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Home My WebLink AboutSW6221201_Design Calculations_20221209CSD ENGINEERING PROJECT NARRATIVE With Project Calculations & Supporting Documents Ample Storage — Erwin, NC INTRODUCTION 032721 CA 10/2 8/2022. Turtle Run, LLC is proposing to build an Ample Storage facility at 404 E. Jackson Boulevard in the Town of Erwin, Harnett County, NC. The development will consist of buildings for indoor storage, office, and on - site apartment for facility manager. Submittals for approval and permitting include detailed construction drawings for site plan, grading, paving, drainage, and stormwater management for the site and minor improvements within the public right-of-way for driveway access. Approval of the construction drawings are under the jurisdiction of the Town of Erwin for site plan approval and zoning permit; N.C. Department of Environmental Quality (NCDEQ), Division of Water Resources (DWR) for stormwater management permit; and NCDEQ, Division of Land Resources (DLR), Land Quality Section for approval of the erosion and sediment control plan. The proposed driveway access will be reviewed and permitted by the N.C. Department of Transportation (NCDOT) District Office for Harnett County. CjOM Soil data was obtained from the NRCS Web Soil Survey for the project area of interest in Harnett County, NC. The soil map from the web application is included with the project calculations and supporting documents. The site mostly consists of loamy sand to sandy loam soils. The soils on the site are associated with uplands and are not a flood prone soil. The soils for the Goldsboro and Marlboro soil series are moderately well -drained soils; therefore, ponding on the surface of bare soil is not expected during construction. Unified classification (used in channel analysis) is SM at the surface. The site grading requires import of soils for the building and driveway foundations. A geotechnical engineering study for the borrow soils is recommended for structural purposes; however, for the purposes of stormwater runoff and erosion and sediment control, the properties of the in -situ soils were used. Regarding drainage, the soils have moderate permeability and fall into Hydrologic Soil Group B. The soil survey states that the water table is from 2 to 3 feet below the surface in the winter and spring; therefore, water may be encountered during installation of storm drainage pipes and the wet pond. 1 Project Narrative Ample Storage — Erwin, NC The soil composition was considered during design and analysis for hydrology, hydraulics, and erosion and sediment control. The soil map for the area of interest and sections of the soil report that were used to gather data used in the design and analysis have been included in the calculations and supporting documents. HYDROLOGY The area of improvement consists of one (1) drainage area within the site boundary. The total site area is 6.18 acres; however, the hydrologic analysis was conducted for the drainage area to the proposed wet pond (4.65 acres) which is all the new impervious area plus some pervious areas within the site development. The remaining on -site may be disturbed during construction; however, this area will remain pervious and not affect the pre- and post -development analysis. The hydrologic calculations for the drainage area to the pond includes pre -development curve number (CN) for the existing conditions and post -development CN for the proposed conditions. The drainage area analyzed was delineate using the post -development grading which was designed to drain all on -site impervious areas to the proposed wet pond. The existing area within the post -development drainage area drains to the lowest point on the site, which is the outfall point for the proposed wet pond. The pre- and post -development Drainage Area Maps show drainage area delineations, along with unimproved areas that do not drain to the proposed wet pond. The impervious surfaces on the Ample Storage site will be drained through a closed drainage system to the proposed wet pond. NRCS Peak Runoff Method The methods outlined in NRCS TR-55 were used to calculate peak runoff for land uses, time of concentration, and peak runoff for the drainage area. The Curve Numbers used were calculated using a composite curve number calculation. Precipitation data was obtained from NOAA's Precipitation Frequency Data Server (web -based), Atlas 14 Point Precipitation Frequency Estimates. The latitude and longitude were entered for the location and the 24-hour precipitation depths for the 1, 2, 10, 25, and 100- year storm recurrence interval were recorded and used in subsequent hydrologic calculations. The precipitation depth for the 1-year. 24-hour storm is 3.70 inches according to the NOAA estimates and this was used in time of concentration calculations. The computer software program Hydraflow Hydrographs was used to calculate peak runoff hydrographs and used to determine the storage required for proposed detention ponds. A copy of the Hydraflow Hydrograph reports for peak flow have been included in this submittal. The hydrologic calculations are summarized as follows: ➢ Drainage Area: ➢ Pre -development CN ➢ Post -development CN ➢ Time of Concentration ➢ Pre -development runoff (cfs): ➢ Post -development runoff (cfs) 4.65 acres 68 94 12 minutes Q1=3.88; Q2=6.47; Q10=15.30; Q25=21.54; Q100=32.65 Q1=15.39; Q2=19.19; Q10=30.06; Q25=36.81; Q100=48.08 STORMWATER CONTROL MEASURE A stormwater wet pond is proposed to capture runoff from the site and release it slowly; and the size needed has been calculated and represented in the plans. Hydraflow Hydrographs was used to calculate 2 Project Narrative Ample Storage — Erwin, NC the peak flow hydrographs for multiple storm recurrence intervals and subsequently used to route the inflow hydrographs and generate an outflow hydrograph for the temporary pool and outlet structure. Data used in site runoff calculations was used to estimate the size needed to meet water quality and water quantity treatment requirements as to improve the post -development stormwater management of the overall drainage area. Once the area needed for the pond was estimated, design for the actual pond grading was entered to determine the actual storage. Various outlet structure and spillway combinations were tried until an optimal solution was reached. A concrete riser with sloped top and trash rack is proposed and adequately stores the 1-year, 24-hour. 2- year, 24-hour storm , and 10-year 24-hour storm volumes. The secondary spillway will be a 15-feet weir in the wet pond dam. A copy of the Hydraflow calculation reports for the 1, 2, 10, 25 and 100-year storms are included in the calculations and supporting documentation. A schematic showing the estimated water surface elevations for the pond and the orifice sizing calculation for release of the overall storage volume have also been included. A summary of the routing calculations follows the next section of the narrative. Minimum Design Criteria The proposed wet pond was designed for water quality treatment and water quantity storage. The main pool surface area and volume was computed using the SA/DA and average depth method. Through iterations of main pool, forebay, and vegetated shelf configurations, the average depth of the pond was calculated to meet MDC (3 to 8 feet below permanent pool elevation). The average depth of the pond was used to determine the minimum surface area of the permanent pool to remove 85% TSS; from Table 1 in Chapter C-3 of the NCDEQ Stormwater Design Manual. The actual surface area at the permanent pool elevation is nearly twice what is needed for 85% TSS removal. The "Simple Method" was used to determine the minimum storage needed for the temporary water quality pool (volume of the 1" precipitation or the "first flush"). The final pond design adequately provides storage above the permanent pool for water quality treatment (see summary and supporting calculations). For the main pool depth, Equation 3 in Chapter C-3 of the Stormwater BMP Manual was used because the vegetated shelf was excluded from the average depth calculation. Through several