adjusted I with a 0.10 dt dh P'HCF)/BCF Safety Factor Initial next Initial next P Adj P of Ksat min hr In In in mirth minlin in/hr gdsf Example 8:00 8:4 .75 14. 1 1. 1.17 64 0. 82 7077 0.12 1 0.016667 9.1 9.1 0 2.25 0.6 0.09 0.00 1 0. 8 7.9 3 33 2 2 5.5 0 0.09 29.16 0.00 9 6.5 4.5 0.22 222 22 2.25 5 0 0.09 109.35 0.00 7 6.5 .5 0.09 .87 0.00 5 5. 1 5 1 2.25 0.5 0 0.09 24.30 0.00 .5 0. 25 4.1 2.9 1.2 1 1.25 .25 0.5 0 0. 19.44 0.00 2. 5 1.4 11.071428571.12.251 0.5 -0 .0 - 22.68 0.00 1.5 1 0.025 1 1.5 1 0 1.5 1 2. 5 0.5 0 0.09 4.3 0,00 0 1 1 0 1 0.09 0.00 STEADY STATE ARITHMETIC AVERAGE of last 3 readln s 2.25.5 3>a7: 0.09 :.3: Z >: Pedon Descri tion Depth JHorlzon Color Texture Structure Horizon Notes Site Notes: Sep 01 10 11:36a Fred Smith 252-459-7798 p.5 110fdVC14 50i/Pnfrrnornfn- /-7;4Cld SC17C1701 C `1 { \ '*� waref1�il,;rl7olt �ia�dva�k 5y5/elm /nfemafionaf, LLG P.O, I3ox 41-f5 5haion, Git30664 aordvaiksy�er�inis/iofi yoi/. c nr� Tar -Pamlico Stormwater Rule 15A NCAC 2B .0258 Last Modified 911912010 Coastal Plain of the Tar -Pamlico River Basin: Includes Greenville and Washington as well as Pitt and Beaufort Counties Total Nitrogen and Total Phosphorus Loading Calculation Worksheet (Automated) Project Name: Famitv Dollar Washington Date: 911912010 By: Pamlico Engineering Services, PLLC Checked By: Marie Peedin, PE Directions (same for pre -development and post -development tables): > Enter the acres of each type of land cover in the green boxes. The spreadsheet will calculate all of the values in light blue. > Compare total areas of development in pre- and post- tables for consistency (bottom of column (2)), and also for consistency with the site plans. If all of these values are not the same, there is an error that must be corrected. > Unless drainage onto the development from offsite is diverted around or through the site, offsite catchment area draining in must be included in the acreage values and treated. Pre -development: f(6) a •.,,y..'-(7) .. �T e of Land Cover yp , Area S.M.SM.Formula Average EMC ,a Column, t , I- Average FMC+,Column "�- 4�•; _ -. •. .� acres I'0:51+9.17:..-ofTN'm L - ^.4 toLTP"m 2fc.3t6' Transportation Impervious 1.31 2.60 0.34 0.19 0.02 Roof Impervious I - 1.31 1.95 0.00 0.11 0.00 Managed pervious 1.31 1.42 1.93 0.28 0.38 ' lManaged�pervious 1.31 4.23 0.00 1.23 t Bind)^"^'"""^""` 0.00 Manned :pervious ` --t+w 1.31 2.04 0.00 0.62 0.00 (pasture) + t .,a I• -_ '�,1Wooded pervious "`"'N 1.31 0.95 0.00 0.14 0.00 F.racUon Impen loos (1) `;a'� 0.09 t , e4 ri,{,'TN Loading :l3oading „ry (lb/yr).= 2.27 /Yr),= 0.41 4 Total Areu ufDevelopment1 gj L14 v V TN Fxp Coif. TP Fip.Xoeff. , Y+ni 1'99 0.36 Post -development: .t(3)i, t "'` ;If Type of Land Cover ,,,y, n All t,Area S Mi+Formula Average EMC• ' Column' Average EMCt u Column; " •" 0.5I +9.11..""ofTN,in L",.2:+3.^..4 :of,TP`m L,I'23"^6 �ransportat o impervious "I", T 6.58 2.60 9.40 0.19 i 0.69 Roof Ira pervious 6.58 1.95 2*69 0.11 0.15 >_'". Managed pervmus d � 6.58 1.42 3.55 0.28 0.70 - Woodedpernons+ram .._ 6.58 0.94 0.00 0.14 0.00 Fraction -I P) 0.67 �7 N Loading -: Goading ,j-'- 14 4.� , w ,„-�s.� yr� _ 15.65 1.54 Td(al Area of Development = ' 1.14 - TN Fxp' Coeft TP Exp Coeff. a 13.73 s I. •. 1.35 Note: The nutrient loading goals are 4.0 Ib/ac/yr for 7N amd 0.4 Ib/ac/yr for TP. If the post -development nutrient loading is below these levels, then no BMP is necessary. Otherwise, the next worksheet calculates post-developnient'IN and IT loadings after BMPs are, installed. Tar -Pamlico Stormwater Rule 15A NCAC 28.0258 Coastal Plain of the Tar -Pamlico River Basin: Includes Greenville and Washington as well as Pitt and Beaufort Cnnnties Last Modified 5/23/03 BMP Removal Calculation Work.Sheet (Automated) Project Name: Family dollar Washington Date: 91192010 By: Pamlico F.nRmeerinp Services, PLLC Checked By: More Pcedin, PB Directions: > It may be advantageous to split the development into separate catchments to be handled by separate BMPs. The tables below allow the development to be split into as many as fhree catchments, and can be copied for greater than three. N(YTE: Unless mnoff flowing onto the development from ofl'site is routed separately around or duough the site, the offside catchment area draining in must be included in the acreage values of the appropriate land uses) and treated. > Above each table: Enter the catchment acreage in the lop green blank. Based on a comparison of the post -development TN and TP export coefficients you calculated above to the rule requirements of 4.0lb/ae/yr TN and 0.4 Ib/uc/yr TP, select BMP(s) from the list for heafiug lire cetichmenl runoff. Enter the chosen BMI'(s) nutrient removal taus in due green blanks. Df more than one BMP is m be used in series, the combined removal rates will be calculated automatically in the blue blanks. > Catchneut Tables: Enter the acres of each type of land cover in the green boxes. The, spreadsheet will calculate all of the light blue boxes. NOTE: Compare the'l'oml Catchment Acreage for the Development (final fable) to the value you established in the pre-BMP worksheet tables, and also to the siltplans, for consistent'_ All of these values need to be the same rF>»,i 'dx , +^i4 ry iMe.M1;r� 6 ,si .' i 4 r G'•^� ti `n0 DestgStandard rt i BMP ° "Wit Detection P nd - 25 40 NC BMP Manual Nutrient , Stormwater Wetli nd% 1Y 40 35 NC BMP Manual Sand Fitter: ar Removal 35 45 NC 8MP Manuel rya'-Baoreteatinn '�''T Rates ,. 1 : ^r. 35 45 NC BMP Manual t/,v y „Ir, nqP .;.,Grass Svvnlesb• 20 20 NC BMP Manual --Vegetated Ndfer Strip w/x ` Level S 'reader' 20 35 NC BMP Manual i Sa./1a 1 ` Dry Detention 10 10 NC BMP Manual Calchment 1: Tool acreage of catchment l- Ield ac Post BN1P's TN removal rate20 % First BMPs TP removal rate - Second BMPs TN removal rate - 35 - % Second BMP's TP removal rate - .; 45"'^"- Third BMPs TN removal rule =0 % Third B1,IP's TP removal"'m,,`a ,�., TOTAL TN REMOVAL RATE = 48 % TOTAL TP REMOVAL RATE = 56 b� pi la.(3) If la "Y (q) n a,' n "' (S) Type of Land Corer Catchment S.M..Formula 'Nverage EMC;, Column F,MC 'Column .';T"'+" _ GNeren e 1 11.51"+'lie ^oG9'Y m 1 1TTvervge 9 2 3 4^ "of 1'P. m C, 2e3 •: ti transportation impervious.'-' "1,La ,i>CF 7frP^a9;v' df:L;"F:1..i 6.58 2.60 9.40 0.19 41.69 -rr y?R��mpenious 6.58 1.95 2.69 0.11 0.15 >--•ManugeJ pervmy nF2x.� 6.58 L42 2.61 LT y. 0.28 0.52 Woiided pervuousr° i-'+ 6.58 0.94 0.00 0.14 0.00 1 6 r' -a Area taken up by BMP �- 6.58 1.95 1.28 0.11 0.07 Fracbnm_Imprmous (1) g67 _ ` Pre BMP TN Pre-BMPTP • , u ^ + 7 •r , d Ib/ r)„_, 16.00 -_ .. 1.43 1 1 , l I ot., Nreu of Development 1.14 -----` Pr�BA1P TN 14.03 Pro-BNIP,_T�P ^Tw . Fx dirt Ib/ac/ r p ( _ y) ti .. _. Lx- 1 (Ih/ac/yr) 1.25 ' ` _Post BMP.IjY (Ib/yr)= 832 Post -BM 1. Tp >=Load (Ib/yr)_ 0.63 a,r-,,w7.;:"r^4a-*.^d1+r 'h -�,-.,..-..� = .. "�""•':'L"., Post BMPTN care: ._. 