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Home My WebLink AboutSW1210502_C-RPT-1901780-STORMWATER_REPORT-2021-05-14_20210519E 1, Architecture An Employee -Owned Company Engineering Environmental Land Surveying . � Companies Stormwater Management Report For the proposed development located at: Boylston Highway Mills River, North Carolina Prepared for Submission to: Town of Mills River, North Carolina December 5, 2019 Revised: January 30, 2020 Revised: May 14, 2021 t``ttt54111 ff+rrrr � A CAROL !�� sslo. rr 'LSD r� � V cno'•c��'GIN��4; � ;= ''+lrrnri ultriy, Prepared for: Samet Corporation P.O. Box 8050 Greensboro, NC 27419 Prepared by: Architecture Engineering Environmental . Land Surveying Companies BL Companies 3420 Toringdon Way, Suite 210 Charlotte, NC 28277 (704) 565-7070 BL Project Number: 1901780 Architecture pool' Engineering . Environmental Land Surveying Companies Contents An Employee -Owned Company Stormwater Management Report ExecutiveSummary......................................................................................................................................1 Existing Site Conditions and Hydrologic Conditions................................................................................... 2 Developed Site Conditions and Hydrologic Conditions............................................................................... 6 StormwaterManagement............................................................................................................................13 Summary.....................................................................................................................................................14 Appendix A: Location Maps Figure 1: USGS Location Map Figure 2: Aerial Location Map Figure 3: NRCS Soil Survey Map with Hydrologic Soil Group Data Figure 4.0: FEMA Federal Insurance Rate Map Figure 4.1: FEMA Firmette Map Figure 5.0: NOAA Atlas 14 Storm Depths Figure 5.1: NOAA Atlas 14 Storm Intensities Appendix B: Pre -development Hydrology (2-, 10-, and 25-year storms) Appendix C: Post -development Hydrology (Water Quality Storm, 2-, 10-, and 25-year storms) Appendix D: Post -development Hydraulics Appendix E: Engineering Calculations Riprap Outlet Protection Calculations Appendix F: Drainage Maps ED-1 — Existing Drainage Area Map PD-1 — Proposed Drainage Area Map PD-2 — Proposed Catchment Drainage Area Map Appendix G: Soil Report Appendix H: Geotechnical Report Appendix I: Site Operations and Maintenance Plan E 1, Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report Land Surveying D,ww- Companies Executive Summary This report has been prepared in support of a Permit Application submission to the North Carolina Department of Environmental Quality (NCDEQ) by Samet Corporation for the proposed development at the intersection of Boylston Highway and Fanning Fields Road. The subject property is approximately 34.23 acres in size and comprised of tax parcel #9975227 and the land to be acquired as part of the land exchange agreement with tax parcels #800374 and #9968359. The parcels are currently undeveloped, forested and farmland areas. Several pockets of wetlands and streams, including a USGS "blue -line" stream, reside on the eastern and western portions of the property, leaving the developable land between them. The USGS "blue -line" stream, also known as "Stream 1", requires a 30-foot buffer. However, no proposed development will impact any of the streams, associated buffers, or wetlands located on -site. The property is bordered to the north and west by Boylston Highway (Rte. 280), to the south by Miles View Drive, and to the east by undeveloped pasture and farmland. Several industrial and commercial uses, such as FedEx Ground, exist across Boylston Highway and Pepsi Bottling Group resides to the south of Miles View Drive. The subject site and all abutting properties are located in the MR-LI (MR- Light Industrial) zoning district per the Town of Mills River zoning regulations and map. Generally, the property slopes toward Boylston Highway. Approximately half of the property slopes northwestward toward "Stream 3" and "Stream 4" (surrounded by "Wetland 3") that discharge to the northwest, underneath Boylston Highway. The other half of the property similarly slopes northeastward toward "Wetland 1" and "Stream 1" that also discharges to the north, underneath Boylston Highway. There are minor areas that drain away from the streams, but ultimately slope toward Boylston Highway as well. The steepest grades of the site reside in the southern corner of the site where a large ridge divides the site to slope toward either