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Home My WebLink AboutMitchell Community College - REVISED-6028-MCC Calc Book_Storm ENGINEERING CALCULATIONS FOR MITCHELL COMMUNITY COLLEGE HEALTH SCIENCES BUILDING Prepared by: LandDesign, Inc. 223 North Graham St. Calculations by: GR Checked by: MDM Revised: March 22, 2019 LandDesign PN: 1016028 Project Name:Mitchell Community CollegeProject Number:1016028Design Requirements:85% TSS RemovalGiven Information:Land Use: InstitutionalDrainage Area to Facility (Acres): 2.00 NCDENR (Maximum 5 Acres)Meck. County (Maximum 10 Ac for a Surface Filter)Meck. County (Maximum 2 Ac for a Perimeter Filter)Meck. County (Maximum 5 Ac for an Underground Filter)Impervious Area (Acres): 0.74Percent Impervious: 37.0%Soil Type: CgCSoil Group: BCurve Number (CN) Pre: 87Curve Number (CN) Post: 75Time of Concentration Pre (hour): 0.230Time of Concentration Post (hour): 0.083Design Storm Rainfall Depth (in): 1.0 (Typically 1")Detention Time (Day): 1.66 Meck. County:2 days - 85% TSS & 70% TP (Optimal Efficiency)1 day - 70% TSS & 35% TP (Standard Efficiency)2 days - 85% TSS & 0% TP (TSS - Only Efficiency)NCDENR1.66 daysCoefficient of Permeability for the Sand Filter Bed: 1.75 inches/hourWatershed:Yadkin-Southeast Catawba - 85% TSS & 70% TPEfficiency:NCDENR Step 1: Compute the water quality volume (WQV). WQV (Ft3) = (RV / 1) X (AD / 1) X (43,560 Ft2 / 1 Acre) X (RD / 1) X (1 Ft / 12 in) WQVAdj (Ft3) = (0.75) WQV Where: WQV = Water Quality Volume (Ft 3) WQVAdj = Adjusted Water Quality Volume (Ft3) AD = Drainage Area to Sand Filter (acres). Max. 5 acres. RV = Volumetric Runoff Coefficient = 0.05 + 0.9 (% Impervious) RD = Design Storm Rainfall Depth (in). Typically 1.0". Percent Impervious = 37% AD =2.00 acres RD = 1.0 in RV = 0.38 WQV = 2,781 Ft3 WQVAdj =2,086 Ft3 Sand Filter Design (NCDENR - 2007) Project Name: Mitchell Community College Job Number: 1016028 Step 2: Determine the maximum head on the sand filter and sedimentation basin. ha (ft) = hMaxFilter / 2 hMaxFilter (Ft) = (WQV Adj) / (AS + Af) AS (Ft2) = -(Q0 / w) x (ln (1 - E)) Af (Ft2) = (WQV x dF) / (k x t x (hA + dF)) Q (Ft3/Sec) = k x (1 Day / 86,400 Sec) x (Af) x ((ha + dF) / dF) Where: ha = Average Head (Ft) hMaxFilter = Maximum Head on the Sand Filter (Ft) AS = Surface Area of the Sedimentation Basin (Ft2) Af = Surface Area of the Sand Filter Bed (Ft2) Q0 = Average Rate of Outflow From Sedimentation Chamber (Ft3 / sec.) = WQV / 86,400 E = Trap Efficiency of the Chamber = 0.9 w = Settling Velocity of Particle (Ft/sec) (Assume Particle Diameter of 20 microns = 0.0004 Ft/sec) dF = Depth of Sand Filter Bed (Ft) (Minimum of 1.5 Ft) k = Coefficient of Permeability for the Sand Filter Bed = 3.5 Ft/day t = Time Required to Drain the WQV through the Sand Filter Bed (day). Q = Sand Filter Infiltration Rate at hMaxFilter (Ft3/Sec). (Darcy's Law) For maximum heads between 2 and 6 feet, the following combinations of variables will work: (Ideal situation AS = Af) hMaxFilter WQVAdj AS + Af (Ft)(Ft3) (Ft 2) 2 2,086 1,043 3 2,086 695 4 2,086 522 5 2,086 417 6 2,086 348 Area available for sand filter = 695 Ft2 hMaxFilter =3 Ft ha = 1.5 Ft Minimum AS =185 Ft2 dF =2.0 Ft k = 3.5 Ft/day t = 1.66 day Minimum Af =274 Ft2 Min. required area for sand filter = 459 Ft2 TRUE Af =348 Ft2 AS =348 Ft2 hMaxFilter =3.0 Ft ha = 1.5 Ft Q = 0.025 Ft3/Sec Step 3: Ensure that the Water Quality Volume is Contained. (Af + AS) x hMaxFilter ≥WQVAdj 2,088 Ft3 ≥2,086 Ft3 TRUE Step 4: Additional Design Requirements. For underground sand filters, provide at least 5 feet of clearance between the surface of the sand filter and the bottom of the roof of the underground structure to facilitate cleaning and maintenance. Step 5: Calculate Surface Area and Underdrain Requirements Q (Ft3/Sec) = k x (1 Day / 86,400 Sec) x (Af) x ((ha + dF) / dF) Where: ha = Average Head (Ft) hMaxFilter = Maximum Head on the Sand Filter (Ft) (Maximum of 2.0 Ft) Af = Surface Area of the Sand Filter Bed (Ft2) AS = Surface Area of the Sedimentation Basin (Ft2) Cd = Sediment Chamber Depth (Ft) dF = Depth of Sand Filter Bed (Ft) (Minimum of 2.0 Ft) k = Coefficient of Permeability for the Sand Filter Bed = 3.5 Ft/day QMaxFilter = Sand Filter Infiltration Rate at hMaxFilter (Ft3/Sec). (Darcy's Law) Q0 = Sand Filter Infiltration Rate at Top of Sand (Ft3/Sec). (Darcy's Law) Required Af =274 Ft2 Provided Af = 373 Ft2 Required As =185 Ft2 Provided As = 2400 Ft2 Required Cd =0.3 Ft Provided Cd =3 Ft QMaxFilter =0.026 Ft3/Sec Q0 =0.000 Ft3/Sec Number of Underdrain Rows Required = 1 (Maximum Spacing = 10 Ft) Total Length of Underdrain = 47 Ft Number of Underdrain Perforations = 368 Holes 50% of Perforations = 184 Holes Area of One Perforation = 0.00077 Ft2 Capacity of One Hole = 0.0058 Ft3/Sec Total Capacity of Perforations = 1.07 Ft3/Sec Check: 1.07 Ft3/Sec > 0.026 Ft3/Sec :. GOOD Capacity of 6" PVC Underdrain at 0.50% Slope = 0.39 Ft3/Sec Assume 50% Clogging = 0.20 Ft3/Sec Check: 0.20 Ft3/Sec > 0.026 Ft3/Sec :. GOOD