730 SL Post BMP,TP 0.55 . Export (Ib/adyr) Esport`(Itile`dy`r) Tar -Pamlico Stormwater Rule 15A NCAC 2B .0258 Weighted Average of Nutrient Loudinys from the Catchments: Last Modified 5123/03 Catchment Post BMI { Post BMP ,i t' Fps r �Acrwgc TN l.oadmg� 'DTP I oadmgj Ib/acf r �, -' Ib/nc/ r -- `, Catchment 1: 1.14 7.30 0.55 t ° 'Catchment "` 2'`�,' 0.00 0.00 0.00 ...r.. i c, i tr.,'-X'� " de. n "'Catchment 3l<.' i+�: �"�' 41.00 0.00 0.00 TOrx FOR Dh VCLOPNIM 1.14 7.30 0.55 Note: The nutrient loading goals are 4.0 Ih/ac/yr for TN and 0.4 Ib/ac/yr for TP. If the post -development nutrient loading is below these levels, then the BMPs planned are adequate. Otherwise, additional BMPs and/or modifications in development plans are required. Culvert Report Hydraflow Express Extension for AutoCAD® Civil 3D® 2009 by Autodesk, Inc. Pipe 1 Invert Elev Dn (ft) = 6.50 Pipe Length (ft) = 92.50 Slope (%) = 0.18 Invert Elev Up (ft) = 6.67 Rise (in) = 12.0 Shape = Cir Span (in) = 12.0 No. Barrels = 1 n-Value = 0.012 Inlet Edge = Sq Edge Coeff. K,M,c,Y,k = 0.0098, 2, 0.0398, 0.67, 0.5 Embankment Top Elevation (ft) = 7.96 Top Width (ft) = 92.00 Crest Width (ft) = 100.00 Elev 011 8.00 7.50 7.00 6.50 <Name], Friday, Sep 17 2010 Calculations Qmin (cfs) = 1.79 Qmax (cfs) = 1.79 Tailwater Elev (ft) = 0.00 Highlighted Qtotal (cfs) Qpipe (cfs) Qovertop (cfs) Veloc Dn (ft/s) Veloc Up (ft/s) HGL Dn (ft) HGL Up (ft) Hw Elev (ft) Hw/D (ft) Flow Regime = 1.79 = 1.79 = 0.00 = 3.86 = 2.43 = 7.07 = 7.56 = 7.60 = 0.93 = Outlet Control Hw Depth (it) 1.33 6.00 0 10 20 - Cc CuHert ,1U 4U bu bll N 8u 90 - HGL - Enbank t :< 0.33 -0.17 -0.67 100 110 120 130 140 Reach (it) Inlet Report HydraOow Express Extension for AutoCAD® Civil 3D® 2009 by Autodesk, Inc. CB 1 Combination Inlet Location = Sag Curb Length (ft) = 3.00 Throat Height (in) = 6.00 Grate Area (sqft) = 6.00 Grate Width (ft) = 2.00 Grate Length (ft) = 3.00 Gutter Slope, Sw (ft/ft) = 0.050 Slope, Sx (ft/ft) = 0.020 Local Depr (in) = 0.50 Gutter Width (ft) = 1.50 Gutter Slope (%) = -0- Gutter n-value = -0- M di ensions in feet 0.2 Calculations Compute by: Q (cfs) Highlighted Friday, Sep 17 2010 Known Q = 1.79 Q Total (cfs) = 1.79 Q Capt (cfs) = 1.79 Q Bypass (cfs) = -0- Depth at Inlet (in) = 2.40 Efficiency (%) = 100 Gutter Spread (ft) = 7.92 Gutter Vel (ft/s) = -0- Bypass Spread (ft) = -0- Bypass Depth (in) = -0- �. i -' ' �` )�. ., Channel Report Hydraflow Express Extension for AutoCAD® Civil 3DO2009 by Autodesk, Inc Swale 1 Triangular Side Slopes (z:1) = 3.00, 3.00 Total Depth (ft) = 2.00 Invert Elev (ft) = 6.00 Slope (%) = 0.50 N-Value = 0.030 Calculations Compute by: Known Q Known Q (cfs) = 1.79 Elev (ft) Section 9.00 8.50 8.00 7.50 7.00 6.50 6.00 5.50 2 4 6 8 Reach (ft) Friday, Sep 17 2010 Highlighted Depth (ft) = 0.63 Q (cfs) = 1.790 Area (sqft) = 1.19 Velocity (ft/s) = 1.50 Wetted Perim (ft) = 3.98 Crit Depth, Yc (ft) = 0.47 Top Width (ft) = 3.78 EGL (ft) = 0.67 10 12 14 16 Depth (ft) 3.00 2.50 2.00 1.50 1.00 0.50 0.00 -0.50 } \. ��/ a 1 .1 � • � %1 ,�..-�, �. , Channel Report Hydraflow Express Extension for AutoCAD® Civil 3D® 2009 by Autodesk, Inc Swale 2 Triangular Side Slopes (z:1) = 3.00, 5.00 Total Depth (ft) = 2.00 Invert Elev (ft) = 6.00 Slope (%) = 0.80 N-Value = 0.030 Calculations Compute by: Known Q Known Q (cfs) = 3.60 Friday, Sep 17 2010 Highlighted Depth (ft) = 0.66 Q (cfs) = 3.600 Area (sqft) = 1.74 Velocity (ft/s) = 2.07 Wetted Perim (ft) = 5.45 Crit Depth, Yc (ft) = 0.56 Top Width (ft) = 5.28 EGL (ft) = 0.73 Elev (ft) Section 9.00 8.50 8.00 7.50 40 7.00 6.50 6.00 5.50 2 4 6 8 10 12 14 16 18 20 Reach (ft) Depth (ft) 3.00 2.50 2.00 1.50 1.00 0.50 0.00 _n �n SECTION 02920 LAWNS AND GRASSES PART GENERAL 1.01 SECTION INCLUDES A. Work shall include, but not be limited to, the following: I. Surface preparation of subsoil. 2. Placing topsoil. 3. Addition of lime and fertilizer. 4. Seeding. 5. Maintenance to produce a permanent stand of grass. 1.02 PAYMENT PROCEDURES A. Base bid for the work on the specified quantities of lime, fertilizer, and seed. After the speed soil tests have been made, Engineer may vary specified quantities. Should the actual quantities applied in the field vary appreciably from those specified, an adjustment in the contract price may be made. 1.03 REFERENCES A. N.C. Department of Agriculture - NCDA B. U.S. Department of Agriculture - USDA 1.04 PERFORMANCE REQUIREMENT A. Grassed area shall be considered established when it presents a green appearance from eye level 50 feet away and the grass is vigorous and growing well in each square foot of seeded area. It is not required that the seeded area be thick and heavy as an old established lawn. B. Should the permanent seed not germinate and produce a strand of grass, reseed affected areas until a permanent stand is established. 1.05 SUBMITTALS A.. Not less than 6 weeks prior to seeding, obtain representative soil samples from areas to be seeded and deliver the properly packaged samples with an information sheet for each sample properly filled out to the Soils Division of the NC Department of Agriculture or a private laboratory. Based on the test results, submit to the Engineer a recommendation as to the quantity and type of lime, fertilizer and seed for the area covered by the test. 1.06 QUALITY ASSURANCE A. Quality of fertilizer, lime, and seed, and operations in connection with the furnishing of this material, shall comply with the requirements of the N.C. Fertilizer, Lime and Seed Law; and with the requirements of the rules and, regulations adopted by the NC Department of Agriculture in accordance with the provisions of the said law. B. Seed containers shall bear an official "Certified Seed" label as inspected by the N.C. Crop Improvement Association. C. Packages for soil conditioners and fertilizer shall bear manufacturer's guaranteed analysis. 02920-1 Lawns & Grasses D. Do not apply lime, fertilizer or seed in strong wind, when the soil is extremely wet, or otherwise unworkable. No rolling shall be done if precipitation after seeding would make the operation detrimental to the seed bed. 1.07 DELIVERY, STORAGE, AND PROTECTION A. Deliver grass seed mixture in sealed containers showing percentage of seed mix, year of production, net production, net weight, date of packaging, and location of packaging. B. Deliver fertilizer in waterproof bags showing weight, chemical analysis, and name of manufacturer. 1.08 MAINTENANCE SERVICE A. Maintain seeded areas until grass is well established and exhibits a vigorous growing condition for a minimum of two cuttings. Mow grass at regular intervals to a maximum height of 3 inches. Hand clip where necessary. B. Control growth of weeds. Apply herbicides in accordance with manufacturer's instructions. C. Water areas seeded between May 1 and July 15 at such intervals as to maintain the seeded area in a moist condition until the grass is established and accepted by the Engineer. Provide equipment to transport and distribute the water to the seeded areas. Areas seeded between September 1 and November 1 need not be irrigated beyond the initial watering specified above except that the Contractor may apply water at his own discretion. PART2 PRODUCTS 2.01 MATERIALS A. Topsoil: Fertile, agricultural soil, typical for locality, capable of sustaining vigorous plant growth, taken from drained site; free of subsoil, Gay or impurities, plants, weeds, and roots; pH value of minimum 5.4 and maximum of 7.0. B. Lime: Ground Dolomitic agricultural limestone, not less than 85 percent total carbonates, ground so that 50 percent passes 100 mesh sieve and 90 percent passes 30 mesh sieve. Coarser material will be acceptable, provided the specified rates of application are increased proportionately on the basis of quantities passing No. 100 mesh sieve. C. Fertilizer. Mixed, commercial, fertilizer containing 10-10-10 percentages of available nitrogen, phosphoric acid, and potash respectively, plus superphosphate with 20 percent P2O5 content. Fertilizer shall be dry, in granular (pellet) form, shall be delivered to the site in the manufacturer's