iterations, the forebay volume was designed to be within 15 to 20 percent of the main pool volume. The proposed grading contours on the plans show the forebay entrance is deeper than the exit. The berm that separates the forebay from the main pool will be submerged and flows will be non -erosive. The forebay and main pool will be excavated to meet sediment storage requirements. The wet pond inlet and outlets were configurated to maximize the flow path. The pond will outlet along the length of the pond giving a wide area to facilitate settling. The pond has been routed for an outlet structure that will adequately convey storm events and provide adequate detention to protect downstream property. The drawdown of wet pond will be gradual within 2 to 3 days. The sloped top of the riser shall be covered by a prefabricated metal grate and help prevent debris from blocking top of riser. The wet pond will include a 12-foot-wide vegetated shelf at a 6:1 slope; 1 foot elevation above the permanent pool to one foot elevation below the permanent pool. A landscape plan is included in the construction drawings for planting of the vegetated shelf and mesic area around the pond. The plant schedule calls for Pickerelweed, Arrow Arum, and Bull Tongue within the submerged vegetated shelf; and, a variety of sedges within the wet mesic part of the vegetated shelf. Juncus will be planted along the water's edge to protect the more fragile submergent plants from potential rouge mowing by maintenance 3 Project Narrative Ample Storage — Erwin, NC crews. The embankments may be planted with love grass; however, a non -clumping turf grass will likely be used. For the final pond grading design, outlet details, and landscape plan, see the construction drawings. The water quality and water quantity calculations, hydrograph reports, routing, drawdown, and anti -floatation calculations are included in the project calculations and supporting documents. A summary of the final wet pond design and calculations is provided below: ➢ Permanent Pool Water Elevation: ➢ Forebay Volume: ➢ Main Pool Volume: ➢ Vegetated Shelf Volume: ➢ Surface Area at Bottom of Shelf: ➢ % Forebay Volume: ➢ Average Depth: ➢ Drainage Area: ➢ Impervious Area: ➢ % Impervious: ➢ SA/DA (Table 1; interpolated) ➢ Surface Area Required (85% TSS): ➢ Actual Surface Area @ 192.0 feet: ➢ Water Quality Volume to be controlled: ➢ Depth of runoff added to permanent pool ➢ Temporary Water Quality Pool Elevation: ➢ Actual Storage at 193.36 feet: Pond Routing Summary: ➢ Top of Dam: ➢ Emergency Spillway weir elevation and length ➢ Riser weir elevation and length: ➢ Culvert size/type and invert elevation: ➢ 1-Year Stage, Storage, and Outflow: ➢ 2-Year Stage, Storage, and Outflow: ➢ 10-Year Stage, Storage, and Outflow: ➢ 25-Year Stage, Storage, and Outflow: ➢ 100-Year Stage, Storage, and Outflow: ➢ Water Quality Volume to Drawdown: ➢ Drawdown Orifice Size: ➢ Drawdown Time: HYDRAULIC DESIGN 192 feet 3,959 cubic feet (cf) 22,545 cf 6,390 cf (below Permanent Pool Elevation) 5,070 square feet (sf) 17.6 3.19 feet (Main Pool — Veg. shelf / SA at shelf) 4.65 Acres 3.92 Acres 84.3 2.95 5,975 sf 10,035 sf 13,651 cf 1.36 feet 193.36 feet 16,833 cf 197.00 feet 195.40 feet; 15.0 feet (Cipoletti) 193.70 feet; 5.0 feet (one side of box) 18 inches; R.C. Pipe; 191.60 feet 193.92 feet; 24,908 cf; 1.87 cfs 194.18 feet: 28,878 cf; 5.60 cfs 194.94 feet: 41,077 cf; 12.70 cfs 195.38 feet: 48,963 cf; 14.40 cfs 195.82 feet; 56,887 cf; 28.14 cfs 16,833 cf 1.5 inches (hole drilled in 4-inch PVC cap) 2.4 days The closed storm drainage system were designed and analyzed using Hydraflow Storm Sewers software, using the methods outlined by Dr. Rooney Malcolm in "Elements of Stormwater Design" for closed system design (Rational Formula used for estimating runoff to inlets). The worst case scenario for water surface elevation in the wet pond was used for the starting elevation in the hydraulic grade line calculations. Some of the drainage system will be wet during normal conditions; therefore, the pipes were sized to 4 Project Narrative Ample Storage — Erwin, NC accommodate the storm runoff under "wet" conditions. The 100-year storm was analyzed for potential site flooding and the 100-year hydraulic grade line does not exceed the finish floor elevations of the building. The grading plan also shows areas where ponding water may runoff site prior to flooding buildings. The roadside channel along St. Matthews Road was analyzed for stability using a custom design spreadsheet workbook that was developed using the normal depth method outlined by Dr. Rooney Malcolm in "Elements of Stormwater Design" and methods outlined in FHWA HEC-15 "Design of Roadway Channels with Flexible Linings" (3rd Ed.). The spreadsheet inputs require discharge, slope, channel geometry, soil data, and permissible shear stress values. For the input given, the normal depth of flow is determined through iteration of values until the solution is met. The shear stress is calculated, and appropriate liners are determined for stability. Normal depth for the channel downstream of driveway culvert was used in the sizing of the driveway pipe. The channel analysis calculations have been included in this submittal. EROSION AND SEDIMENT CONTROL The erosion and sediment control plan includes measures to keep runoff from disturbed areas from leaving the site, minimize initial erosion, and to capture sediment from disturbed areas. The plan is divided into two phases: demolition/clear and grub (1) and intermediate/final (2). The plans show a constructed berm at the low end of the site to be built to finished slope and grade. The berm will act as a temporary diversion to drain disturbed areas to the sediment basin. The construction drawings show detailed sections for the berm/diversion. The sediment basin will be constructed in the footprint of the proposed wet pond. The contractor has the option of building the pond riser and grading the pond first. The site will be graded through stages so that runoff will be intercepted by the diversion. A basin dimension worksheet summarizes the basin design, and the sediment basin will be dewatered from surface with a skimmer. The wet pond riser detail shows how a skimmer can be attached to the permanent riser. Temporary inlet protection will be utilized to keep sediment out of the drainage system boxes and pipes. The site will be stabilized throughout construction with erosion control matting, gravel subgrade, pavement, concrete, and permanent vegetation as construction progresses. UTILITIES The site will be served by an existing water service. A septic permit has been obtained to repair/relocate the existing septic system. Construction of a new septic system is included in the limits of disturbance; however, there will be limited disturbance in this area beside Building A. Minimal disturbance is anticipated for modifications of the water service from the meter to the buildings. 5 t BRYANT RD T .r. v� ON D E.H i Ilk s �FNSITE ��p LAT. 351935"N 421 r LONG: 78'2"W ()o D pc)ST�R D tIC`,, ti a m O° l � c v 1000 500 0 1000 2000 SCALE IN FEET.• 1"= 1000' ENGINEERING AMPLE STORAGE USGS QUAD MAP DATE: 1012512022 LAND PLANNING DRAWN BY. JFO oa"a/ mmoau ERWIN QUADRANGLE r.a � 12M LAND OWNER. TURTLE RUN, LLC HARNETT COUNTY, NC w 1rc 27591 225 PEEDIN ROAD 7.5—MINUTE SERIES LICENSE # c-2ro SMITHFIELD, NC 27577 2016 UAD-1 19191 �ho27' PROD. NO: 21-0590 � 712680 35° 19'49"N 712770 712860 712950 Soil Map —Harnett County, North Carolina (Ample Storage - Irwin) 713040 713130 713220 1 1 1 ExA a , r Soil MaN 11 iaot h �aliel at this scale. 