stream. Some off -site area within the Boylston Highway right-of-way steeply slopes toward the road and into the points of interest in this drainage analysis as well. Elevations of the existing topography within the subj ect property range from 2180 feet at the southern top of the ridge down to 2084 feet at the inlet receiving water from "Stream 1" on the eastern portion of the property. The proposed stormwater management system is designed to be in compliance with the 2013 NC Erosion and Sediment Control Planning and Design Manual and the NCDEQ Stormwater Design Manual for a high -density project. A HydroCAD model, using TR-55 methodology, was developed to evaluate the existing and proposed drainage conditions of the property. The results of the analysis demonstrate that there will not be an increase in peak stormwater runoff rates for the 2-, 10- and 25-year storm events. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 1 Architecture . Engineering . Environmental Land Surveying Companies An Employee -Owned Company Stormwater Management Report The stormwater runoff from the proposed development for all intensities and durations of rainfall up to the 25-year storm event shall not exceed that of the existing conditions. Infiltration has conservatively been considered in the drainage calculations using exfiltration rates recommended by NRCS Web Soil Survey data. The exfiltration rate utilized is 0.2 in/hr. The NCDEQ stormwater regulations require high density projects to treat the design storm depth in a stormwater control measure. The stormwater control measures incorporated into this project include underground stormwater infiltration/detention systems with isolator rows and BayFilter systems to remove sediment and nutrients. The impervious area stormwater runoff will be captured by catch basins with deep sumps for pretreatment. Stormwater will then be conveyed through the proposed storm sewer system and discharge into several subsurface detention/infiltration basin facilities. The detention/infiltration systems have been designed to dewater the 1" design volume within 72 hours or less. The stormwater will then outlet through the combined BayFilter and outlet control structures and discharge into the wetlands and streams. All other landscaped areas will continue to flow as they currently do today either directly into the streams or directly into the Boylston Highway storm sewer system. Existing Site Conditions and Hydrologic Conditions General Site Information The existing site consists of undeveloped forested and farmland areas. Existing wetlands and streams located in the western corner of the property and the eastern portion of the property frame the undeveloped pasture in the center of the site. The site soils identified by the United States Department of Agriculture (USDA) Natural Resources Conservation Services (MRCS) are Delanco (dillard) loam, 2 to 7 percent slopes, Hayesville loam, 2 to 7 percent slopes, 7 to 15 percent slopes and 15 to 25 percent slopes. Per the USDA the NRCS Hydrologic Soil Group the soil rating for within the project area are C, B, C and C respectively. A copy of the USDA NRCS Hydrologic Soil Group Map is included in Appendix A for reference. Per the FEMA Flood Insurance Rate Map Number 3700964200K for North Carolina, map revised date: January 6, 2010, the site resides in FEMA Flood Hazard Zone X. This is defined as areas determined to be outside the 0.2% annual chance floodplain. A copy of the FEMA Flood insurance rate map is included in Appendix A for reference. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 2 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report D � Land Surveying Companies Existing Hydrologic Conditions The existing site drainage area that was analyzed totals 55.78 acres and is approximately 0.3% impervious. There is currently no existing stormwater management system onsite, as the subject site is undeveloped. The majority of the stormwater runoff generated on -site overland flows into either the stream located in the western corner of the site or the stream on the eastern portion of the site. Both of these streams are piped northwestward underneath Boylston Highway via two 30" RCP culverts and downstream to the other side of the highway. The rest of the stormwater from the subject property flows untreated to Boylston Highway through overland flow and into the highway storm sewer system within the right-of-way. Eventually all of the stormwater that is generated from the site will discharge ultimately downstream of the site into the McDowell Creek and/or the French Broad River. The following is a brief analysis of the