original bag or container which shall be plainly marked as to formula. D. Seed: Fresh seed guaranteed 95 percent pure with a minimum germination rate of 85 percent within one year of tests. Provide the following seed mixtures with lime and fertilizer in disturbed areas including NCDOT Rights -of -Way: Lawns & Grasses 02920-2 Job NO: Mo/Day/Yr 1. Temporary Seeding Planting Dates Grass Type Pounds/Acre Dec. 1 -Apr. 15 Rye (Grain) 120 Kobe Lespedeza 50 Apr. 15 - Aug. 15 German Millet 40 Aug. 15 - Dec, 1 Rye (Grain) 120 Lime 3,000 Fertilizer 10-10-10 800 Mulch Straw 4,000 2. Permanent Seeding Planting Dates Grass Tvce Pounds/Acre Sept. 1 - Oct. 31 Tall Fescue 200 Rye (grain) 25 Lime 4,000 Fertilizer 10-10-10 1,000 Mulch Straw 4,000 E. Matting / Erosion Control Fabric (ECF): Matting and ECF shall be heavy jute mesh over mulch held in place by staples. Commercially available ECFs may be used upon approval of the engineer. Approval of fabrics will require manufacturer's design data regarding velocity; ditch slopes, method of installation, decay cycle, repair techniques, and grass growth enhancement characteristics. F. Wire Staples: 16 gauge steel wire, with minimum of 3" top and 4" long legs. G. Mulch: Threshed straw of oats, wheat, or rye; free from seed of obnoxious weeds; or clean salt hay. Straw which is fresh and excessively brittle or straw which is in such an advanced stage of decomposition as to smother or retard growth of grass will not be acceptable. H. Water: Water shall be free from substances harmful to growth of grass. PART 3 EXECUTION 3.01 PREPARATION OF SUBSOIL A. Complete operations in the area to be seeded and prepare subsoil to eliminate uneven areas and low spots. Bring surface to the approximate design contours. B. Scarify subsoil to a depth. of 3 inches. Remove weeds, roots, stones and foreign materials 1-1/2 inches in diameter and larger. 3.02 PLACING TOPSOIL A. Place topsoil during dry weather and on dry unfrozen subsoil. B. Spread topsoil to a minimum depth of 4 inches. Remove vegetable matter and foreign non -organic material from topsoil'while spreading. Grade surface to provide positive drainage and prevent water ponding. Lightly compact topsoil with at least one pass of a cultipacker or similar equipment 02920-3 Lawns 8 Grasses C. Maintain the finished surfaces by protecting, and replacing topsoil and subsoil as necessary until the area is accepted under the contract. 3.03 APPLICATION OF LIME A. Liming shall be done immediately after grading has reached the fine grading stage, even though actual seeding may not be done until several months later. B. Spread lime evenly by means of a mechanical distributor. C. When lime is distributed by commercial liming dealers, sales slips showing the tonnage delivered shall be filed with the Engineer and shall show the full tonnage required for the acres treated. D. Incorporate lime in the top 2 to 3 inches of soil by harrowing, disking, or other approved means. 3.04 APPLICATION OF FERTILIZER A. Spread fertilizer not more than 2 weeks in advance of seeding. B. To verify application rate, determine acreage to be fertilized and provide Engineer with total weight of fertilizer applied to the area. C. Provide mechanical spreader for even distribution and spread half of the rate in one direction, and the other half at right angles to the first. Mix thoroughly into upper 2 to 3 inches of soil by disking, harrowing or other approved methods. 3.05 SEEDING A. Accomplish seeding by means of an approved power -drawn seed drill, combination corrugated roller -seeder, approved hand operated mechanical seeder, or other approved methods to provide even distribution of seed. B. Do not seed when ground is excessively wet or excessively dry. After seeding, roll area with a roller, not less than 18 inches in diameter and weighing not more than 210 pounds per foot of width. Upon completion of rolling, water area with a fine spray. C. Immediately following seeding apply mulch or matting. Do not seed areas in excess of that which can be mulched on same day. D. Apply water with a fine spray immediately after each area has been mulched. Saturate to 4 inches of soil'depth 3.06 MULCHING AND MATTING A. Apply mulch or matting as required to retain soil and grass, but no less then the following: 1. Slopes from 0 to 20 percent by spreading a light cover of mulch over seeded area at the rate of not less than 85 lbs. per 1000 sq. ft. 2. Slopes greater than 20 percent mulch with matting. Pin matting to the ground with wire staples at 5 foot intervals, immediately after seeding. 3. Use tack to prevent disruption of mulch. B. For tack use an asphalt tie -down of emulsified asphalt grade AE-3 or cut -back asphalt grade RC-2 or other approved equal. The application rate shall be 0.10 gal/sy (11 gal / 1000 sq ft).,An approved jute mesh or net may be used in lieu of tacking straw mulch. Lawns & Grasses 02920-4 Job No: Mo/DayNr C. Other types of mulch and anchoring methods may be used upon approval by the Engineer. 3.07 PROTECTION A. Protect seeded areas from damage by barricades, signs, and other appropriate means. Maintain and protect slopes from weather damage. END OF SECTION 02920-5 Lawns & Grasses ror MNX use UNLY Reviewer: North Carolina Department of Environment and ®rA svcnm Natural Resources BJC®ENR Request for Express Permit Review Tim Confirm: FILL-IN all the information below and CHECK the Permit(s) you are requesting for express review. FAX or Email the completed form to Express Coordinator along with a completed DETAILED narrative site plan (PDF file) and vicinity map (same items expected in the application package of the project location. Please include this form in the application package. • Asheville Region -Alison Davidson 818-296-4698;alison.davidson(dncdenr.gov • Fayetteville or Raleigh Region -David Lee 919.7914203; david.lee(a%ncdenr.gov • Mooresville & -Patrick Grogan 704-663.3772 or pairick.groganfincdenr.gov • Washington Region -Lyn Hardison 252-946-9215 or Ivn.hardison(g ncdenr gov • Wilmington Region -Janet Russell 910-350-2004 orLanet.russel!@ncdencgov NOTE: Project application received after 12 noon will be stamped in the following work day Project Name: FAMILY DOLLAR WASHINGTON County: BEAUFORT Permits of request SW SW SW SW SW Applicant: BARNES BOYKIN Company: EASTERN PRIDE. INC. Address: 2405F NASH ST City: WILSON, State: NC Zip: 27896 Phone: -, Fax: _ — Email: s@ Physical Location:John Small Ave. and Bonner Street Project Drains into JACKS CREEK waters -Water classification CNSW (for classification see-http:/m2o.enr.state.nc.us/bims/reports/reportsWB.html) Project Located in TAR PAM River Basin. Is project draining to class ORW waters? N , within Y2 mile and draining to class SA waters N or within 1 mile and draining to class HQW waters? N I EXPRESS Engineer/Consultant: PAMLICO ENGINEERING SERVICES, Company: MARIE PEEDIN EXPRESS a� Address: 128ABBEY LANE City: WASHINGTON, State: NC Zip:27889-SEP 2� Z�j(! Phone: 252-945-2983, Fax: 252-974-7618. Email: PESPLLC@EMBARQMAILCOM SECTION ONE: REQUESTING A SCOPING MEETING ONLY ❑ Scoping Meeting ONLY ® DWQ, ❑ DCM, ® DLR, ❑ OTHER: ntl%i ®F.1119rb SECTION TWO: CHECK ONLY THE PROGRAM (S) YOU ARE REQUESTING FOR EXPRESS PERMITTING ❑ 401 Unit ❑ Stream Origin Determination; _ # of stream calls - Please attach TOPO map marking the areas in questions ❑ IntermittentlPerennial Determination: _ # of stream calls - Please attach TOPO map marking the areas in questions ❑ 401 Water Quality Certification ❑ Isolated Wetland (_linear It or _acres) ❑ Riparian Buffer Authorization ❑ Minor Variance ❑ Major General Variance 3C-AUr:--)C (I ® State Stormwater ❑ General ❑ SFR, ❑ SFR < 1 ac. ❑Bkhd & Bt Rmp, ❑ Clear & Grub, ❑ Utility ❑ Other ❑ Low Density ❑ Low Density -Curb & Gutter — # Curb Outlet Swales ❑ Off -site [SW _ (Provide permit #)] ❑ High Density -Detention Pond _ # Treatment Systems ❑ High Density -Infiltration _ #Treatment Systems ® High Density -Bio-Retention 1 # Treatment Systems ❑ High Densily-SW Wetlands _ # Treatment Systems ❑ High Density -Other _ # Treatment Systems / ❑ MOD:❑ Major ❑ Minor ❑ Plan Revision ❑ Redev. Exclusion SW (Provide permit #) ❑ Coastal Management ❑ Excavation & Fill ❑ Bridges & Culverts ❑ Structures Information ❑ Upland Development ❑ Marina Development ❑ Urban Waterfront ® Land Quality ® Erosion and Sedimentation Control Plan with2-acres to be disturbed.