712680 712770 712860 712950 713040 713130 Map Scale: 1:4,190 if printed on A landscape (11" x 8.5") sheet. Meters N 0 50 100 200 500 Feet 0 200 400 8D0 1200 Map projection: Web Mercator Comer coordinates: WGS84 Edge tics: UTM Zone 17N WGS84 USDA Natural Resources Web Soil Survey IiI Conservation Service National Cooperative Soil Surve 713310 713400 713490 713220 713310 713400 35° 19' 49" N 0 N_ - 35° 19' 30" N 713490 713580 M 5/9/2022 Page 1 of 3 MAP LEGEND Area of Interest (AOI) 0 Area of Interest (AOI) Soils 0 Soil Map Unit Polygons ,N Soil Map Unit Lines Soil Map Unit Points Special Point Features Blowout Borrow Pit Clay Spot Closed Depression Gravel Pit �i Gravelly Spot 0 Landfill A. Lava Flow Marsh or swamp Mine or Quarry Miscellaneous Water Perennial Water Rock Outcrop Saline Spot Sandy Spot Severely Eroded Spot Sinkhole Slide or Slip o Sodic Spot Soil Map —Harnett County, North Carolina (Ample Storage - Irwin) MAP INFORMATION Spoil Area The soil surveys that comprise your AOI were mapped at 1:24,000. Stony Spot Very Stony Spot Warning: Soil Map may not be valid at this scale. Wet Spot Enlargement of maps beyond the scale of mapping can cause misunderstanding of the detail of mapping and accuracy of soil 4� Other line placement. The maps do not show the small areas of Special Line Features contrasting soils that could have been shown at a more detailed scale. Water Features Streams and Canals Please rely on the bar scale on each map sheet for map measurements. Transportation Rails Source of Map: Natural Resources Conservation Service Web Soil Survey URL: . 0 Interstate Highways Coordinate System: Web Mercator (EPSG:3857) US Routes Maps from the Web Soil Survey are based on the Web Mercator Major Roads projection, which preserves direction and shape but distorts distance and area. A projection that preserves area, such as the Local Roads Albers equal-area conic projection, should be used if more accurate calculations of distance or area are required. Background Aerial Photography This product is generated from the USDA-NRCS certified data as of the version date(s) listed below. Soil Survey Area: Harnett County, North Carolina Survey Area Data: Version 19, Jan 21, 2022 Soil map units are labeled (as space allows) for map scales 1:50,000 or larger. Date(s) aerial images were photographed: Oct 22, 2018—Oct 25, 2018 The orthophoto or other base map on which the soil lines were compiled and digitized probably differs from the background imagery displayed on these maps. As a result, some minor shifting of map unit boundaries may be evident. usoA Natural Resources Web Soil Survey 5/9/2022 Conservation Service National Cooperative Soil Survey Page 2 of 3 Soil Map —Harnett County, North Carolina Ample Storage - Irwin Map Unit Legend Map Unit Symbol Map Unit Name Acres in AOI Percent of AOI Co Coxville loam 16.0 21.1 % ExA Exum very fine sandy loam, 0 to 2 percent slopes 1.5 1.9% GoA Goldsboro loamy sand, 0 to 2 percent slopes, Southern Coastal Plain 13.3 17.5% MaA Marlboro sandy loam, 0 to 2 percent slopes 21.6 28.4% MaB Marlboro sandy loam, 2 to 6 percent slopes 1.3 1.7% Na Nahunta loam 0.5 0.7% NoA Norfolk loamy sand, 0 to 2 percent slopes 6.7 8.8% NoB Norfolk loamy sand, 2 to 6 percent slopes 6.4 8.4% OrB Orangeburg loamy sand, 2 to 6 percent slopes 8.8 11.5% Totals for Area of Interest 76.9 100.0% USDA Natural Resources Web Soil Survey 5/9/2022 Conservation Service National Cooperative Soil Survey Page 3 of 3 Plasticity Index ---Harnett County, North Carolina Plasticity Index Map unit symbol Map unit name Rating (percent) Acres in AOI Percent of AOI Co Coxville loam 24.0 16.0 21.1 % ExA Exum very fine sandy 19.0 1.5 1.9% loam, 0 to 2 percent slopes GoA Goldsboro loamy sand, 11.0 13.3 17.5% 0 to 2 percent slopes, Southern Coastal Plain MaA Marlboro sandy loam, 0 13.0 21.6 28.4% to 2 percent slopes MaB Marlboro sandy loam, 2 13.0 1.3 1.7% to 6 percent slopes Na Nahunta loam 19.0 0.5 0.7% NoA Norfolk loamy sand, 0 to 11.6 6.7 8.8% 2 percent slopes NoB Norfolk loamy sand, 2 to 9.7 6.4 8.4% 6 percent slopes OrB Orangeburg loamy 11.0 8.8 11.5% sand, 2 to 6 percent slopes Totals for Area of Interest 76.9 100.0% USDA Natural Resources Web Soil Survey 5/9/2022 Conservation Service National Cooperative Soil Survey Page 1 of 2 Plasticity Index ---Harnett County, North Carolina Description Plasticity index (PI) is one of the standard Atterberg limits used to indicate the plasticity characteristics of a soil. It is defined as the numerical difference between the liquid limit and plastic limit of the soil. It is the range of water content in which a soil exhibits the characteristics of a plastic solid. The plastic limit is the water content that corresponds to an arbitrary limit between the plastic and semisolid states of a soil. The liquid limit is the water content, on a percent by weight basis, of the soil (passing #40 sieve) at which the soil changes from a plastic to a liquid state. Soils that have a high plasticity index have a wide range of moisture content in which the soil performs as a plastic material. Highly and moderately plastic clays have large PI values. Plasticity index is used in classifying soils in the Unified and AASHTO classification systems. For each soil layer, this attribute is actually recorded as three separate values in the database. A low value and a high value indicate the range of this attribute for the soil component. A "representative" value indicates the expected value of this attribute for the component. For this soil property, only the representative value is used. Rating Options Units of Measure: percent Aggregation Method: Dominant Component Component Percent Cutoff.- None Specified Tie -break Rule: Higher Interpret Nulls as Zero: No Layer Options (Horizon Aggregation Method): Depth Range (Weighted Average) Top Depth: 12 Bottom Depth: 24 Units of Measure: Inches USDA Natural Resources Web Soil Survey 5/9/2022 Conservation Service National Cooperative Soil Survey Page 2 of 2 Hydrologic Soil Group and Surface Runoff ---Harnett County, North Carolina Ample Storage - Irwin Hydrologic Soil Group and Surface Runoff This table gives estimates of various soil water features. The estimates are used in land use planning that involves engineering considerations. Hydrologic soil groups are based on estimates of runoff potential. Soils are assigned to one of four groups according to the rate of water infiltration when the soils are not protected by vegetation, are thoroughly wet, and receive precipitation from long -duration storms. The four hydrologic soil groups are: Group A. Soils having a high infiltration rate (low runoff potential) when thoroughly wet. These consist mainly of deep, well drained to excessively drained sands or gravelly sands. These soils have a high rate of water transmission. Group B. Soils having a moderate infiltration rate when thoroughly wet. These consist chiefly of moderately deep or deep, moderately well drained or well drained soils that have moderately fine texture to moderately coarse texture. These soils have a moderate rate of water transmission. Group C. Soils having a slow infiltration rate when thoroughly wet. These consist chiefly of soils having a layer that impedes the downward movement of water or soils of moderately fine texture or fine texture. These soils have a slow rate of water transmission. Group D. Soils having a very slow infiltration rate (high runoff potential) when thoroughly wet. These consist chiefly of clays that have a high shrink -swell potential, soils that have a high water table, soils that have a claypan or clay layer at or near the surface, and soils that are shallow over nearly impervious material. These soils have a very slow rate of water transmission. If a soil is assigned to a dual hydrologic group (A/D, B/D, or C/D), the first letter is for drained areas and the second is for undrained areas. Surface runoff refers to the loss of water from an area by flow over the land surface. Surface runoff classes are based on slope, climate, and vegetative cover. The concept indicates relative runoff for very specific conditions. It is assumed that the surface of the soil is bare and that the retention of surface water resulting from irregularities in the ground surface is minimal. The classes are negligible, very low, low, medium, high, and very high. Report —Hydrologic Soil Group and Surface Runoff Absence of an entry indicates that the data were not estimated. The dash indicates no documented presence. Hydrologic Soil Group and Surface Runoff —Harnett County, North Carolina Map symbol and soil name Pct. of map unit Surface Runoff Hydrologic Soil Group Co—Coxville loam Coxville, drained 85 Low C/D Coxville, undrained 10 Low C/D USDA Natural Resources Web Soil Survey 