existing design points as shown on the enclosed Existing Drainage Plan (ED-1), in Appendix F. Existing Drainage Area 1 (EDA-1): This drainage area is 0.93 acres and is approximately 0.0% impervious, consisting mainly of pasture, grassland or range, and a small portion of woodland. EDA-1 encompasses the small western corner of the site, due west of "Stream 3". Stormwater runoff from this drainage area flows westward into an existing 24" RCP culvert under Fanning Fields Road. This culvert then outlets to a grassed area within the right-of-way, noted as Point of Interest 1 (POI-1). Stormwater is eventually collected by a 30" RCP culvert at the intersection of Boylston Highway and Fanning Fields Road and discharges under Boylston Highway, flows to the McDowell Creek and ultimately reaches the French Broad River. Existing Drainage Area 2 (EDA-2): This drainage area is 11.55 acres and is approximately 0.0% impervious, consisting primarily of pasture, grassland or range with a portion of woodland. All the EDA-2 watershed's runoff overland flows into "Wetland 3", "Stream 3" and "Stream 4". EDA-2 includes nearly a fifth of the total land analyzed in this drainage study. Stormwater runoff flows in the northwestwardly direction into "Stream 3" and "Stream 4". These streams converge and convey runoff through a 30" RCP culvert under Boylston Highway, Point of Interest 2 (P0I- 2). Ultimately, all the stormwater that is generated from EDA-2 will discharge downstream into the McDowell Creek and eventually into the French Broad River. Existing Drainage Area 3 (EDA-3): This drainage area is 3.80 acres and is approximately 0.0% impervious, consisting primarily of pasture, grassland or range with a portion of woodland. EDA- 3 is located toward the center of the property, fronting Boylston Highway. Stormwater flows overland into a drainage ditch along the right-of-way and is collected into a riprap basin inlet. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 3 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report D � Land Surveying Companies Runoff is then discharged through a 36" RCP culvert under Boylston Highway, Point of Interest 3 (POI-3). Ultimately, all the stormwater that is generated from EDA-3 will discharge into the McDowell Creek and eventually into the French Broad River. Existing Drainage Area 4 (EDA-4): This drainage area is 1.68 acres and is approximately 0.0% impervious, consisting primarily of woodland with a portion of pasture, grassland or range. EDA- 4 is located toward the center of the property, fronting Boylston Highway. Stormwater flows overland into a yard drain inlet along the right-of-way that connects into the Boylston Highway storm sewer system, Point of Interest 4 (POI-4). Ultimately, all the stormwater that is generated from EDA-4 discharges downstream of the site into the French Broad River. Existing Drainage Area 5 (EDA-5): This drainage area is 34.29 acres and is approximately 0.6% impervious, consisting primarily of woodland with a portion of pasture, grassland or range from both onsite and offsite area. There is a small amount of existing development in the neighboring southern property consisting of a tennis court and a building, giving this drainage area a very minor area of impervious coverage. EDA-5 includes over half of the total land analyzed in this drainage study. All the EDA-5 watershed's runoff overland flows into "Wetland 1", "Wetland 2", and "Stream 1". Stormwater runoff flows in the northwestwardly direction into "Stream 1". A portion of this drainage area discharges to "Wetland 2" in the center of the site which is hydrologically connected to "Stream 1" through a drainage ditch. "Stream 1" then discharges through a concrete headwall and into a 30" RCP culvert that conveys runoff under Boylston Highway, Point of Interest 5 (POI-5). Ultimately, all the stormwater that is generated from EDA-5 will discharge downstream into the French Broad River. Existing Drainage Area 6 (EDA-6): This drainage area is 3.53 acres and is approximately 0.0% impervious, consisting primarily of woodland with a portion of pasture, grassland or range. EDA- 6 encompasses the small northeastern corner of the site, located east of "Stream 1". A small ridge sends stormwater runoff north through an existing concrete headwall and into a 30" RCP culvert connecting into the Boylston Highway storm sewer system, Point of Interest 6 (POI-6). Ultimately, all of the stormwater that is generated from EDA-6 discharges downstream of the site into the French Broad River. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com E 1, Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report Land Surveying 0'WW_ Companies Table 1- Pre -Development (Existing Conditions) Drainage Characteristics Drainage Area Total Area SF Composite Curve Number Imperviousness Cover % Time of Concentration Minutes EDA-1 40,701 78 0.0% 6.20 EDA-2 503,020 75 0.0% 32.80 EDA-3 165,534 78 0.0% 14.80 EDA-4 73,222 75 0.0% 38.90 EDA-5 1,493,578 73 0.6% 41.40 EDA-6 153,765 F 69 0.0% 27.80 Table 2 - Pre -Development Conditions Peak Flows Analysis Peak Flows CFS Point Description 2-YR 10-YR 25-YR 100-YR Flow to Drainage Ditch and P0I-1 24" RCP at corner of Miles 1.88 3.29 4.15 5.52 View Drive and Fanning Field Road Flow to Wetland 3 and P0I-2 Streams 3 & 4 and 30" RCP 9.81 19.00 24.93 34.96 along Boylston Highway P0I-3 Flow to Drainage Ditch & 30" 5.53 9.94 12.68 17.13 RCP along Boylston Highway P0I-4 Flow to Drainage Ditch & 15" 1.37 2.66 3.49 4.90 RCP along Boylston Highway Flow to Wetland 1 and P0I-5 Stream 1 and 30" RCP along 35.55 70.26 92.59 129.95 Boylston Highway Flow to northeastern corner of P0I-6 site and 30" RCP along 2.22 4.88 6.66 9.75 Boylston Highway 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report D � Land Surveying Companies Developed Site Conditions and Hydrologic Conditions General Site Information The proposed site development consists of a proposed 110,866 s.f. industrial warehouse building, associated impervious parking and drives, sidewalks, drainage infrastructure, subsurface detention facilities, lawn with various landscape plantings, and proposed utilities to serve the development. The existing 34.23-acre project parcel has two areas containing streams and wetlands on either side of the proposed development, though the development will not impact either area or the USGS "blue -line" stream known as "Stream 1". Proposed Hydrologic Conditions For the purposes of the drainage analysis and discussion, the proposed development has been analyzed as thirteen sub -drainage basins as illustrated on the enclosed Proposed Drainage Plan (PD- 1) located in Appendix E. The proposed analysis includes a total of 56.03 acres, adding some land in the southern corner for a proposed grading easement, and is approximately 30.4% impervious. The intent of the proposed site drainage is to mimic existing drainage patterns to the maximum extent practical. The site stormwater system will provide stormwater quantity and quality improvements through several underground detention/infiltration basins and BayFilter filtration devices. Additionally, a formalized street sweeping program for the impervious surfaces will contribute to the sediment removal onsite and deep sump catch basins will aid in pretreatment. These measures will treat the stormwater quality flow through structural means to provide water quality treatment in conformance with the North Carolina Department of Environmental Quality (NCDEQ) Stormwater Design Manual. Riprap energy dissipators are proposed at the flared end structure outlets discharging to all streams, wetlands, and drainage ditches throughout the site. The riprap will protect the discharge point from erosion and scouring. Engineering calculations and sizing can be found on the "Details Sheets", sheet DN-7, of the land development plans. Please refer to the "Details Sheets" in the land development plans for the Operation and Maintenance Schedule and Appendix I for the site Operations and Maintenance Plan which details the maintenance requirements for the subsurface detention facilities, as well as the various stormwater management components proposed for the development. For the hydrologic analysis, the developed site retains the same Points of Interest as the existing model. The following drainage areas were developed to model the proposed site improvements. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 6 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report D � Land Surveying Companies Proposed Drainage Area 1 (PDA-1): PDA-1 is a 0.51-acre drainage area consisting mainly of pasture, grassland or range, and a small portion of woodland, approximately 0.0% impervious. Similar to Existing Drainage Area 1 (EDA-1), PDA-1 encompasses the small western corner of the site to the west of "Stream 3" but incorporates less land area due to the proposed development and grading. Stormwater runoff from this drainage area flows in the westerly into an existing 24" RCP culvert under Fanning Fields Road. This culvert then outlets to a grassed area within the right- of-way, noted as Point of Interest 1 (POI-1). Stormwater is eventually collected by a 30" RCP culvert at the intersection of Boylston Highway and Fanning Fields Road and discharges under Boylston