(CK # <h�y r� (for DENR use)) t 6 `, SECTION THREE - PLEASE CHECK ALL THAT IS APPLICABLE TO YOUR PROJECT (for both Scoping and express meeting request) Wetlands on Site ❑ Yes ® No Wetlands Delineation has been completed: ❑ Yes ® No US ACOE Approval of Delineation completed: ❑ Yes ® No Received from US ACOE ❑ Yes ® No Buffer Impacts: ® No ❑ YES: _acre(s) Isolated wetland on Property ❑ Yes ® No 404 Application in Process wl US ACOE: ❑ Yes ® No Permit For DENR use only Fees I'nfor multi lepermits: Check# j n, - I Total Fee Amount $ -0, SUBMITTAL DATES Fee 1 SUBMITTAL DATES Fee CAM, $ Variance (❑ Mal; ❑ Min) $ SW (❑ HD, ❑ LD, ❑Gen) - $ .3c� �.SL 401: $ LQS $ r b�l Lt., 4 L. Stream Deter,_ $ NCDENR EXPRESS March 2009 u'OOS 196u• 1: STOCKS & TAYLOR CONSTRUCTION, INC./P.O. BOX 2147 Check#: 5196 Date: 0911712010 Amount: 4,000.00 Vendor: 211 NCDENR 005196 Invoice# Job/Description Balance Retain Discount This Check 09172010-11 10008 Family Dollar - Washi 4,000,00 4,000,00 EXPRESS SEP 21 ZM NC ®ENR .�T E EP 2$1=201B BOOK 9 4 8 PAGE 3 ti 0 cp� PREPARED BY: HC DENR RODMAN, HOLSCHER, FRANCISCO & PECK, P. A., Attorneys at Law (L• 130 E. 2nd St., P. 0. Box 1747 1' TATE OF NORTH CAROLINA Washington, NC 27889 �OUNTY OF BEAUFORT Telephone: (919) 946-3122 THIS DEED made and entered into this the /"? day of mber, 1991, by THE BOARD OF EDUCATION OF THE WASHINGTON CITY NISTRATIVE UNIT, a body politic and corporate (also known as BOARD OF SCHOOL TRUSTEES OF THE CITY OF WASHINGTON, INC., a h Carolina corporation, and THE BOARD OF SCHOOL TRUSTEES OF TOWN OF WASHINGTON, a North Carolina corporation, and THE ) OF TRUSTEES OF THE WASHINGTON CITY ADMINISTRATIVE UNIT OF T COUNTY, NORTH CAROLINA), Grantor, to ROBERT E. E, SR. AND WIFE, SUSAN S. DEATHERAGE AND WILLIAM DEATHERAGE AND WIFE, LYNN W. DEATHERAGE, as tenants by e entireties, Grantees; W I T N E S S E T H; That the Grantor, in consideration of the sum of Ten and 0/100 Dollars ($10.00) and other valuable considerations to it aid by the Grantees, the receipt whereof is acknowledged, has given, granted bargained, sold and does hereby convey unto the laid Grantees,' ROBERT E. DEATHERAGE, SR. AND WIFE, SUSAN S. DEATHERAGE, their heirs and assigns, a one-half (1/2) undivided interest, and WILLIAM STANHOPE DEATHERAGE AND WIFE, LYNN W. EATHERAGE, their heirs and assigns, a one-half (1/2) undivided NooMAN. 11OISCHPH. nterest, in and to that certain tract or parcel of land, lying 2ANC;SCO h PECK. P.A. 4TlONN CVM1 Ai Aw and being in the City of Washington, County of Beaufort, State of North Carolina, more particularly described as follows: I I BOOR 948PAGE 321 BEGINNING at a point, said point being indicated by the letter "A" on the map referred to below; and said point being the intersection of the Northern right-of-way line of East Fourth Street and the Western right-of-way line of Harvey Street; and running thence from said beginning point so located with the Northern right-of- way line of East Fourth Street, North 610 56' 43" West 629.97 feet to a point, said point being located in the Eastern sideline of Bonner Street; thence with the Eastern sideline of Bonner Street, North 280 13' 40" East 88.72 feet to a point; thence South 610 46' 20" East 160.00 feet to an iron pipe; thence North 280 13' 40" East 52.50 feet to an iron pipe; thence South 610 46' 20" East 50.00 feet to an iron pipe; thence North 280 13' 40" East 52.50 feet to an iron pipe; thence North 610 46' '20" West 210.00 feet to a point in the Eastern right-of-way line of Bonner Street; thence with the right-of-way of Bonner Street, North 280 13' 40" East 200.15 feet to a point in the Southern right-of- way line of East Fifth Street (also known as John Small Avenue); and running thence South 600 45' 37" East 318.34 feet to an iron pipe; thence South 620 18' 54" East 313.24 feet to a point in the Western right-of-way line of Harvey Street; thence with the right-of-way line of Harvey Street, South 280 27' 26" West 389.31 feet to a point, the point of beginning, and containing a total area of 5.193 acres, according to that certain survey of Mayo and Associates Land Surveying dated October 8, 1991, a copy of said survey being recorded in the)Beaufort County Registry in Plat Cabinet /= Slide Reference is herein made to said survey and the same is incorporated herein for a more complete and adequate description. TO HAVE AND TO HOLD the same, together with all and singu- lar, the rights, ways, privileges and appurtenances thereto belonging or in -anywise appertaining unto the said Grantees, their heirs and assigns, ROBERT E. DEATHERAGE, SR. AND WIFE, SUSAN S. DEATHERAGE, a one-half (�) undivided interest, and WILLIAM STANHOPE DEATHERAGE AND WIFE, LYNN W. DEATHERAGE, a RODMAN. HOLSCHER. one-half (-�) undivided interest, in fee simple, but subject to FRANCISCO C PECK. P.A. AT O„„ETSA,,.AW any easements or rights -of -way of record in the Beaufort County W /.S IIINOTO N. NC Public I Registry. BOOK . 948PA6E 322 0 The Grantor covenants with the Grantees that it is seized in fee simple of said land above described and has good right and title to convey the same; that the same is free and clear of all liens and encumbrances, except the aforesaid easements or rights -of -way and 1991 Beaufort County Ad Valorem taxes, and that it will forever warrant and defend the title to the same against all lawful claims and demands. IN WITNESS WHEREOF, Grantor has caused this instrument to be executed in its. name by its C liftl(i MPW attested by its Secretary, and its corporate seal to be hereto affixed, all by proper authority duly given, this the day, and year first above written. THE BOARD OF EDUCATION OF THE WASHINGTON CITY ADMINISTRATIVE UNIT i• . BY: Chairman Alto ri0lsr,ns,.i:o: ATTEST: =` (Corporate Seal) Secretary ROOMAN. HOLSCHER.. RANCISCO 9 PECK. P.A. ATTORNCYL AT LAW WASIIINOTON. NC MSRMaps: Print Page 1 of 1 Send To Printer Back To MSR Maps Change to 11x17 Print Size Show Grid Lines Chancre to Landscape yds 100 2 300 V V Image courtesy of the U.S. Geological Survey ® 2010 Microsoft Corporation. Terms of Use Privacy Statement http://msrmaps.com/Printlmage.aspx?T=2&S=11 &Z=18&X=785&Y=9838... 9/ 17/2010 \ P 3 � 4? � ��8+. V r Ur 3� " �� 3 .31+�� ,S�Gir �j # f. •}ri Y I �V��lr � �1.. l �.. •.. ( 5 � e ro , �yJ+p�,. � .a,��. ` �� 'a""r r i1?. �, ..il �+� t�� 'h _ € , w ' its w. �.� Ig ; �� { a '-- a I � - ' I > , �-iD'`,�'', xw'�"'� Ah#" �a�-5.-. ✓ p` � I "� `L'� � 'a�T� � �- � r F ,o � s a' ✓� ��x �: vs e "", "t��aZ+ ��rr.. v S�iPo 4r{' � ,may. AaA, �.