5/9/2022 Conservation Service National Cooperative Soil Survey Page 1 of 2 Hydrologic Soil Group and Surface Runoff ---Harnett County, North Carolina Ample Storage - Irwin Hydrologic Soil Group and Surface Runoff —Harnett County, North Carolina Map symbol and soil name Pct. of map unit Surface Runoff Hydrologic Soil Group ExA—Exum very fine sandy loam, 0 to 2 percent slopes Exum 90 Low C GoA—Goldsboro loamy sand, 0 to 2 percent slopes, Southern Coastal Plain Goldsboro 85 — B MaA—Marlboro sandy loam, 0 to 2 percent slopes Marlboro 90 Low B MaB—Marlboro sandy loam, 2 to 6 percent slopes Marlboro 90 Low B Na—Nahunta loam Nahunta, drained 80 Low C/D Nahunta, undrained 10 Low C/D NoA—Norfolk loamy sand, 0 to 2 percent slopes Norfolk 83 — A NoB—Norfolk loamy sand, 2 to 6 percent slopes Norfolk 83 — A OrB—Orangeburg loamy sand, 2 to 6 percent slopes Orangeburg 90 Low A Data Source Information Soil Survey Area: Harnett County, North Carolina Survey Area Data: Version 19, Jan 21, 2022 USDA Natural Resources Web Soil Survey 5/9/2022 am Conservation Service National Cooperative Soil Survey Page 2 of 2 (S) fl �� CSD ENGINEERING Q 115 E. 1N1RD ST. REND&/, NC 27591 (919) 624-0997 o LUI � l � sca n d P 0 �QXOWOMi 0 100 200 400 Feet 1 "=200'Rli T ° A D112 DI2 DIi3 DI4 / 1.,� Q r' / n C D15 0 3 A TO Cal J 0 Dli DiE DIIO s � o DI8 � � ° � p 9° Q o 0 0 V 4, 4 � Q � ❑� o D L�Q a ,e� 4 � 2 10125122 C R/G \ 1" = 200' o \ JFO RBS ° \ a 21-0590 DA-1 1i 1 Sheet Na 1 of 1 CSD Engineering Subject: Stormwater Detention Design Date: 10/25/2022 Set Up By: JO Work: Pre -development Conditions - Outfall 1 Computed By: JO Checked By: HR Project: Ample Storage - Erwin JOB NO. 21-0590 Page No. 3 OF 8 Site Offsite DA= 4.65 AC 4.65 0.00 SUB AREAS Total Area Description CN Open Space 2.54 Managed Open Space 69 Open Space -UM 1.84 Unmanaged Open Space 61 Pavement 0.22 Drive Aisles & Parking 98 Sidewalk 0.00 Concrete Sidewalk 98 Building (Roof) 0.05 With roof drains 98 SCM 0.00 Wet Pond 80 Total 4.65 SOIL TYPES Hydrologic Soil Group Sub Area Area (AcresCN B Open Space 2.54 69 Open Space -UM 1.84 61 CURVE NUMBER CN = (Area 1 x CN 1) + (Area2 x CN2) + .... Sum(Areal, Area2...) CN = 67.5 SAY 68 TIME OF CONCENTRATION From TR-55 Worksheet: 12.0 min. REMARKS: CSD Engineering Subject: Stormwater Detention Design Date: 10/25/2022 Set Up By: JO Work: Pre -development Conditions - Outfall 1 Computed By: JO Checked By: HR Project: Ample Storage - Erwin JOB NO. 21-0590 Page No. 3 OF 8 Site Offsite DA= 4.65 AC 4.65 0.00 SUB AREAS Total Area Description CN Open Space 0.34 Managed Open Space 69 Open Space -UM 0.00 Unmanaged Open Space 61 Pavement 1.49 Drive Aisles & Parking 98 Sidewalk 0.02 Concrete Sidewalk 98 Building (Roof) 2.41 With roof drains 98 SCM 0.39 Wet Pond 80 Total 4.65 SOIL TYPES Hydrologic Soil Group Sub Area Area (AcresCN B Open Space 0.34 69 Open Space -UM 0.00 61 CURVE NUMBER CN = (Area 1 x CN 1) + (Area2 x CN2) + .... Sum(Areal, Area2...) CN = 94.4 SAY 94 TIME OF CONCENTRATION From TR-55 Worksheet: 12.0 min. REMARKS: Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 3 Pre -Development (NRCS) Hydrograph type = SCS Runoff Peak discharge = 3.876 cfs Storm frequency = 1 yrs Time to peak = 722 min Time interval = 2 min Hyd. volume = 11,359 cuft Drainage area = 4.650 ac Curve number = 68 Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 12.00 min Total precip. = 3.05 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Pre -Development (NRCS) Q (Cfs) Hyd. No. 3 -- 1 Year Q (Cfs) 4.00 4.00 3.00 3.00 2.00 2.00 1.00 1.00 0.00 - 0.00 0 120 240 360 480 600 720 840 960 1080 1200 1320 1440 1560 — Hyd No. 3 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 4 Post -Development (NRCS) Hydrograph type = SCS Runoff Peak discharge = 15.39 cfs Storm frequency = 1 yrs Time to peak = 720 min Time interval = 2 min Hyd. volume = 41,750 cuft Drainage area = 4.650 ac Curve number = 94 Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 10.00 min Total precip. = 3.05 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Q (Cfs) 18.00 15.00 12.00 •M .M 3.00 a�ais Post -Development (NRCS) Hyd. No. 4 -- 1 Year Q (Cfs) 18.00 15.00 12.00 • wo] 3.00 0 120 240 360 480 600 720 840 960 1080 1200 1320 1440 1560 Hyd No. 4 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 3 Pre -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 2 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 3.70 in Storm duration = 24 hrs Q (cfs) 7.00 N. 11 5.00 i 3.00 2.00 1.00 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Pre -Development (NRCS) Hyd. No. 3 -- 2 Year 0.00 ' ' 0 120 240 360 480 600 Hyd No. 3 Tuesday, 10 / 25 / 2022 = 6.471 cfs = 722 min = 17,748 cuft = 68 = 0 ft = 12.00 min = Type II = 484 Q (cfs) 7.00 . ee, 5.00 4.00 3.00 2.00 1.00 / I I I I I 1 1% 1 0.00 720 840 960 1080 1200 1320 1440 1560 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 4 Post -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 2 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 3.70 in Storm duration = 24 hrs Q (Cfs) 21.00 18.00 15.00 12.00 • ee 3.00 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Post -Development (NRCS) Hyd. No. 4 -- 2 Year Tuesday, 10 / 25 / 2022 = 19.19 cfs = 720 min = 52,757 cuft = 94 = 0 ft = 10.00 min = Type II = 484 Q (Cfs) 21.00 18.00 15.00 12.00 3.00 0.00 ' ' ' ' ' 0.00 0 120 240 360 480 600 720 840 960 1080 1200 1320 1440 1560 — Hyd No. 4 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 3 Pre -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 10 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 5.58 in Storm duration = 24 hrs Q (Cfs) 18.00 15.00 12.00 M ME 3.00 M Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Pre -Development (NRCS) Hyd. No. 3 -- 10 Year 120 240 360 480 600 Hyd No. 3 Tuesday, 10 / 25 / 2022 = 15.30 cfs = 722 min = 40,084 cuft = 68 = 0 ft = 12.00 min = Type II = 484 Q (Cfs) 18.00 15.00 12.00 Me] CM 0.00 720 840 960 1080 1200 1320 1440 1560 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 4 Post -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 10 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 5.58 in Storm duration = 24 hrs Q (Cfs) 35.00 30.00 25.00 20.00 15.00 10.00 5.00 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Tuesday, 10 / 25 / 2022 = 30.06 cfs = 720 min = 84,962 cuft = 94 = 0 ft = 10.00 min = Type II = 484 Q (Cfs) 35.00 30.00 25.00 20.00 15.00 10.00 5.00 0.00 1 1 1 10.00 0 120 240 360 480 600 720 840 960 1080 1200 1320 1440 — Hyd No. 4 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 3 Pre -Development (NRCS) Hydrograph type = SCS Runoff Peak discharge = 21.54 cfs Storm frequency = 25 yrs Time to peak = 720 min Time interval = 2 min Hyd. volume = 55,999 cuft Drainage area = 4.650 ac Curve number = 68 Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 12.00 min Total precip. = 6.76 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Pre -Development (NRCS) Q (Cfs) Hyd. No. 3 -- 25 Year Q (Cfs) 24.00 24.00 20.00 20.00 16.00 16.00 12.00 12.00 8.00 8.00 4.00 4.00 0.00 0.00 0 120 240 360 480 600 720 840 960 1080 1200 1320 1440 1560 — Hyd No. 3 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 4 Post -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 25 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 6.76 in Storm duration = 24 hrs Q (Cfs) 40.00 30.00 20.00 10.00 0.00 1 0 120 240 — Hyd No. 4 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Post -Development (NRCS) Hyd. No. 4 -- 25 Year 360 480 600 720 840 960 Tuesday, 10 / 25 / 2022 = 36.81 cfs = 720 min = 105,314 cuft = 94 = 0 ft = 10.00 min = Type II = 484 Q (Cfs) 40.00 30.00 20.00 10.00 0.00 1080 1200 1320 1440 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 3 Pre -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 100 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 8.74 in Storm duration = 24 hrs Q (Cfs) 35.00 30.00 25.00 20.00 15.00 10.00 5.00 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Tuesday, 10 / 25 / 2022 = 32.65 cfs = 720 min = 84,666 cuft = 68 = 0 ft = 12.00 min = Type II = 484 Q (Cfs) 35.00 30.00 25.00 20.00 15.00 10.00 5.00 0.00 0.00 0 120 240 360 480 600 720 840 960 1080 1200 1320 1440 1560 — Hyd No. 3 