�� qi L ' ` + 3 ;• I y r Sin IS Sb � cy,.� � ��•� ,�. .F,�. 4 � _ "�i,. 9 M e �4•;r" t �� :.'s 3" `�� xq �. n rU: v �' 4§ �N�i � L � '� `gr `� I L kT,. �i+' ` �¢R 9 � i. �� j I I I';< 1 � � (' � v ,/�.•' 1 � I 4., --i' y. a 1) . I .v s,. _ � j � � vgy. _"+. ( % _ psilf(!'ryP" d# in.� m2 Point e 01/11/2010 18:28 2522370766 EASTERNPRIDEINC S0SID:0647965 Date Filed: 1/14/2010 8:32:00 AM ^� Elaine F. Marshall BUSINESS CORPORATION North Carolina Secretary of State CA2009317008I2 ANAL REPORT NAME OF BUSINESS CORPORATION: &astern Pride Inc. FISCAL YEAR ENDING: STATE OF INCORPORATION: NC SECRETARY OF STATE CORPORATE IDTRSMBER: 064790 NATURE OF BUSINESS: Real r fate develaryment/leusitrg REGISTERED AGENT: 17totnas, Charles A. RCGISTF.RED OFFK E MAUNG ADDRESS: 2005-FWest No:•,4 Street WiLron, NC 27896 EXPRESS XP ®CC99E c S REGISTERED OFFICR STREET ADDRESS: 1105•FWest mmi Street SEP 21 2.( 0 - --- . R9ltan, NC 278SK Wtlson Cmmry 'NC DENR SIG NATURF- OF THE NEW REGISTERED AGEtn; tIGNATURP. CONYPITUTES CONSENT TO THE APPOINTMENT PRINCIPAL OFFICE T.EIZPI•IONE NU),,1BER: r:51) 399-1964 PRINCIPAL OFFICE MAILING ADDRESS: 2eOS .Narh St. MI , Ste F Wilson NC Z789G PRINCIPAL OFFICE STREET ADDRESS: 2405-F West Nash Slreei INilscie, NC 2789; PRINCIPAL OFFICERS: Name: Charles nomm Mime: Battles B,vkln Title: President Title: Secretary Address: Address: 140.7-FWest NmhStreet ld'05-FWest Nulb4Street T1F ANNITAL REPORT MUST BE COMPLF_�'ED BY ALL, BUSWESS CORPORATIONS �A FORM MUST BE SIGN BY AN OPPICER Of -MCCitPORATI0t4 DATE TYPR OR PRINT NAME TYPE OR PRWTTaLE ANNUAL. TPORT PRE: 275 MAIL. TO: ;:mvWy of Rma • Cm[wminnp Oividm • Pml OfEw Box 29925 • Raleigh, NC 2mr.fi$" 1 � �y h1 1 , 4 Char-Meck Bioretention Design Guidance (Hahne, 2004) note: this is provided for you to see an alternative sizinq quideline EXPRESS SEP 21 2010 SIC WATER QUALITY VOLUME (WQv) Rv = runoff coefficient (Runoff/Rainfall) Rv = 0.05 + 0.009( 1) Where "I" = % Impervious ("Simple Method" - Schueler, 1987) NCDENR April 1999 WQv = 1.5"RvA 12 Fill in Values: "I" = F_6_61 Percent Impervious of Site "A" = 1.14 Acres Answer: WQv = 0.092 Ac. Ft ,i/ 3997 Cubic Feet Required �r GG Formula: Af = (WQv) (DO Where: ((k) (Hf+Df) (Tf)) Af = From Georgia Design Manuaf WQv = Section 3.2.3.6 Df = (Based on Darcy's Law) k = Hf = Tf = INNS] 0,67 , V= 4-10 53� �,Kl� Surface area of Rain Garden (S.F.) Water Quality Volume to be Captured Filter Bed Depth (2 feet minimum) permeability coefficient of filter media (use 1.0 ff/day for sandy -loam) Average height of water above filter bed (use 3 inches, which is half of 6" ponding depth) Design filter bed drain time in days (2 Days or 48 hours ) . Fill in Values: "k" =I 1 ft./day (1/2"/Hour) Df =1 2 Feet Hf = 6 inches Tf =1 21 Days Answer: Af = ( a,X 3� -1 �t 7,< 100 =3g7s Av, , 4912 Square Feet Required to detain 1.5" and 1 yr 24 hr Event lop 5A= szss 1 Z1 c& z v IK V = 4-156 G Water Draw Through Rate: Darcy's Equation: Q = (.0000232)'K'W( H/L ) Where: Q = Flow (Rate of Draw) through Bioretentioin Soil (cfs) K = Hydraulic Conductivity of soil ( Use 1"/Hour) A = Surface Area of Bio-Retention Area (SF) H = Height of Water above Drainage Pipe (Underdrain) L = Thickness of Soil Bed (Usually 4' ) Assume (H/L) - 1 Q = 0.114 cfs EXPRESS SEP 21 2010 Time to Drawdown water from Inundation to Saturation at Surface: GEC,' DENR Volume/Q: 21552 Seconds 6.0 Hours to Saturation Time to lower Water Table to 2.0 feet below surface: Assume 45% Porosity Volume = Area x Tx 0.45 4420.8 Cubic Feet 38793 Seconds 10.8 Hours to Lower Water 2' below surface Formulating Pre- & Post- Development Hydrographs utilize small watershed method & center -weighted storm (Malcom) Location Washington Return Period 1 year 1= _'� `4",70 in/hr (assumes Tc <= 5 min, check below) Cpre 0.41 (Rational C, see adjoining table) Cpost 0.75 A= ^a1fd"40 acre A- 49658I sf Rainfall in (6 hr Depth) Qpre= Qpost= Vol - Pre 2.2 1 4.0 cis is cf 3300 Vol - Post 8212 cf Tpre 18 min Tpost 25 min Time Q- pre Q-post min cfs cfs 0 0.00 0.00 1 0.02 0.02 2 0.07 0.07 3 0.15 0.15 4 0.26 0.26 5 0.39 0.40 6 0.55 0.57 7 0.72 0.76 8 0.91 0.97 9 1.10 1.20 10 1.29 1.44 11 1.47 1.69 12 1.65 1.94 13 1.80 2.20 14 1.94 2.46 15 2.05 2.70 16 2.13 2.94 17 2.18 3.16 18 2.20 3.36 19 2.18 3.54 20 2.13 3.69 21 2.05 3.82 22 1.94 3.92 23 1.81 3.98 24 1.69 4.01 25 1.57 4.01 26 1.46 3.98 27 1.36 3.92 28 1.26 3.82 29 1.18 3.69 30 1.09 3.54 31 1.02 3.37 32 0.95 3.19 33 0.88 3.03 34 0.82 2.87 35 0.76 2.72 36 0.71 2.58 37 0.66 2.45 38 0.61 2.32 39 0.57 2.20 EXPRESS SEP 21 2010 SIC ®ENR (total pre -development runoff volume) (total post -development runoff volume) Time of Concentration Check (Kirpich Tc Equation) Predevelopment L 204.4 R (Length of Overland Flow) S 0.18 RAt (average overland slope) tc 0.91 min bare soil tc 1 1.82 min grassed Post Development L 382 R (Length of Overland Flow) S 0.19 fUR (average overland slope) tc I 1.44 min bare soil tc 1 0.58 min asphalUconcrete Nate: Compare this to a 5 minute minimum. Time q- pre q-post tc 1 82 min grassed min ds cfs 40 0.53 2.09 41 0.49 1.98 42 0.46 1.88 43 0.43 1.78 44 0.40 1.69 45 0.37 1.60 46 0.34 1.52 47 0.32 1.44 48 0.30 1.37 49 0.28 1.30 50 0.26 1.23 51 0.24 1.17 52 0.22 1.11 53 0.21 1.05 54 0.19 0.99 55 0.18 0.94 56 0.17 0.89 57 0.16 0.85 58 0.14 0.80 59 0.13 0.76 60 0.13 0.72 61 0.12 0.69 62 0.11 0.65 63 0.10 0.62 64 0.09 0.58 65 0.09 0.55 66 0.08 0.53 67 0.08 0.50 68 0.07 0.47 69 0.07 0.45 70 0.06 0.43 71 0.06 0.40 72 0.05 0.38 73 0.05 0.36 74 0.05 0.34 75 0.04 0.33 76 0.04 0.31 77 0.04 0.29 78 0.03 0.28 79 0.03 0.26 80 0.03 0.25 81 0.03 0.24 82 0.03 0.23 83 0.02 0.21 84 0.02 0.20 85 0.02 0.19 86 0.02 0.18 87 0.02 0.17 88 0.02 0.16 89 0.02 0.16 90 0.01 0.15 91 0.01 0.14 92 0.01 0.13 93 0.01 0.13 94 0.01 0.12 95 0.01 0.11 96 0.01 0.11 97 0.01 0.10 98 0.01 0.10 99 0.01 0.09 100 0.01 0.09 101 0.01 0.08 102 0.01 0.08 Time Q- pre Q-post tc 1 82 min grassed min cts c/s I 103 0.01 0.07 104 0.01 0.07 105 0.00 0.07 106 0.00 0.06 107 0.00 0.06 108 0.00 0.06 109 0.00 0.05 110 0.00 0.05 111 0.00 0.05 112 0.00 0.05 113 0.00 0.04 114 0.00 0.04 115 0.00 0.04 116 0.00 0.04 117 0.00 0.04 118 0.00 0.03 119 0.00 0.03 120 0.00 0.03 121 0.00 0.03 122 0.00 0.03 123 0.00 0.03 124 0.00 0.02 125 0.00 0.02 126 0.00 0.02 127 0.00 0.02 128 0.00 0.02 129 0.00 0.02 130 0.00 0.02 131 0.00 0.02 132 0.00 0.02 133 0.00 0.02 Formulating Pre- & Post- Development Hydrographs utilize small watershed method & center -weighted storm (Malcom) Location Washington Return Period 10 year 1= •: ^.: `-�:•;: 8'95 in/hr (assumes Tc <= 5 min, check below) Cpre 0.41 (Rational C, see adjoining table) Cpost 0.75 A= ;;C+1-1'40 acre A- 49658 sf Rainfall '---." r4.64 in (6 hr Depth) Qpre= 4.2 cis Qpost-- 7.7 cf., Vol - Pre 1 3300 cf (total pre -development runoff volume) Vol - Post 8212 c/min (total post -development runoff volume) Tpre 9 1 Time of Concentration Check (Kirpich Tc Equation) Tpos 13 min Predevelopment L 204.4 ft (Length of Overland Flow) S 0.18 fUR (average overland slope) tc _ 0.91 min bare soil Time Q-pre Q-post tc 1.82 min grassed min cfs cfs� 0 0.00 0.00 Post Development 1 0.11 0.11 L 382 It (Length of Overland Flow) 2 0.44 0.45 S 0.19 ft/ft (average overland slope) 3 0.96 0.98 tc 1 1.44 min bare soil 4 1.59 1.68 tc 1 0.58 min asphalt/concrete 5 2.28 2.51 6 2.95 3.42 Note: Compare this to a 5 minute minimum. 7 3.52 4.35 8 3.94 5.25 9 4.16 6.07 10 4.15 6.75 11 3.92 7.26 12 3.49 7.57 13 3.04 7.65 14 2.65 7.51 15 2.31 7.15 16 2.01 6.59 17 1.76 5.96 18 1.53 5.39 19 1.33 4.87 20 1.16 4.40 21 1.01 3.98 22 0.88 3.60 23 0.77 3.25 24 0.67 2.94 25 0.58 2.66 26 0.51 2.40 27 0.44 2.17 28 0.39 1.96 29 0.34 1.77 30 0.29 1.60 31 0.26 1.45 32 0.22 1.31 33 0.19 1.18 34 0.17 1.07 35 0.15 0.97 36 0.13 0.87 37 0.11 0.79 38 0.10 0.71 39 0.09 0.65 Time Q-pre Q-post tc 1.82 min grassed min cfs cfs 40 0.07 0.58 41 0.06 0.53 42 0.06 0.48 43 0.05 0.43 44 0.04 0.39 45 0.04 0.35 46 0.03 0.32 47 0.03 0.29 48 0.02 0.26 49 0.02 0.24 50 0.02 0.21 51 0.02 0.19 52 0.01 0.17 53 0.01 0.16 54 0.01 0.14 55 0.01 0.13 56 0.01 0.12 57 0.01 0.10 58 0.01 0.09 59 0.01 0.09 60 0.00 0.08 61 0.00 0.07 62 0.00 0.06 63 0.00 0.06 64 0.00 0.05 65 0.00 0.05 66 0.00 0.04 67 0.00 0.04 68 0.00 0.03 69 0.00 0.03 70 0.00 0.03 71 0.00 0.03 72 0.00 0.02 73 0.00 0.02 74 0.00 0.02 75 0.00 0.02 76 0.00 0.02 77 0.00 0.01 78 0.00 0.01 79 0.00 0.01 80 0.00 0.01 81 0.00 0.01 82 0.00 0.01 83 0.00 0.01 84 0.00 0.01 85 0.00 0.01 86 0.00 0.01 87 0.00 0.01 88 0.00 0.00 89 0.00 0.00 90 0.00 0.00 91 0.00 0.00 92 0.00 0.00 93 0.00 0.00 94 0.00 0.00 95 0.00 0.00 96 0.00 0.00 97 0.00 0.00 98 0.00 0.00 99 0.00 0.00 100 0.00 0.00 101 0.00 0.00 102 0.00 0.00 Time Q- pre Q-post tc 1 82 min grassed min cfs ofs 103 0.00 0.00 104 0.00 0.00 105 0.00 0.00 106 0.00 0.00 107 0.00 0.00 108 0.00 0.00 109 0.00 0.00 110 0.00 0.00 111 0.00 0.00 112 0.00 0.00 113 0.00 0.00 114 0.00 0.00 115 0.00 0.00 116 0.00 0.00 117 0.00 0.00 118 0.00 0.00 119 0.00 0.00 120 0.00 0.00 121 0.00 0.00 122 0.00 0.00 123 0.00 0.00 124 0.00 0.00 125 0.00 0.00 126 0.00 0.00 127 0.00 0.00 128 0.00 0.00 129 0.00 0.00 130 0.00 0.00 131 0.00 0.00 132 0.00 0.00 133 0.00 0.00 Hyd/rographh Routing through Bioretention l 7i �N9w BIORETENTION CELL 1 Surface Area 0.11 ac Type Structure: Weir Surface Area 4722 sf Dimensions Average Depth 12 in length 5 Average Depth 1 ft width 2 Effective Storage Vol. 4 222 cf Total Length 14 % occupied by grate 0 Effective length 14 Surf. Infiltration Rate I-�1 L in/hr Height above soil 12 If Sandy Loam, 1 in/hr, Loamy Sand, 2 in/hr Height above soil 1.001 Volume lost to Infil 787 cfihr Number of Outlets 0 Max Depth Over Grate 0.47 CELL 1 ROUTING T me �lnflow `� Volume in Surf Vol Depth Overflow Exfilt Vol Out min Mntcis cf cf ft CIS cf cf 0 0.00 0 0 0.00 0.00 000 o on 1 0.02 1 1 0.00 0.00 0.99 0.99 2 0.07 4 4 0.00 0.00 3.94 3.94 3 0.15 9 9 0.00 0.00 8.81 8.81 4 0.26 16 16 0.00 0.00 13.12 13.12 5 0.40 24 26 0.01 0.00 13.12 13.12 6 0.57 34 47 0.01 0.00 13.12 13.12 7 0.76 45 79 0.02 0.00 13.12 13.12 8 0.97 58 124 0.03 0.00 13.12 13.12 9 1.20 72 183 0.04 0.00 13.12 13.12 10 1.44 86 256 0.05 0.00 13.12 13.12 11 1.69 101 344 0.07 0.00 13.12 13.12 12 1.94 117 448 0.09 0.00 13.12 13.12 13 2.20 132 567 0.12 0.00 13.12 13.12 14 2.46 147 701 0.15 0.00 13.12 13.12 15 2.70 162 850 0.18 0.00 13.12 13.12 16 2.94 176 1013 0.21 0.00 13.12 13.12 17 3.16 189 1190 0.25 0.00 13.12 13.12 18 3.36 202 1378 0.29 0.00 13.12 13.12 19 3.54 212 1577 0.33 0.00 13.12 13.12 20 3.69 222 1786 0.38 0.00 13.12 13.12 21 3.82 229 2002 0.42 0.00 13.12 13.12 22 3.92 235 2224 0.47 0.00 13.12 13.12 23 3.98 239 2449 0.52 0.00 13.12 13.12 24 4.01 241 2677 0.57 0.00 13.12 13.12 25 4.01 241 2905 0.62 0.00 13.12 13.12 26 3.98 239 3131 0.66 0.00 13.12 13.12 27 3.92 235 3352 0.71 0.00 13.12 13.12 28 3.82 229 3569 0.76 0.00 13.12 13.12 29 3.69 222 3777 0.80 0.00 13.12 13.12 L = &,34 �' 70&k Time, Inflow Volume in Surf Vol Depth Overflow E>�It Vol Out _ min cfs cf cf tt cfs cf cf 30 3.54 212 3976 0.84 0.00 13.12 1319 31 3.37 202 4165 0.88 0.00 13.12 13.12 32 3.19 192 4344 0.92 0.00 13.12 13.12 33 3.03 182 4512 0.96 0.00 13.12 13.12 34 2.87 172 4672 0.99 0.00 13.12 13.12 35 2.72 163 4822 1.02 0.00 13.12 13.12 36 2.58 155 4964 1.05 0.00 13.12 13.12 37 2.45 147 5098 1.08 0.00 13.12 13.12 38 2.32 139 5224 1.11 0.00 13.12 13.12 39 2.20 132 5343 1.13 0.00 13.12 13.12 40 2.09 125 5455 1.16 0.00 13.12 13.12 41 1.98 119 5561 1.18 0.00 13.12 13.12 42 1.88 113 5660 1.20 0.00 13.12 13.12 43 1.78 107 5754 1.22 0.00 13.12 13.12 44 1.69 101 5843 1.24 0.00 13.12 13.12 45 1.60 96 5926 1.25 0.00 13.12 13.12 46 1.52 91 6004 1.27 0.00 13.12 13.12 47 1.44 86 6077 1.29 0.00 13.12 13.12 48 1.37 82 6146 1.30 0.00 13.12 13.12 49 1.30 78 6210 1.32 0.00 13.12 13.12 50 1.23 74 6271 1.33 0.00 13.12 13.12 51 1.17 70 6328 1.34 0.00 13.12 13.12 52 1.11 66 6381 1.35 0.00 13.12 13.12 53 1.05 63 6431 1.36 0.00 13.12 13.12 54 0.99 60 6477 1.37 0.00 13.12 13.12 55 0.94 57 6521 1.38 0.00 13.12 13.12 56 0.89 54 6561 E3Kj 0.00 13.12 13.12 57 0.85 51 6599 1.40 0.00 13.12 13.12 58 0.80 48 6634 1.41 0.00 13.12 13.12 59 0.76 46 6667 1.41 0.00 13.12 13.12 60 0.72 43 6697 1.42 0.00 13.12 13.12 61 0.69 41 6725 1.42 0.00 13.12 13.12 62 0.65 39 6751 1.43 0.00 13.12 13.12 63 0.62 37 6775 1.43 0.00 13.12 13.12 64 0.58 35 6797 1.44 0.00 13.12 13.12 65 0.55 33 6817 1.44 0.00 13.12 13.12 66 0.53 32 6835 1.45 0.00 13.12 13.12 67 0.50 30 6852 1.45 0.00 13.12 13.12 68 0.47 28 6868 1.45 0.00 13.12 13.12 69 0.45 27 6881 1.46 0.00 13.12 13.12 70 0.43 26 6894 1.46 0.00 13.12 13.12 71 0.40 24 6905 1,46 0.00 13,12 13.12 72 0.38 23 6915 1.46 0.00 13.12 13.12 73 0.36 22 6923 1.47 0.00 13.12 13.12 74 0.34 21 6931 1.47 0.00 13.12 13.12 75 0.33 20 6937 1.47 0.00 13.12 13.12 76 0.31 19 6943 1.47 0.00 13.12 13.12 77 0.29 18 6947 1.47 0.00 13.12 13.12 78 0.28 17 6951 1.47 0.00 13.12 13.12 79 0.26 16 6954 1.47 0.00 13.12 13.12 TWO - nflow ,, Volume in Surf Vol Depth Overflow E>�It Vol Out min.R, nwcf§! " cf cf ff cfs cf cf 80 0.25 15 6955 1.47 0 00 13 19 1119 81 0.24 14 6957 1.47 0.00 13.12 13.12 82 0.23 14 6957 1.47 0.00 13.12 13.12 83 0.21 13 6957 1.47 0.00 13.12 13.12 84 0.20 12 6956 1.47 0.00 13.12 13.12 85 0.19 12 6954 1.47 0.00 13.12 13.12 86 0.18 11 6952 1.47 0.00 13.12 13.12 87 0.17 10 6949 1.47 0.00 13.12 13.12 Hydrograph Routing through Bioretention BIORETENTION CELL 1 Area ac Area sf Depth 14722 in Depth ff Storage Vol.cf urf. Infiltration Rate Din/hr Sandy Loam, 1 in1hr, Loamy Sand, 2 in/hr olume lost to Infil 787 cf/hr Type Structure: Weir Dimensions length 3 width 3 Total Length % occupied by grate 0 Effective length 121 Height above soil 1 12 Height above soil 1 1.001 Number of Outlets 0 Max Depth Over Grate CELL 1 ROUTING Time ry, , Inflow Volume in SurfVol Depth Overflow Exfilt Vol Out rain ° " cis' • cf cf ff cfs cf cf 0 0.00 0 0 0.00 0.00 0.00 0.00 1 0.11 7 7 0.00 0.00 6.81 6.81 2 0.45 27 27 0.01 0.00 13.12 13.12 3 0.98 59 73 0.02 0.00 13.12 13.12 4 1.68 101 160 0.03 0.00 13.12 13.12 5 2.51 151 298 0.06 0.00 13.12 13.12 6 3.42 205 490 0.10 0.00 13.12 13.12 7 4.35 261 738 0.16 0.00 13.12 13.12 8 5.25 315 1041 0,22 0.00 13.12 13.12 9 6.07 364 1392 0.29 0.00 13.12 13.12 10 6.75 405 1784 0.38 0.00 13.12 13.12 11 7.26 436 2206 0.47 0.00 13.12 13.12 12 7.57 454 2647 0.56 0.00 13.12 13.12 13 7.65 459 3093 0.66 0.00 13.12 13.12 14 7.51 450 3530 0.75 0.00 13.12 13.12 15 7.15 429 3946 0.84 0.00 13.12 13.12 16 6.59 395 4328 0.92 0.00 13.12 13.12 17 5.96 358 4673 0.99 0.00 13.12 13.12 18 5.39 323 4983 1.06 0.00 13.12 13.12 19 4.87 292 5262 1.11 0.00 13.12 13.12 20 4.40 264 5513 1.17 0.00 13.12 13.12 21 3.98 239 5739 1.22 0.00 13.12 13.12 22 3.60 216 5942 1.26 0.00 13.12 13.12 23 3.25 195 6124 1.30 0.00 13.12 13.12 24 2.94 176 6287 1.33 0.00 13.12 13.12 25 2.66 159 6433 1.36 0.00 13.12 13.12 26 2.40 144 6564 1.39 0.00 13.12 13.12 27 2.17 130 6681 1.41 0.00 13.12 13.12 28 1.96 118 6786 1.44 0.00 13.12 13.12 29 1.77 106 6879 1.46 0.00 13.12 13.12 Time Inflow I Volume in Surf Vol Depth Overflow Exfilt