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Hyd. No. 4 Post -Development (NRCS) Hydrograph type = SCS Runoff Storm frequency = 100 yrs Time interval = 2 min Drainage area = 4.650 ac Basin Slope = 0.0 % Tc method = User Total precip. = 8.74 in Storm duration = 24 hrs Q (Cfs) 50.00 30.00 20.00 10.00 0.00 1 0 120 240 — Hyd No. 4 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Post -Development (NRCS) Hyd. No. 4 -- 100 Year 360 480 600 720 840 Tuesday, 10 / 25 / 2022 = 48.08 cfs = 720 min = 139,571 cuft = 94 = 0 ft = 10.00 min = Type II = 484 Q (Cfs) 50.00 w1 1I 30.00 20.00 10.00 ' 0.00 960 1080 1200 1320 1440 Time (min) Pond Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Pond No. 2 - Forebay Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 187.00 ft Stage / Storage Table Stage (ft) Elevation (ft) Contour area (sgft) Incr. Storage (cult) Total storage (cult) 0.00 187.00 105 0 0 1.00 188.00 300 194 194 2.00 189.00 580 432 626 3.00 190.00 910 739 1,365 4.00 191.00 1,290 1,094 2,460 5.00 192.00 1,720 1,500 3,959 Culvert / Orifice Structures [A] [B] [C] [PrfRsr] Rise (in) = 0.00 0.00 0.00 0.00 Span (in) = 0.00 0.00 0.00 0.00 No. Barrels = 0 0 0 0 Invert El. (ft) = 0.00 0.00 0.00 0.00 Length (ft) = 0.00 0.00 0.00 0.00 Slope (%) = 0.00 0.00 0.00 n/a N-Value = .000 .000 .000 n/a Orifice Coeff. = 0.00 0.00 0.00 0.00 Multi -Stage = n/a No No No Stage (ft) 5.00 4.00 3.00 2.00 IR111l 0.00 0 400 Storage Weir Structures [A] [B] [C] [D] Crest Len (ft) = 0.00 0.00 0.00 0.00 Crest El. (ft) = 0.00 0.00 0.00 0.00 Weir Coeff. = 0.00 0.00 0.00 0.00 Weir Type = --- --- --- --- Multi-Stage = No No No No Exfil.(in/hr) = 0.000 (by Wet area) TW Elev. (ft) = 0.00 Note: Culvert/Orifice outflows are analyzed under inlet (ic) and outlet (oc) control. Weir risers checked for orifice conditions (ic) and submergence (s). Stage / Storage 800 1,200 1,600 2,000 2,400 2,800 Elev (ft) 192.00 191.00 190.00 189.00 188.00 187.00 3,200 3,600 4,000 Storage (cuft) Pond Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Pond No. 1 - Main Pool Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 183.00 ft Stage / Storage Table Stage (ft) Elevation (ft) Contour area (sgft) Incr. Storage (cult) Total storage (cult) 0.00 183.00 06 0 0 1.00 184.00 270 105 105 2.00 185.00 750 490 595 3.00 186.00 1,270 999 1,594 4.00 187.00 1,815 1,534 3,128 5.00 188.00 2,395 2,098 5,226 6.00 189.00 3,135 2,756 7,983 7.00 190.00 4,090 3,602 11,584 8.00 191.00 5,070 4,571 16,155 9.00 192.00 7,810 6,390 22,545 Culvert / Orifice Structures Weir Structures [A] [B] [C] [PrfRsr] [A] [B] [C] [D] Rise (in) = 0.00 0.00 0.00 0.00 Crest Len (ft) = 0.00 0.00 0.00 0.00 Span (in) = 0.00 0.00 0.00 0.00 Crest El. (ft) = 0.00 0.00 0.00 0.00 No. Barrels = 0 0 0 0 Weir Coeff. = 0.00 0.00 0.00 0.00 Invert El. (ft) = 0.00 0.00 0.00 0.00 Weir Type = --- --- --- --- Length (ft) = 0.00 0.00 0.00 0.00 Multi -Stage = No No No No Slope (%) = 0.00 0.00 0.00 n/a N-Value = .000 .000 .000 n/a Orifice Coeff. = 0.00 0.00 0.00 0.00 Exfil.(in/hr) = 0.000 (by Contour) Multi -Stage = n/a No No No TW Elev. (ft) = 0.00 Stage (ft) 10.00 8.00 6.00 4.00 2.00 Note: Culvert/Orifice outflows are analyzed under inlet (ic) and outlet (oc) control. Weir risers checked for orifice conditions (ic) and submergence (s). Stage / Storage Elev (ft) 193.00 191.00 189.00 187.00 185.00 0.00 ' 1 1 1 1 1 1 1 1 1 1 1' 183.00 0 2,000 4,000 6,000 8,000 10,000 12,000 14,000 16,000 18,000 20,000 22,000 24,000 Storage Storage (cuft) Pond Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Pond No. 3 - Temporary Pool Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 192.00 ft Stage / Storage Table Stage (ft) Elevation (ft) Contour area (sgft) Incr. Storage (cult) Total storage (cult) 0.00 192.00 10,035 0 0 1.00 193.00 13,420 11,685 11,685 2.00 194.00 15,200 14,299 25,985 3.00 195.00 17,035 16,107 42,092 4.00 196.00 18,925 17,970 60,062 5.00 197.00 20,875 19,890 79,952 Culvert / Orifice Structures [A] [B] [C] [PrfRsr] Rise (in) = 18.00 1.50 0.00 0.00 Span (in) = 18.00 1.50 0.00 0.00 No. Barrels = 1 1 0 0 Invert El. (ft) = 191.60 192.00 0.00 0.00 Length (ft) = 44.00 2.00 0.00 0.00 Slope (%) = 0.43 0.30 0.00 n/a N-Value = .013 .010 .013 n/a Orifice Coeff. = 0.60 0.60 0.60 0.60 Multi -Stage = n/a Yes No No Stage (ft) 5.00 4.00 3.00 2.00 IR111l 0.00 0 8,000 Storage Weir Structures [A] [B] [C] [D] Crest Len (ft) = 5.00 15.00 0.00 0.00 Crest El. (ft) = 193.70 195.40 0.00 0.00 Weir Coeff. = 3.33 3.00 3.33 3.33 Weir Type = 1 Ciplti --- --- Multi-Stage = Yes No No No Exfil.(in/hr) = 0.000 (by Wet area) TW Elev. (ft) = 0.00 Note: Culvert/Orifice outflows are analyzed under inlet (ic) and outlet (oc) control. Weir risers checked for orifice conditions (ic) and submergence (s). Stage / Storage Elev (ft) 197.00 196.00 195.00 194.00 193.00 192.00 16,000 24,000 32,000 40,000 48,000 56,000 64,000 72,000 80,000 Storage (cuft) Pond Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Pond No. 4 - V Shelf Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 191.00 ft Stage / Storage Table Stage (ft) Elevation (ft) Contour area (sgft) Incr. Storage (cult) Total storage (cult) 0.00 191.00 5,070 0 0 1.00 192.00 7,810 6,390 6,390 Culvert / Orifice Structures Weir Structures [A] [B] [C] [PrfRsr] [A] [B] [C] [D] Rise (in) = 0.00 0.00 0.00 0.00 Crest Len (ft) = 0.00 0.00 0.00 0.00 Span (in) = 0.00 0.00 0.00 0.00 Crest El. (ft) = 0.00 0.00 0.00 0.00 No. Barrels = 0 0 0 0 Weir Coeff. = 0.00 0.00 0.00 0.00 Invert El. (ft) = 0.00 0.00 0.00 0.00 Weir Type = --- --- --- --- Length (ft) = 0.00 0.00 0.00 0.00 Multi -Stage = No No No No Slope (%) = 0.00 0.00 0.00 n/a N-Value = .000 .000 .000 n/a Orifice Coeff. = 0.00 0.00 0.00 0.00 Exfil.(in/hr) = 0.000 (by Contour) Multi -Stage = n/a No No No TW Elev. (ft) = 0.00 Stage (ft) 1.00 0.90 0.80 0.70 [oi:IH 0.50 0.40 0.30 0.20 0.10 000 Note: Culvert/Orifice outflows are analyzed under inlet (ic) and outlet (oc) control. Weir risers checked for orifice conditions (ic) and submergence (s) Stage / Storage Elev (ft) 192.00 191.90 191.80 191.70 ti0S91-1H 191.50 191.40 191.30 191.20 191.10 191 00 0 600 1,200 1,800 2,400 3,000 3,600 4,200 4,800 5,400 6,000 6,600 Storage Storage (cuft) CSD Engineering Subject: Stormwater Detention Design Date: 10/28/2022 Set Up By: JO Work: Forebay Volumen Check Computed By: JO Checked By: HR Project: Ample Storage - Erwin JOB NO. 21-0590 Page No. 1 OF 1 FOREBAY VOLUME = 3,959 CF MAIN BAY VOLUME = 22,545 CF From To Vegetated Shelf Volume = 6,390 CF 192.0 191.0 Surface area at Bottom of Shelf = 5,070 SF @ 191.0 3,95922,545 FB VOL. = x 100 = 17.6% 16,155 AVG. DEPTH = = 3.19 5,070 CSD Engineering Subject: Stormwater Detention Design Date: 10/25/2022 Set Up By: JO Work: POOL SIZING (TSS REMOVAL) Computed By: JO Checked By: HR Project: Ample Storage - Erwin JOB NO. 21-0590 Page No. DRAINAGE AREA = 4.65 AC IMP. AREA = 3.92 AC IMP = 3.92 x 100 = 84.3% 4.65 Equation 3 (NCDEQ Stormwater Design Manual, Part C-3): Average Depth Average Depth = 3.186 Volume of Main Pool = 22,545 Volume of Vegetated Shelf = 6,390 Area of Main Pool at Bottom of Vegetated Shelf = 5,070 FOR 85% TSS REMOVAL; SAY PERMANENT POOL AVERAGE DEPTH = 3.2' SA/DA 2.95% (NCDEQ SA/DA TABLE 1; Interpolated) SA = (SA/DA from TABLE 1) (DA) (43,560 SF/AC) = 5,975 ACTUAL SA @ 192.0 = 10,035 SF OKAY CSD Engineering Subject: Stormwater Detention Design Date: 10/25/2022 Set Up By: JO Work: 1" RUNOFF STORAGE Computed By: JO Checked By: HR Project: Ample Storage - Erwin JOB NO. 21-0590 Page No. 1 OF 1 USING "SIMPLE METHOD" DA = 4.65 ACRES IMPERVIOUS = 3.92 ACRES RV = 0.05 + 0.0091 3.92 1 = % IMP = x 100 = 84.3% 4.65 RV = 0.05 + (0.009) (1) _ VOLUME TO BE CONTROLLED VOLUME= (1")(RV)(DA)(I ft/l2in) VOLUME = 0.31 AC-ft VOLUME = 13,651 CF SA @ 192.0 ft = DEPTH OF RUNOFF ADDED TO PERMANENT POOL DEPTH = 13,651 10,035 ELEVATION PERM POOL + HR = 193.36 *ACTUAL POND STORAGE @ 193.36 * FROM STAGE/STORAGE TABLE 0.8087 in/in (REQUIRED) 10,035 sf 1.360 ft 16,833 CF OKAY Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 6 NRCS Outflow Hydrograph type = Reservoir Peak discharge = 1.873 cfs Storm frequency = 1 yrs Time to peak = 12.43 hrs Time interval = 2 min Hyd. volume = 35,283 cuft Inflow hyd. No. = 4 - Post -Development (NRCS)Max. Elevation = 193.92 ft Reservoir name = Temporary Pool Max. Storage = 24,908 cuft Storage Indication method used. Q (cfs) 18.00 15.00 12.00 M ME 3.00 M NRCS Outflow Hyd. No. 6 -- 1 Year 10 20 30 40 Hyd No. 6 Hyd No. 4 Q (cfs) 18.00 15.00 12.00 3.00 0.00 50 60 70 80 90 100 Time (hrs) Total storage used = 24,908 cuft Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 6 NRCS Outflow Hydrograph type = Reservoir Peak discharge = 5.602 cfs Storm frequency = 2 yrs Time to peak = 12.20 hrs Time interval = 2 min Hyd. volume = 46,267 cuft Inflow hyd. No. = 4 - Post -Development (NRCS)Max. Elevation = 194.18 ft Reservoir name = Temporary Pool Max. Storage = 28,878 cuft Storage Indication method used. Q (cfs) 21.00 18.00 15.00 12.00 • ee 3.00 0.00 ' 0 8 — Hyd No. 6 NRCS Outflow Hyd. No. 6 -- 2 Year 16 24 32 40 48 56 64 Hyd No. 4 Total storage used = 28,878 cuft Q (cfs) 21.00 18.00 15.00 12.00 3.00 0.00 72 Time (hrs) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 6 NRCS Outflow Hydrograph type = Reservoir Peak discharge = 12.70 cfs Storm frequency = 10 yrs Time to peak = 12.17 hrs Time interval = 2 min Hyd. volume = 78,425 cuft Inflow hyd. No. = 4 - Post -Development (NRCS)Max. Elevation = 194.94 ft Reservoir name = Temporary Pool Max. Storage = 41,077 cuft Storage Indication method used. NRCS Outflow Q (cfs) Hyd. No. 6 -- 10 Year Q (cfs) 35.00 35.00 30.00 30.00 25.00 25.00 20.00 20.00 15.00 15.00 10.00 10.00 5.00 5.00 0.00 0.00 0 2 4 6 8 10 12 14 16 18 20 22 24 26 Time (hrs) Hyd No. 6 — Hyd No. 4 Total storage used = 41,077 cuft Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 6 NRCS Outflow Hydrograph type = Reservoir Peak discharge = 14.40 cfs Storm frequency = 25 yrs Time to peak = 12.17 hrs Time interval = 2 min Hyd. volume = 98,754 cuft Inflow hyd. No. = 4 - Post -Development (NRCS)Max. Elevation = 195.38 ft Reservoir name = Temporary Pool Max. Storage = 48,963 cuft Storage Indication method used Q (cfs) 40.00 30.00 20.00 10.00 0.00 0 2 4 — Hyd No. 6 NRCS Outflow Hyd. No. 6 -- 25 Year 6 8 10 12 14 16 18 20 22 24 — Hyd No. 4 Total storage used = 48,963 cuft Q (cfs) 40.00 30.00 20.00 10.00 0.00 26 Time (hrs) Hydrograph Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Tuesday, 10 / 25 / 2022 Hyd. No. 6 NRCS Outflow Hydrograph type = Reservoir Peak discharge = 28.14 cfs Storm frequency = 100 yrs Time to peak = 12.13 hrs Time interval = 2 min Hyd. volume = 132,982 cuft Inflow hyd. No. = 4 - Post -Development (NRCS)Max. Elevation = 195.82 ft Reservoir name = Temporary Pool Max. Storage = 56,887 cuft Storage Indication method used. NRCS Outflow Q (cfs) Hyd. No. 6 -- 100 Year Q (cfs) 50.00 50.00 40.00 40.00 30.00 30.00 20.00 20.00 10.00 10.00 0.00 - 0.00 0 2 4 6 8 10 12 14 16 18 20 22 24 26 Time (hrs) Hyd No. 6 — Hyd No. 4 Total storage used = 56,887 cuft Hydraflow Hydrographs Extension for Autodesk@ Civil 3D0 by Autodesk, Inc. v2023 we] 5.00 ft Riser Meff im Top of pond _\ Elev. 197.00 15.00 ft Cipoletti weir W-i,B Ber 1198.40 44.0 LF of 18.0 in @ 0.43% Front View _25-yr NTS - Looking Downstream , 2-yr 1 00-yr 1 -yr Inflow hydrograph = 4. SCS Runoff - Post -Development {MRCS} I Project: Ample-Erwin.gpw I Tuesday, 10 / 25 / 2022 1 CSD Engineering Subject: Stormwater Detention Design Date: Set Up By: Work: Storage Pool Drawdown & Anti -Flotation Computed By Checked By Project: Ample Storage - Erwin JOB NO. 21-0590 Page No 10/28/2022 JO JO HR 1 OF 1 Pond must detain the first 1" of runoff and release it in 2 to 5 days INPUT Number of Drains = 1.0 Starting Water Elevation = 193.36 ft Diameter of Drains = 1.50 in Ending Water Elevation = 192.00 ft Orifice Coefficient = 1.00 ft Average Head = 0.68 ft Elevation of Drains = 192.00 ft OUTPUT Drawdown By the Orifice Equation: Average Flow = 0.08 cfs Volume of Storage = 16833 cfs Length of Drawdown = 207258 sec or 2.40 days OK Antiflotation: Unit weight of water: 62.40 pcf Volume of Riser: Max. Height of Water: 4.00 ft Length (ft) Width (ft) Thickness (ft) Riser Height: 25.00 sf 5.00 5.00 Volume of Riser: 100.00 cf Total Weight: 6240 pcf Factor of Safety: 1.5 Therefore, needed total weight = 9360 Ibs Weight of Riser Base: 2.1 ft height 788 Ibs 5.0 ft wide 0.5 ft thick For concrete grout: 5.0 ft long Use 150 pcf for weight of concrete 5.0 ft wide 2.30 ft high Total base weight: 9413 Ibs OKAY Date: 10/25/2022 Project Name: Ample Storage - Erw Station: Drive Skew: Size/Type Pipe: Type Entrance: Direction of Flow: Hydrological Method:* H.W. Control Elevation: Shoulder at St. Matthews Rd Elev. 0 Groove End North to South Rational Inlet 196 Invert Elev PIPE DATA SHEET Sheet 1 of 1 I.D. No. 21-0590 County: Harnett Designed By: JFO Checked By: HSR CL Elev.: H.W. LSo JU- U.Yo /U 194.05 ft L= 144 ft 197 ft H T. W Outlet Inv. Elev. 193.4 ft Plan Summary Data Drainage Area: 2.07 Design Freq.: 25 YR Design Disch.: 7.7 Design H.W. Elev.: 196.00 Q10 Disch.: 6.8 Q10 HW Elev.: 195.72 Overtopping Freq.: >100YR Overtopping Disch.: 10.6 Overtopping Elev.: 197.05 PIPE CULVERT ANALYSIS (English) rcp=.012, cmp=.024 Channel Specs Slope: 0.0034 Lt. Side Slope 4 n= 0.012 11 Base= 0 n= 0.065 Rt_ Side Slone 4 Size & Type TW ft Q* ft^3/s Nat. H.W. Allow.** H.W. Inlet Control Outlet Control HW ELEV. Vo Q/A Remarks SIZE # FREQ HW/D HW (ft) Ke d� (d,+D)/2 ho H L*So I HW Pipes* 18 1 2 YR 1.2 5.2 0.85 1.28 0.2 0.87 1.18 1.21 0.459 0.62 1.05 195.33 2.94 INLET CONTROL 18 1 10 YR 1.5 6.8 1.01 1.52 0.2 1.02 1.26 1.50 0.786 0.62 1.67 195.72 3.85 OUTLET CONTROL 18 1 25 YR 1.6 7.7 1.11 1.66 0.2 1.09 1.30 1.56 1.007 0.62 1.95 196.00 4.36 OUTLET CONTROL 18 1 100 YR 1.6 8.9 1.23 1.84 0.2 1.19 1.35 1.60 1.346 0.62 2.33 196.38 5.04 OUTLET CONTROL 18 1 OVERTOP 1.8 10.6 2.00 3.00 1.38 1.44 1.80 1.797 0.62 2.98 197.05 6.00 INLET CONTROL Notes: *Hydrological Method: C=0.6 (R/W and Future Development) Tc=15 min. (TR-55); IDF from NOAA Atlas 14 Point Precipitation Frequency Recommendation: Install 1 @ 18" R.C. Pipe Class III **Overtopping H.W: 2.98' Elevation = 197.05' at shoulder point 2 1 12 Outfall 3 4 5 13 6 7 10 9 8 11 Project File: Ample-Erwin.stm Number of lines: 13 Date: 10/28/2022 Storm Sewers v2023.00 Page 1 Station Len Drng Area Rnoff Area x C Tc Rain Total Cap Vel Pipe Invert Elev HGL Elev Grnd / Rim Elev Line ID coeff (1) flow full Line To Incr Total Incr Total Inlet Syst Size Slope Dn Up Dn Up Dn Up Line (ft) (ac) (ac) (C) (min) (min) (in/hr) (cfs) (cfs) (ft1s) (in) 00 (ft) 00 (ft) (ft) 00 I End 36.000 0.37 4.11 0.95 0.35 3.90 5.0 9.8 6.5 25.37 5185 3.59 36 0.56 190.80 191.00 195.40 195.44 193.80 197.50 D11 TO OUTFALL 2 1 113.931 0.38 3.74 0.95 0.36 3.55 5.0 9.2 6.6 23.55 42.81 3.33 36 0.35 191.00 191.40 195.74 195.87 197.50 197.50 D12 TO D11 3 2 67.460 0.18 3.36 0.95 0.17 3.19 5.0 8.9 6.7 21.43 39.34 3.03 36 0.30 191.40 191.60 195.95 196.01 197.50 197.70 D13 TO D12 4 3 65.006 0.33 2.96 0.95 0.31 2.81 5.0 8.5 6.8 1916 40.08 2.71 36 0.31 191.60 191.80 196.23 196.27 197.70 197.50 D14 TO D13 5 4 100.000 0.33 2.63 0.95 0.31 2A9 5.0 7.9 7.0 17A5 45.70 2.47 36 0.40 191.80 192.20 196.33 196.39 197.50 197.50 D15 TO D14 6 5 74.462 0.18 2.30 0.95 0.17 2.18 5.0 6.8 7.3 15.95 91.72 1.13 36(2b) 0.40 192.20 192.50 196.43 196.44 197.50 197.60 D16 TO D15 7 6 59.517 0.32 1.71 0.93 0.30 1.62 5.0 6.4 7.4 12.05 31.54 2.45 30 0.50 192.50 192.80 196.47 196.52 197.60 197.00 D17 TO D16 8 7 43.507 0.32 1.39 0.95 0.30 1.32 5.0 6.1 7.5 9.93 15.34 3.16 24 0.46 192.80 193.00 196.60 196.68 197.00 197.40 D18 TO D17 9 8 95351 0.00 0.59 0.00 0.00 0.56 0.0 5.5 77 4.34 6.80 2A5 18 0.42 193.00 193.40 196.91 197.07 197.40 198.40 MI-19 TO D18 10 9 74.990 0.59 0.59 0.95 0.56 0.56 5.0 5.0 7.9 4.44 6.64 2.51 18 0.40 193.40 193.70 197.11 197.25 198.40 197.40 D110 TO MI-19 11 8 99.918 0.48 0.48 0.95 0.46 0.46 5.0 5.0 7.9 3.61 7.43 2.04 18 0.50 193.20 193.70 196.91 197.03 197.40 198.30 D11 I TO D18 12 3 80.002 0.22 0.22 0.95 0.21 0.21 5.0 5.0 7.9 1.65 7.43 0.94 18 0.50 193.00 193.40 196.23 196.25 197.70 197.50 D112 TO D13 13 6 95.990 0.41 0.41 0.95 0.39 0.39 5.0 5.0 7.9 3.08 10.17 1.74 18 0.94 193.00 193.90 196.47 196.56 197.60 197.40 D113 TO D16 Project File: Ample-Erwin.stm Number of lines: 13 Run Date: 10/28/2022 NOTES:Intensity = 77.50 / (Inlet time + 12.30) 1 0.80; Return period =Yrs. 10 c = cir