Vol Out min cfs cf cf ft cfs cf cf 30 1.60 96 6962 1.47 0.00 13.12 13.12 31 1.45 87 7036 1.49 0.00 13.12 13.12 32 1.31 79 7102 1.50 0.00 13.12 13.12 33 1.18 71 7160 1.52 0.00 13.12 13.12 34 1.07 64 7211 1.53 0.00 13.12 13.12 35 0.97 58 7256 1.54 0.00 13.12 13.12 36 0.87 52 7295 1.54 0.00 13.12 13.12 37 0.79 47 7329 1.55 0.00 13.12 13.12 38 0.71 43 7359 1.56 0.00 13.12 13.12 39 0.65 39 7385 1.56 0.00 13.12 13.12 40 0.58 35 7407 1.57 0.00 13.12 13.12 41 0.53 32 7425 1.57 0.00 13.12 13.12 42 0.48 29 7441 1.58 0.00 13.12 13.12 43 0.43 26 7453 1.58 0.00 13.12 13.12 44 0.39 23 7464 1.58 0.00 13.12 13.12 45 0.35 21 7472 1.58 0.00 13.12 13.12 46 0.32 19 7478 1.58 0.00 13.12 13.12 47 0.29 17 7482 1.58 0.00 13.12 13.12 48 0.26 16 7484 1.59 0.00 13.12 13.12 49 0.24 14 7485 1.59 0.00 13.12 13.12 50 0.21 13 7485 1.59 0.00 13.12 13.12 51 0.19 12 7483 1.58 0.00 13.12 13.12 52 0.17 10 7481 1.58 0.00 13.12 13.12 53 0.16 9 7477 1.58 0.00 13.12 13.12 54 0.14 9 7472 1.58 0.00 13.12 13.12 55 0.13 8 7467 1.58 0.00 13.12 13.12 56 0.12 7 7461 1.58 0.00 13.12 13.12 57 0.10 6 7454 1.58 0.00 13.12 13.12 58 0.09 6 7447 1.58 0.00 13.12 13.12 59 0.09 5 7439 1.58 0.00 13.12 13.12 60 0.08 5 7430 1.57 0.00 13.12 13.12 61 0.07 4 7421 1.57 0.00 13.12 13.12 62 0.06 4 7412 1.57 0.00 13.12 13.12 63 0.06 3 7402 1.57 0.00 13.12 13.12 64 0.05 3 7392 1.57 0.00 13.12 13.12 65 0.05 3 7382 1.56 0.00 13.12 13.12 66 0.04 3 7371 1.56 0.00 13.12 13.12 67 0.04 2 7361 1.56 0.00 13.12 13.12 68 0.03 2 7349 1.56 0.00 13.12 13.12 69 0.03 2 7338 1.55 0.00 13.12 13.12 70 0.03 2 7327 1.55 0.00 13.12 13.12 71 0.03 2 7315 1.55 0.00 13.12 13.12 72 0.02 1 7303 1.55 0.00 13.12 13.12 73 0.02 1 7292 1.54 0.00 13.12 13.12 74 0.02 1 7280 1.54 0.00 13.12 13.12 75 0.02 1 7268 1.54 0.00 13.12 13.12 76 0.02 1 7255 1.54 0.00 13.12 13.12 77 0.01 1 7243 1.53 0.00 13.12 13.12 78 0.01 1 7231 1.53 0.00 13.12 13.12 79 0.01 1 7218 1.53 0.00 13.12 13.12 Tiimelnflow Volume in Surf Vol Depth Overflow EAR Vol Out n+kAwa3a, Cf Cf ff CIS Cf CI 80 0.01 1 7206 1.53 n no 11.119 11 19 81 0.01 1 7193 1.52 0.00 13.12 13.12 82 0.01 1 7181 1.52 0.00 13.12 13.12 83 0.01 0 7168 1.52 0.00 13.12 13.12 84 0.01 0 7155 1.52 0.00 13.12 13.12 85 0.01 0 7142 1.51 0.00 13.12 13.12 86 0.01 0 7130 1.51 0.00 13.12 13.12 87 0.01 0 7117 1.51 0.00 13.12 13.12 Precipitation Frequency Data Server Page 1 of 3 POINT PRECIPITATIONr' FREQUENCY ESTIMATES FROM NOAA ATLAS 14 WASHINGTON MAIN STREET, NORTH CAROLINA (31-9100) 35.5333 N 77.0167 W 26 feet from "Precipitation -Frequency Atlas of the United States" NOAA Atlas 14, Volume 2, Version 3 G.M. Bonnin, D. Martin, B. Lin, "F. Parzybok, M.Yekla, and D. Riley NOAA, National Weather Service, Silver Spring, Maryland, 2004 Extracted: Fri Sep 17 2010 Confidence Limits Seasonality Related Info GIS data Maps Docs Return to State Map Precipitation Intensity Estimates (in/hr) ARI* (years) 5 min 10 min 15 min 30 - min 60 mm �� 120 3 hr 6 hr 12 hr �� 24 hr 48 hr 4 J 7 d� 10 p 20 day 30 45 d� 60 mm - - 1� 5.39 67267 4.3 I 5.00 3.59 4.20 2.46 2.90 1.53 Ej2E7E.77 0.90 0.64 0.39 0.46 0.22 0.27 0.13 0.16 0.08 0.09 0.04 0.05 0.03 0.04 0.02 0.03 0.02 0.02 0.01 0.02 0.01 0.01 0.01 0.01 0 7.13 5.71 4.82 3.42 2.19 1.32 0.95 0.57 0.33 0.21 0.12 0.07 0.04 0.03 0.02 0.02 0.02 0.01 10 8.12 6.50 5.48 3.97 2.58 1.59 1.15 0.69 0.41 0.25 0.14 0.08 0.05 0.04 0.03 0.02 0.02 0.02 25 9.17 7.31 6.18 4.57 3.04 1.92 1.40 0.84 0.50 0.31 0.18 0.10 0.06 0.05 0.03 0.02 0.02 0.02 50 10.08 8.02 6.77 5.10 3.46 2.22 1.64 0.99 0.59 0.36 0.21 0.11 0.07 0.05 0.03 0.03 0.02 0.02 100 10.91 8.67 7.30 5.59 3.85 2.52 1.88 1.14 0.69 0.42 0.24 0.13 0.08 0.06 0.04 0.03 0.02 0.02 Ill 75 931 78 6.09 42722 5 3 9008000 48 4 09 07.04 0200 0.03 0.03 0.02 500 12.76 10.09 8.46 6.73 4.83 3.30 2.53 1.55 0.94 0.57 0.33 0.17 0.11 0.08 0.05 0.04 0.03 0.03 1000 13.70 10.79 9.03 7.31 5.34 3.72 2.89 1.78 1.09 0.65 0.38 O.19 0.12 0.09 0.05 0.04 0.03 0.03 These precipitation frequency estimates are based on a partial duration series. ARI is the Average Recurrence Interval. Please refer to NOAA Atlas 14 Document for more information. NOTE: Formatting forces estimates near zero to appear as zero. * Upper bound of the 90% confidence interval Precipitation Intensity Estimates (in/hr) ARI 5 10 IS 30 60 120 3 6 12 24 48 4 7 10 20 30 45 60 (years) min min min min min min hr hr hr hr hr day day day day dayl jday 1� 5.94 4.75 3.96 2.71 I.69 1.00 0.72 0.44 0.25 0. 15 0.09 0.05 0.03 0.03 0.02 0.01 0.01 0.01 2� 6.90 5.52 4.62 3.19 2.00 1.19 0.86 0.52 0.30 0.18 0.10 0.06 0.04 0.03 0.02 0.02 0.01 0.01 7.85 6.28 5.30 3.76 2.41 1.46 1.06 0.64 0.37 0.23 0.13 0.07 0.05 0.04 0.02 0.02 0.02 0.01 10 8.95 7.15 6.03 4.37 2.85 1.75 1.28 0.77 0.45 0.27 0.16 0.09 0.06 0.04 0.03 0.02 0.02 0.02 25 10.08 8.03 6.79 5.03 3.35 2.11 1.56 0.94 0.56 0.34 0.19 0.10 0.07 0.05 0.03 0.03 0.02 0.02 50 11.08 8.81 7.44 5.60 3.80 2.44 1.82 1.11 0.66 0.39 0.23 0.12 0.08 0.06 0.04 0.03 0.02 0.02 100 I T 9-9 9.52 KE 6.14 4.23 2.78 2.09 1.28 0.76 0.46 0.26 0.14 0.09 0.07 0.04 0.03 0.03 0.02 200 12.90 10.22 8.60 6.70 4.70 3.14 2.39 L 0.88 0.53 0.31 0.16 0.10 0.08 0.05 0.04 0.03 0.02 500 14.03IF] 131 0 9. 71 .4 5.32 3.64 2.81 1.73 1.05 0.63 0.37 0.19 0.12 0.09 0.05 0.04 0.03 0.03 1000 15.1 I 11.90 9.96 8.06 5.88 4.10 3.21 1.98 1.21 0.72 0.42 0.21 0.13 0.10 0.06 0.04 0.04 0.03 ' The upper bound of the confidence interval at 90% confidence level is the value which 5% of the simulated quantile values for a given frequency are greater than. These precipitation frequency estimates are based on a partial duration series. ARI is the Average Recurrence Interval. Please refer to NOAA Atlas 14 Document for more information. NOTE: Formatting prevents estimates near zero to appear as zero. * Lower bound of the 90% confidence interval Precipitation Intensity Estimates (in/hr) http://hdse.nws.noaa.gov/cgi-bin/hdsc/buildout.per]9type=idf&units=us&ser... 9/ 17/2010 Family Dollar Total Site Drainage Design Small Watershed Method Hydrograph Generation (Rf: "Elements of Urban Stormwater Design, H.R. Malcom, PE) Drainage Area Description =_> Predevelopment -Entire Development Total Drainage Area: Impervious Area = 0.1 AC @ c= 0.98 and CN =[]61 CBD = 0 AC @ c= 0.98 and CN = Open / Grassy / Landscaped Area = 1.04 AC @ c= 0.35 and CN = Wooded Area = 0 AC @ c= 0.2 and CN = Agricultural Field = 0 AC @ c= 0.35 and CN = Total DA = 1.14 AC @ c= 0.41 and CN = 64.2 Family Dollar Total Site Drainage Design Design Storm Description /Watershed Sensitivity ==> Time of Concentration =r 5.0 minutes Tc methodology = SCS TR-55 segmental approach (1986) Enter known OF factors to compute the intensity, or enter a known intensity in the area marked "known intensity'. If known, clear all OF factors from the chart. OF Factors: 1-year 2-year I 5-year I 10-year 25-year I 50-year I 100-year I storm storm storm storm storm storm storm g h 12 22 13 23 1 Calculated Intensities (do not enter known values here): 1-year 2-year 5-year I 10-year I 25-year I 50-year I 100-year I storm storm storm storm storm storm storm Intensity 4.70 5.82 0.00 8.95 0.00 0.00 0.00 (in/hr) Design storm flowrates ==> Flowrates are calculated using the rational method, and incorporating frequency coefficients for the 25, 50, and 100 year storms. These frequency coefficients are 1.1, 1.2, and 1.25 respectively. Flowrate for 1-year storm is calculated as 80% of the 2-year storm. Calculated design flowrates: 1 year 2-year I 5-year I 10-year I 25-year I 50-year I 100-year I storm storm storm storm storm storm storm Flowrates 2.17 2.69 0.00 4.13 0.00 0.00 0.00 (CFS) Formulate hydrograph using step -function estimated SCS dimensionless UH ==> Ultimate Soil Storage: S = 5.57 inches m Family Dollar Total Site Drainage Design Precipitation Depths for 24 hr. design storm: 1-year storm 2-year I storm 5-year I storm 10-year I storm 25-year I stone 50-year I storm 100-year I stone P-depth 3.50 3.88 5.02 5.98 7.41 8.63 9.981 (inches) SCS runoff depth using default initial loss characteristics (0.2S and 0.8S): 1-year 2-year I 5-year I 10-year I 25-year I 50-year I 100-year I storm storm storm storm storm storm storm Q' 0.72 0.92 1.61 2.27 3.34 4.32 5.45 (inches) Time to peak for design hydrograph (for step -function hydrograph): 1-year 2-year I 5-year I 10-year 25-year 50-year 100-year storm storm storm storm storm storm storm TP 16.35 16.94 (minutes) Resultant SWM design hydrographs => 1-year = 2.17 CFS @ 16.35 minutes 2-year= 2.69 CFS @ 16.94 minutes 5-year = 0.00 CFS @ 0.00 minutes 10-year = 4.13 CFS @ 0.00 minutes 25-year = 0.00 CFS @ 0.00 minutes 50-year = 0.00 CFS @ 0.00 minutes 100-year = 0.00 CFS @ 0.00 minutes Family Dollar Washington Drainage Calculations Small Watershed Method Hydrograph Generation (Rf: "Elements of Urban Stormwater Design, H.R. Malcom, PE) Drainage Area Description =_> ITotal Post. Development- Entire Development Total Drainage Area: Roadway Area = 0.76 AC @ c= 0.95 and CN =IA55 Roof Impervious = 0 AC @ c= 0.95 and CN = Open I Grassy I Landscaped Area = 0.38 AC @ c= 0.35 and CN = Wooded Area = 0 AC @ c= 0.25 and CN = Other undescribed area = 0 AC @ c= 0.25 and CN = Total DA = 1.14 AC @ c= 0.75 and CN = 85.7 Design Storm Description / Watershed Sensitivity =_> Time of Concentration = r- 5.0 minutes Tc methodology [SCS TR-55 segmental approach (1986) Enter known IDF factors to compute the intensity, or enter a known intensity in the area marked "known intensity'. If known, clear all IDF factors from the chart. IDF Factors: 1-year 2-year I 5-year I 10-year 25-year 50-year I 100-year I storm storm storm storm storm storm storm g 1271 163 h -221 23 Calculated Intensities (do not enter known values here): 1-year 2-year I 5-year I 10-year I 25-year I 50-year I 100-year I storm stone storm stone stone storm storm Intensity 4.70 5.82 0.00 8.95 0.00 0.00 0.00 (in/hr) Family Dollar Washington Drainage Calculations Design storm Fowrates ==> Flowrates are calculated using the rational method, and incorporating frequency coefficients for the 25, 50, and 100 year storms. These frequency coefficients are 1.1, 1.2, and 1.25 respectively. Flowrate for 1-year storm is calculated as 80% of the 2-year storm. Calculated design flowrates: 1 year 2-year I 5-year I 10-year I 25-year I 50-year I 100-year I storm storm storm storm stone storm storm Flowrates 4.02 4.98 0.00 7.65 0.00 0.00 0.00 (CFS) Formulate hydrograph using step -function estimated SCS dimensionless UH ==> Ultimate Soil Storage: S = 1.67 inches Precipitation Depths for 24 hr design storm: 1-year storm 2-year I storm 5-year I storm 10-year I storm 25-year I storm 50-year I storm 100-year I storm P-depth 3.50 3.88 5.02 5.98 7.41 8.63 9.981 (inches) SCS runoff depth using default initial loss characteristics (0.2S and 0.8S): 1-year 2-year I 5-year I 10-year I 25-year I 50-year I 100-year I storm storm storm storm storm storm storm Q. 2.07 2.41 3.45 4.35 5.72 6.90 8.22 (inches) Time to peak for design hydrograph (for step -function hydrograph): 1-year 2-year I 5-year I 10-year 25-year 50-year 100-year storm storm storm storm storm storm storm Tp 25.53 (minutes) Resultant SWM design hydrographs ==> 1-year = 4.02 CFS @ 25.53 minutes 2-year = 4.98 CFS @ 0.00 minutes 5-year = 0.00 CFS @ 0.00 minutes 10-year = 7.65 CFS @ 0.00 minutes 25-year = 0.00 CFS @ 0.00 minutes 50-year = 0.00 CFS @ 0.00 minutes 100-year = 0.00 CFS @ 0.00 minutes 1 Family Dollar Washington Drainage Calculations Check Control of 1-year. 24-hour Storm If thel-year, 24-hour storm must be controlled, then the difference in the volume of runoff between the post -development and the pre -development must be stored. drainage area = 1.14 acres 1-year, 24-hour precipitation = 3.50 inches pre -developed CN = 64 post -developed CN = 85.7 pre -developed ult. storage = 5.63 inches post -developed ult. storage = 1.67 inches pre -developed runoff = 0.71 inches post -developed runoff = 2.07 inches storage volume required = 0.13 acre-feet = 5,651.59 cubic feet Post Development Rational Method 1 YR - 24 HR STORM EVENT Q = CIA c= 0.75 Allowabel release rate - 3.411 cfs A= 1.14 ac 4.01dlfrs 4.7inlhr Pre Development Rational Method 1 YR - 24 HR STORM EVENT Q=CIA C= 0.41 A= -F� Pq 1 Year Q 3.411 CFS I 4.70 in/hr F. irst F. IdSW Ran De fig in 040te1�iti'sV4 i::{' "+aY 'f 1.5 To1el: Runoff.Voluma- >.,,.��:. „"sa?Iy" 42d965 TotaI,RurroN-..Volume (ac-m)MG?i??-N✓rb *`+�1- f.17 PRIMARY BMP CHARACTERISTICS Avdra 'BMRDe m'in)M xF'vt�ti,N".Fr&8': s'.- 12 Ave BMP-De Ui'Il ituliy�+,4,''.�,>;.[k�,tt..`,' 1 uI:M FSYSi-Tf877FRWIWI kW�'' 0.1084 e1ulP1Y7iF1 - '12FNE%'rJt�l° w -x"u' r ..;.,'`,°:1 4722 CALCULATION CHECKS Total P.re-0evabpmem,Wetersbetl Area (s0ydw::; 49658 Total.P.os4Devebpnrent�Waersfietl'Area(s0° 49858 %BMP.Aioe oLWeheErAFea$^u��w�'a w'',.'.�ti%;i 9.51 Bioretention Sizing PRE -DEVELOPMENT WATERSHED CHARACTERISTICS Family Dollar EXPRESS SEP 21 2010 NC DENR ds we.43rt 41. urltl Uee/Cover f �41n:- krk.W d s y41jm� ..�,n:aaa ✓n, u.,, tk9' SWI r4Hytlrvloele r�rlGmuP ., 0.,-en,.rce@A A f Ana(si) �rv1 :,e 0 .'Curve Number :N _.V 89 t ' '� > slinl ' 9'. 1.24 USE to 2',S)!or liihli Abfhac0on7 1 ( l tafeYN.9'+yW7risAv 1 aq+ +wAhtj3' Tp kManuN liHtl±!r+%'w.,o,•viU�1 AMVallon(in)(Abatrachan A am 4%Initlil"$d t Usea In w6Hi� sI.,: Runoa y .+ii Oepthp' In 17 r�4 0,63 )tw .: i6RunoR ,I Volume c µgyi; s 0.00 2�1rountl B 0 61 6,39 1 0.02 0.01 0.00 rnerlBged C 44858 73 370 --"-1_+. "- "-0.02 n 0,13 484.59 D 0 79 2.66 1 0.02 >:W'"'0'53"�': 0,26 OoD A 0 81 2.35 1 D02 }'vtr` O:C7.6 < 0,31 too Sitl fk B 4BOD I 98 0.20 1 0.02 r:;r'O.Oa"^an 1.28 512.05 C 0 91 0.99 1 0.02 074 1 2'0 D 0 00.75 1 0.02 K"F'0\151lUQ 0.87 1 0.00 1 002 F'Ml crooer. l 1.50 o.DO 000 1 Do .11iao06as�s:a 1.50 o.ao 0.00 1 0.02 HnO.00S`::i 1.50 0.00 000 1 0.02 346.004'$'+* 1.50 f 000 0.00 1 0.02 Ak<'uc'0.00w'y 1.50 000 0.00 1 0.02 1.50 0.00 000 1 0.02 10.0011«' 1.50 0.DO POST -DEVELOPMENT WATERSHED CHARACTERISTICS ...:,sou. Lantl UaelCover }i},, ,8g�0 t ( M "Ll, plc A n;,.... A_ne (sUv s 0 k Curvet rr ^-^�^ 5 Nunlbev : w 89 '.-a Nyt S'(Inl 1.2d usE,lo.asl ror Inlilel' AbabacUo ?�(I ss,'ey'rw,Ywl°k 1 4xp-o14.iatAaiilm'4 Manwl inlllalpp ��••wa �1 Abebactlon Inf 0.02 +w�-i4olp7 Abatractlon �vvUeetl In t9.t'�025R''::'', 'Runort y OepN In &Volume c •M11Nta 0.63 s..z✓,�.ri.'. Burpn t', PoWn.6bh4!? 0,00 B 0 60 6E7 1 0.02 O';,rif,33u::ii(=_+ 0.00 ow C O 73 370 1 0,02 ": „0 ]A ,^; 0.13 0.00 0 0 79 266 1 0,02 ?0`53?.+I 0.26 0.00 A 0 81 2,35 1 0.02 .`S.t i0.d7 0,31 O,DO B 0 88 1.36 1 0,02 ``gip='O 271_2.7` 0,58 0-00 C 0 1 91 0,99 1 1 0.02 f:2i3' 0'20''9""'- 0,74 0.00 D 93 075 1 002 0.87 0.00 A 61 639 1 002 ! vkli2e"�' 0.01 000 B 69 4,49 1 002 iy"".:.090 a 0.07 0.00 mane roes C 11831 73 370 1 0.02 �Gfi 7 0,13 127.81 A 90 1.11 1 C 02 "7 ' 0.22Ss, s68 0 0.00 im erviow B 33105 98 0.20 1 0.02 ri 1.28 3531.59 C 95 0,53 1 0,02 1.01 0.D0 D 98 0.20 1 0.02 LrO:pq xq.,ei 128 0DO BMP RUass -> 4722 100 0.00 0 1 1.50 590.25 WATER QUALITY RAINFALL AND POST -DEVELOPMENT RUNOFF Note: cells C38 and B50 should match, adjust C38