e = ellip b = box Storm Sewers v2023.00 Proj. file: Ample-Erwin.stm •. // •. ��■�--II��: �i��l�-■I� PA=��II��1��1�-�1��■1� it i 1 11 1 ii i it i Ii 1 ii Storm Sewers Proj. file: Ample-Erwin.strn IMUL2 �11 # Storm Sewers Proj. file: Ample-Erwin.stm Elev. (ft) 205.00 CO CD a 205.00 202.00 202.00 199.00 199.00 196.00 196.00 193.00 190.00 193.00 190.00 0 25 50 75 100 125 150 175 HGL EGL Reach (ft) 200 225 Storm Sewers Storm Sewer Profile Proj. file: Ample-Erwin.strn Elev. (ft) 209.00 Qc 0 -c J 0 209.00 205.00 205.00 MI M 201.00 201.00 M I 1 197.00 197.00 MI M—M 193.00 189.00 193.00 189.00 =��Mm MI 1 0 25 50 75 100 125 150 175 — HGL EGL Reach (ft) Storm Sewers 11 Storm Sewer Profile Proj. file: Ample-Erwin.stm Elev. (ft) 204.00 204.00 189.00 10 20 30 40 50 60 70 80 90 100 110 120 130 140 150 — HGL EGL Reach (ft) Storm Sewers Proj. file: Ample-Erwin.stm 1: / 1 s�s�--s��s- l l l l s-■-s��s-■- l l l i : / i s�s��s��s��stls��■ � � s�Il■��I �si��Is��Is�11�s1�■I��■I� s7=i�■�� sl��Is��Is�11�s1�■��■�� I�1■��I��I��I��Is�11�s1�■� �■�� i�1��I�sI��Is��Is�11�s1�■� ■�■�� 1■��I�sI��Is��Iss�ll�sslss ■�� 1■��I�sI��Is�s�Iss�ll�sslss i ��L� ssl■�■�I �ssl��ls��'��1 �s !''A'M i • :� ! MCI s111s-■F.7 77�-IIIssG7TTTTlle4T 7TT�--■-- i t it i ii i 11 1 Ii i MI / Ii 1 .11 . 1 ii Storm Sewers Page 1 of 2 CHANNEL ANALYSIS WORKBOOK 10/25/2022 Computed: JO Checked: HR Ample Storage - Erwin Q............... Design Year Discharge (cfs) A............ Flow Area (sf) Zreq........... (Q x n)/(1.49 x Slope^0.5) P............ Wetted Perimeter (ft) B............... Base Width (ft) R............ Hydraulic Radius (ft) d............... Normal Depth (ft) V............ Velocity (fps) Z1.............. Left Side Slope Zay......... A"R^2/3 Z2.............. Right Side Slope n............. Manning's Roughness Coefficient (Reference 1) PI ............... Plasticity Index of Soil (<10: Non -cohesive soil) e............... Soil Void Ratio Class ......... ,ASTM Soil Classification (Reference 1: Table 4.6) Ret. Class... Retardance Classification of Vegetal Covers (Reference 1: Table 4.1) Height........ Stem Height (feet) Cn............. Roughness Coefficient of Grass To .............. Mean Boundary Shear Stress (Reference 1; Eqn. 2.3); Applied Shear Stress on Grass Cf.............. Cover Factor (Reference 1: Table 4.5) T............... Shear Stress in Channel at maximum depth, pounds per square foot (psf) (Reference 1; Eqn. 2.4) Tp.............. Permissable Shear Stress (Reference 1: Table 2.3; Eqn. 4.5, 4.6, 4.7) Reference 1: FHWA Hydraulic Engineering Circular No. 15, Publication No. FHWA-NHI-05-114, 2005 Reference 2: Harnett County Soil Survey Station: St. Matthews Description: Roadside Channel US Driveway Q = 5.2 cfs Slope = 0.0210 ft/ft n = 0.042 Zreq = 1.00 ft RIPRAP,COBBLE, GRAVEL Type D50 (ft) Top W da n1 Vs 0.69 Re minD50 (ft) 2-year Soil (Sandy Loam) Vegetation Tp,soil Coefficients, c PI 12.0 Ret. Classl D Cn = 0.142 1 1.070 e 0.14 Height ft 0.25 To = 0.45 2 7.150 Class SM Condition Good Cf = 1 0.750 3 11.900 D75 in 0.020 Type Mixed Tp,veg 1 1.21 4 1.420 n (soil) 0.016 5 -0.610 _Tp,soil 0.04 1 6 0.000 GRAVEL/SOIL Type D75 (in) Tp,soil n (liner) Tp,liner ROLLED MAT/SOIL Type To Ti n (liner) Tp,liner TURF REINFORCE Type Tp,TRM Tp,VEG Cf,TRM Tp,VEG B d Z1 Z2 A P R V Zav T Tp Remarks 0.0 0.71 4.0 4.0 2.0 5.9 0.34 2.5 0.99 0.93 1.21 1 Stable Station: St. Matthews Description: Roadside Channel US Driveway Q = 6.8 cfs Slope = 0.0210 ft/ft n = 0.040 Zreq = 1.27 ft RIPRAP,COBBLE, GRAVEL Type D50 ft Top W da n1 Vs 0.72 Re minD50 ft 10-year Soil (Sandy Loam) Vegetation Tp,soil Coefficients, c PI 12.0 Ret. Class D Cn = 0.142 1 1.070 e 0.14 Height (ft) 0.25 To = 0.49 2 7.150 Class SM Condition Good Cf = 0.750 3 11.900 D75 (in) 0.020 Type Mixed Tp,veg 1.14 4 1.420 n soil 0.016 5 -0.610 Tp,soil 0.04 6 0.000 GRAVEL/SOIL Type D75 (in) Tp,soil n (liner) Tp,liner ROLLED MAT/SOIL Type To Ti n (liner) Tp,liner TURF REINFORCE Type Tp,TRM Tp,VEG Cf,TRM Tp,VEG B d Z1 Z2 A P R V Zav T Tp Remarks 0.0 0.77 4.0 4.0 2.4 6.3 0.37 2.8 1.23 1.01 1.14 1 Stable Page 2 of 2 CHANNEL ANALYSIS WORKBOOK 10/25/2022 Computed: JO Checked: HR Ample Storage - Erwin Q............... Design Year Discharge (cfs) A............ Flow Area (sf) Zreq........... (Q x n)/(1.49 x Slope^0.5) P............ Wetted Perimeter (ft) B............... Base Width (ft) R............ Hydraulic Radius (ft) d............... Normal Depth (ft) V............ Velocity (fps) Z1.............. Left Side Slope Zay......... A"R^2/3 Z2.............. Right Side Slope n............. Manning's Roughness Coefficient (Reference 1) PI ............... Plasticity Index of Soil (<10: Non -cohesive soil) e............... Soil Void Ratio Class ......... ,ASTM Soil Classification (Reference 1: Table 4.6) Ret. Class... Retardance Classification of Vegetal Covers (Reference 1: Table 4.1) Height........ Stem Height (feet) Cn............. Roughness Coefficient of Grass To .............. Mean Boundary Shear Stress (Reference 1; Eqn. 2.3); Applied Shear Stress on Grass Cf.............. Cover Factor (Reference 1: Table 4.5) T............... Shear Stress in Channel at maximum depth, pounds per square foot (psf) (Reference 1; Eqn. 2.4) Tp.............. Permissable Shear Stress (Reference 1: Table 2.3; Eqn. 4.5, 4.6, 4.7) Reference 1: FHWA Hydraulic Engineering Circular No. 15, Publication No. FHWA-NHI-05-114, 2005 Reference 2: Harnett County Soil Survey Station: St. Matthews Description: Roadside Channel DS Driveway Q = 5.2 cfs Slope = 0.0034 ft/ft n = 0.070 Zreq = 4.17 ft RIPRAP,COBBLE, GRAVEL Type D50 (ft) Top W da n1 Vs 0.36 Re minD50 (ft) 2-year Soil Sandy Loam Ve etation Tp,soil Coefficients, c PI 12.0 Ret. Classl D Cn = 0.142 1 1.070 e 0.14 Height ft 0.25 To = 0.12 2 7.150 Class SM Condition Good Cf = 1 0.750 3 11.900 D75 in 0.020 Type Mixed Tp,veg 1 3.39 4 1.420 n (soil) 0.016 5 -0.610 Tp,soil 0.04 1 6 0.000 GRAVEL/SOIL Type D75 (in) Tp,soil n (liner) Tp,liner ROLLED MAT/SOIL Type To Ti n (liner) Tp,liner TURF REINFORCE Type Tp,TRM Tp,VEG Cf,TRM Tp,VEG B d Z1 Z2 A P R V Zav T Tp Remarks 0.0 1.21 4.0 4.0 5.9 10.0 0.59 0.9 4.11 0.26 3.39 1 Stable Station: St. Matthews Description: Roadside Channel DS Driveway Q = 6.8 cfs Slope = 0.0034 ft/ft n = 0.065 Zreq = 5.08 ft RIPRAP,COBBLE, GRAVEL Type D50 ft Top W da n1 Vs 0.40 Re minD50 ft 10-year Soil (Sandy Loam) Vegetation Tp,soil Coefficients, c PI 12.0 Ret. Classl D Cn = 0.142 1 1.070 e 0.14 Height (ft) 0.25 To = 1 0.15 2 7.150 Class SM Condition Good Cf = 1 0.750 3 11.900 D75 (in) 0.020 Type Mixed Tp,veg 1 2.96 4 1.420 n soil 0.016 5 -0.610 Tp,soil 0.04 6 0.000 GRAVEL/SOIL Type D75 (in) Tp,soil n (liner) Tp,liner ROLLED MAT/SOIL Type To Ti n (liner) Tp,liner TURF REINFORCE Type Tp,TRM Tp,VEG Cf,TRM Tp,VEG B d Z1 Z2 A P R V Zav T Tp Remarks 0.0 1.47 3.0 3.0 6.5 9.3 0.70 1.0 5.10 0.31 2.96 1 Stable User Input Data Calculated Value Reference Data Designed By: CFO Date: 10/28/2022 Checked By: HSR Date: 10/28/2022 Company: Project Name: Project No.: Site Location (City/Town) Ervin, NC Culvert Id. Driveway Total Drainage Area (acres) 2.07 Step 1. Determine the tailwater depth from channel characteristics below the pipe outlet for the design capacity of the pipe. If the tailwater depth is less than half the outlet pipe diameter, it is classified rninirnurn tailwater condition_ If it is greater than half the pipe diameter, it is classified maximum condition. Pipes that outlet onto wide flat areas with no defined channel are assumed to bane a nairtimuma tailwater condition unless reliable food stage elevations show otherwise. Outlet pipe diameter, Do (in.) 18 Tailwater depth (in.) 18 Minimum/Maximum tailwater? Max TW (Fig. 8.06b) Discharge (cfs) 6.8 Velocity (ft./s) 3.85 Step 2. Based on the tarlwater conditions deterinurM rn step 1, enter Figure 8 06a or Figure 8 06b, and determine dsa riprap sin and minimum apron length (L J The d� size is the median stone size in a well -graded riprap apron. Step 3. Determine apron width at the pipe outlet, the apron shape, and the apron width at the outlet end from the same figure used in Step 2. Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d5g, (ft.) 0.5 Minimum apron length, La (ft.) 9 Apron width at pipe outlet (ft.) 4.5 4.5 Apron shape Rectangle Apron width at outlet end (ft.) 1.5 5.1 Step 4. Determine the --in n stone diameter: d,,,,, = 1.5 x d. Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0 0.75 Step 5, Determine the apron tluclaiess: Apron thickness = 1.5 x d Minimum TW Maximum TW Apron Thickness(ft.) 0 1.125 Step 6. Fit the riprap apron to the site by making it level for the minimum length, 1r, from Figure 8 06a or Figure 8 06b_ Extend the apron farther downstream and along channel banks until stability is assured_ Keep the apron as straight as possible and align it with the flow of the receiving stream. Make any necessary alignment bends near the pipe outlet so that the entrance into the receiving stream is straight. Some locations may require lining of the entire charnel cross section to assure stability It may be necessary to increase the sire of riprap where protection of the channel side slopes is necessary (Appendix 8.05). Where overfills exist at pipe outlets at flows are excessive, a plunge pool should be considered, see page 9.06.8. User Input Data Calculated Value Reference Data Designed By: CFO Date: 10/28/2022 Checked By: HSR Date: 10/28/2022 Company: Project Name: Ample Storage Project No.: Site Location (City/Town) Ervin, NC Culvert Id. 36" Pipe In Total Drainage Area (acres) 4.11 Step 1. Determine the tailwater depth from channel characteristics below the pipe outlet for the design capacity of the pipe. If the tailwater depth is less than half the outlet pipe diameter, it is classified mimmurn tailwater condition_ If it is greater than half the pipe diameter, it is classified maximum condition. Pipes that outlet onto wide flat areas with no defined channel are assumed to bave a nairtimuma tailwater condition unless reliable food stage elevations show otherwise. Outlet pipe diameter, Do (in.) 36 Tailwater depth (in.) 36 Minimum/Maximum tailwater? Max TW (Fig. 8.06b) Discharge (cfs) 25.4 Velocity (ft./s) 3.6 Step 2. Based on the tarlwater conditions deterinurM rn step 1, enter Figure 8 06a or Figure 8 06b, and determine dsa riprap sin and minimum apron length (L J The d� size is the median stone size in a well -graded riprap apron. Step 3. Determine apron width at the pipe outlet, the apron shape, and the apron width at the outlet end from the same figure used in Step 2. Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d5g, (ft.) 0.75 Minimum apron length, La (ft.) 12 Apron width at pipe outlet (ft.) 9 9 Apron shape Rectangle Apron width at outlet end (ft.) 3 7.8 Step 4. Determine the —xiamm stone diameter: d,,,,, = 1.5 x d. Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0 1.125 Step 5, Determine the apron tluclaiess: Apron thickness = 1.5 x d Minimum TW Maximum TW Apron Thickness(ft.) 0 1.6875 Step 6. Fit the riprap apron to the site by making it lerel for the minimum length, 1r, from Figure 8 06a or Figure 8 06b_ Extend the apron farther downstream and along channel banks until stability is assured_ Keep the apron as straight as possible and align it with the flow of the receiving stream. Make any necessary alignment bends near the pipe outlet so that the entrance into the receiving stream is straight. Some locations may require lining of the entire charnel cross section to assure stability It may be necessary to increase the sire of riprap where protection of the channel side slopes is necessary (Appotidir 8.05). Where overfills exist at pipe outlets at flows are excessive, a plunge pool should be considered, see page 9.06.8. User Input Data Calculated Value Reference Data Designed By: CFO Date: 10/28/2022 Checked By: HSR Date: 10/28/2022 Company: Project Name: Ample Storage Project No.: Site Location (City/Town) Ervin, NC Culvert Id. Pond Outlet Total Drainage Area (acres) 6.17 Step 1. Determine the tailwater depth from channel characteristics below the pipe outlet for the design capacity of the pipe. If the tailwater depth is less than half the outlet pipe diameter, it is classified minirnuru tailwater condition_ If it is greater than half the pipe diameter, it is classified maximum condition. Pipes that outlet onto wide flat areas with no defined channel are assumed to have a mr-inum tailwater condition unless reliable flood stage elevations show otherwise. Outlet pipe diameter, Do (in.) 18 Tailwater depth (in.) 12 Minimum/Maximum tailwater? Max TW (Fig. 8.06b) Discharge (cfs) 10 Velocity (ft./s) 4.6 Step 2. Based on the tailwater conditions determined in step 1, enter Figure 8 06a or Figure 8 06b_ and determine dsa riprap sin and minimum apron length (L J The d� size is the median stone size in a well -graded riprap apron. Step 3. Determine apron width at the pipe outlet, the apron shape, and the apron width at the outlet end from the same figure used in Step 2. Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d5g, (ft.) 0.5 Minimum apron length, La (ft.) 8 Apron width at pipe outlet (ft.) 4.5 4.5 Apron shape Rectangle Apron width at outlet end (ft.) 1.5 4.7 Step 4. Determine the --in n stone diameter: d,,,,, = 1.5 x d. Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0 0.75 Step 5. Determine the apron tluclaiess: Apron thickness = 1.5 x d Minimum TW Maximum TW Apron Thickness(ft.) 0 1.125 Step 6. Fit the riprap apron to the site by making it lexel for the minimum length, 1r, from Figure 8 06a or Figure 8 06b_ Extend the apron farther downstream and along channel banks until stability is assured_ Keep the apron as straight as possible and align it with the flow of the receiving stream. Make any necessary alignment bends near the pipe outlet so that the entrance into the receiving stream is straight. Some locations may require lining of the entire channel cross section to assure stability It may be necessary to increase the sire of riprap where protection of the channel side slopes is necessary (Appendix 8.05). Where ovcrfalls exist at pipe outlets at flows are excessive, a plunge pool should be considered, see page 9.06.8. Figure 8.06b: Design of outlet protection from a round pipe flowing full, maximum tailwater condition (Tw>=0.5 diameter) Discharge (Olsec) Curves may not be extrapolated_ Figure 8.O0b Design of outlot protection from a round pipe flowing full. maximum wilwater condition (T. >_ 0.5 diameter). 8.06.4 Rev.1"3 Project: Ample Storage Basin Dimension Worksheet ESC Date: 10/25/2022 ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- ----------------- Pond Report Hydraflow Hydrographs Extension for Autodesk® Civil 3D® by Autodesk, Inc. v2023 Wednesday, 10 / 26 / 2022 Pond No. 5 - Sediment Basin Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 192.00 ft Stage / Storage Table Stage (ft) Elevation (ft) Contour area (sgft) Incr. Storage (cult) Total storage (cult) 0.00 192.00 10,035 0 0 1.00 193.00 12,220 11,108 11,108 2.00 194.00 14,180 13,187 24,295 Culvert / Orifice Structures Weir Structures [A] [B] [C] [PrfRsr] [A] [B] [C] [D] Rise (in) = 0.00 0.00 0.00 0.00 Crest Len (ft) = 0.00 0.00 0.00 0.00 Span (in) = 0.00 0.00 0.00 0.00 Crest El. (ft) = 0.00 0.00 0.00 0.00 No. Barrels = 0 0 0 0 Weir Coeff. = 0.00 0.00 0.00 0.00 Invert El. (ft) = 0.00 0.00 0.00 0.00 Weir Type = --- --- --- --- Length (ft) = 0.00 0.00 0.00 0.00 Multi -Stage = No No No No Slope (%) = 0.00 0.00 0.00 n/a N-Value = .000 .000 .000 n/a Orifice Coeff. = 0.00 0.00 0.00 0.00 Exfil.(in/hr) = 0.000 (by Wet area) Multi -Stage = n/a No No No TW Elev. (ft) = 0.00 Note: Culvert/Orifice outflows are analyzed under inlet (ic) and outlet (oc) control. Weir risers checked for orifice conditions (ic) and submergence (s). Stage (ft) Stage / Storage Elev (ft) 2.00 1.80 1.60 1.40 1.20 1.00 0.80 0.60 0.40 0.20 0 00 194.00 193.80 193.60 193.40 193.20 193.00 192.80 192.60 192.40 192.20 19200 0 2,000 4,000 6,000 8,000 10,000 12,000 14,000 16,000 18,000 20,000 22,000 24,000 26,000 Storage Storage (cuft) Ample Storage Skimmer Sizing 10/25/2022 Calculate Skimmer Size Basin Volume in Cubic Feet jDays to Drain* I*1n NC assume 3 days to drain 24,295 Cu.Ft 3 Days Skimmer Size Orifice Radius Orifice Diameter 3.0 Inch 1.4 Inch[es] 2.7 Inch[es] Estimate Volume of Basin Length Width Top of water surface in feet Feet VOLUME 0 Cu. Ft. Bottom dimensions in feet Feet Depth in feet Feet