Highway, flows to the McDowell Creek and ultimately reaches the French Broad River. Proposed Drainage Area 2 (PDA-2): This drainage area is 4.37 acres and is approximately 1.1% impervious, consisting primarily of pasture, grassland or range, a small portion of proposed grass, a portion of woodland, and the proposed driveway within the right-of-way. PDA-2 also contains "Wetland 3", "Stream 3" and "Stream 4" in which all of this watershed's runoff overland flows into. PDA-2 discharges untreated and un-detained stormwater runoff directly into "Stream 3" and "Stream 4" as it does in current conditions . These streams converge and convey runoff through a 30" RCP culvert under Boylston Highway, Point of Interest 2 (POI-2). Ultimately, all the stormwater that is generated from EDA-2 will discharge downstream into the McDowell Creek and eventually into the French Broad River. Proposed Drainage Area 2A (PDA-2A): PDA-2A is a 1.69-acre drainage area which consists of the proposed parking in the southwestern portion of the site, a portion of the circulating drive, and minor areas of interior landscaping. This area is approximately 55.8% impervious and stormwater is captured in a proposed storm sewer network of catch basin inlets that convey runoff into a subsurface stormwater detention facility SWMB-2. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm events are routed through the outlet control portion of the structure. Stormwater discharges to a flared end structure at the beginning of"Stream 3". "Stream 3" converges with "Stream 4" and conveys runoff through a 30" RCP culvert under Boylston Highway, Point of Interest 2 (POI-2). Ultimately, all the stormwater that is generated from PDA-2A will discharge downstream into the McDowell Creek and eventually into the French Broad River. Proposed Drainage Area 2B (PDA-2B): PDA-213 is a 4.43-acre drainage area which consists of the proposed parking in the southern corner of the site, a portion of the circulating drive, and minor areas of interior landscaping. This area is approximately 88.9% impervious and stormwater is captured in a proposed storm sewer network of catch basin inlets that convey runoff into a subsurface stormwater detention facility SWMB-3. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm events are routed through the 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 7 Architecture . Engineering . Environmental Land Surveying Companies An Employee -Owned Company Stormwater Management Report outlet control portion of the structure. Stormwater discharges to a flared end structure into "Wetland 3" at the beginning of "Stream 4". "Stream 4" converges with "Stream 3" and conveys runoff through a 30" RCP culvert under Boylston Highway, Point of Interest 2 (POI-2). Ultimately, all the stormwater that is generated from PDA-213 will discharge downstream into the McDowell Creek and eventually into the French Broad River. Proposed Drainage Area 2C (PDA-2C): PDA-2C is a 0.57-acre drainage area consisting mainly of the impervious proposed western driveway and proposed grass with minor areas of existing pasture, grassland or range, approximately 42.5% impervious. PDA-2C is located in the western corner of the site, due west of "Stream 3". Stormwater runoff from this drainage area flows northwestward down the driveway and is captured in curb inlet catch basins. into a subsurface stormwater detention facility SWMB-I. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm events are routed through the outlet control portion of the structure. Stormwater discharges to a flared end structure directed towards "Stream 3". "Stream 3" converges with "Stream 4" and conveys runoff through a 30" RCP culvert under Boylston Highway, Point of Interest 2 (POI-2). Ultimately, all the stormwater that is generated from PDA-2C will discharge downstream into the McDowell Creek and eventually into the French Broad River. Proposed Drainage Area 3 (PDA-3): This drainage area is 0.55 acres and is approximately 0.0% impervious, consisting primarily of woodland within the right-of-way with a portion of pasture, grassland or range. PDA-3 is located toward the center of the property, fronting Boylston Highway as it did in the existing analysis. Stormwater overland flows into a ditch along the right-of-way and is collected into a riprap basin inlet. Runoff is then discharged through a 36" RCP culvert under Boylston Highway, Point of Interest 3 (POI-3), where all stormwater flows into the McDowell Creek and eventually into the French Broad River. Proposed Drainage Area 3A (PDA-3A): PDA-3A is a 3.49-acre drainage area which contains half of the proposed 110,866 s.f. industrial warehouse building, associated parking to the northwest and west of the building, and minor areas of interior landscaping. This area is approximately 91.9% impervious and stormwater is captured in a proposed storm sewer network of catch basin inlets that convey runoff into a subsurface stormwater detention facility SWMB-4. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm events are routed through the outlet control portion of the structure. Stormwater discharges to a flared end structure at the existing "riprap basin" within the Boylston Highway right-of-way. Runoff is then conveyed through a 36" RCP culvert under Boylston Highway, Point of Interest 3 (POI-3), where all stormwater flows into the McDowell Creek and eventually into the French Broad River. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 8 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report D � Land Surveying Companies Proposed Drainage Area 4 (PDA-4): This drainage area is 0.88 acres and is approximately 0.0% impervious, consisting primarily of woodland within the right-of-way with a portion of pasture, grassland or range. PDA-4 is located toward the center of the property, fronting Boylston Highway. Stormwater overland flows into an inlet along the right-of-way that connects into the Boylston Highway storm sewer system, Point of Interest 4 (POI-4). Ultimately, all the stormwater that is generated from PDA-4 discharges downstream of the site into the French Broad River. Proposed Drainage Area 4A (PDA-4A): This drainage area is 0.55 acres and is approximately 34.2% impervious, consisting primarily of grass and impervious pavement. PDA-4A contains the eastern access drive and is located toward the center of the property, fronting Boylston Highway. Stormwater is captured in the proposed storm sewer system via catch basin inlets that convey runoff into a subsurface stormwater detention facility SWMB-5. The water quality design storm is then routed held in the underground basin and infiltrated into the ground. Due to elevation constraints, as ADS BayFilter filtration device is not utilized. The larger storm events are routed through an outlet control structure. Stormwater discharges into an existing Boylston Highway catch basin located within a swale in the right-of-way, Point of Interest 4 (POI-4). Ultimately, all the stormwater that is generated from PDA-4A discharges downstream of the site into the French Broad River. Proposed Drainage Area 5 (PDA-5): This drainage area is 25.47 acres and is approximately 1.1% impervious, consisting primarily of woodland with a portion of pasture, grassland or range. There is a small amount of existing development in the neighboring southern property consisting of a tennis court and a building, giving this drainage area a very minor area of impervious coverage. PDA-5 also contains "Wetland 2", as well as "Wetland 2" and "Stream 1" into which all of this watershed's runoff overland flows. PDA-5 includes nearly half of the area analyzed in this drainage study and discharges stormwater runoff northeastward off of the southern ridge directly into "Stream 1". A portion of this drainage area discharges to "Wetland 2" in the center of the site which is hydrologically connected to "Stream 1" through a drainage ditch. "Stream 1" then discharges through a concrete headwall and into a 30" RCP culvert that conveys runoff under Boylston Highway, Point of Interest 5 (POI-5). Ultimately, all the stormwater that is generated from EDA-5 will discharge downstream into the French Broad River. Proposed Drainage Area 5A (PDA-5A): This drainage area is 4.26 acres and is approximately 88.1% impervious. PDA-5A contains the other half of the proposed 110,866 s.f industrial warehouse building, associated loading areas to the southeast of the building, a portion of the circulating drive, and minor areas of interior landscaping. Runoff is collected in curb inlet catch basins that convey runoff into a subsurface stormwater detention facility SWMB-6. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 9 Architecture . Engineering . Environmental Land Surveying Companies An Employee -Owned Company Stormwater Management Report events are routed through the outlet control portion of the structure. Stormwater discharges to a flared end structure discharging to "Wetland 2". This pocket of wetlands is located in the center of the site and is hydrologically connected to "Stream 1" through a drainage ditch. "Stream 1" then discharges through a concrete headwall and into a 30" RCP culvert that conveys runoff under Boylston Highway, Point of Interest 5 (POI-5). Ultimately, all the stormwater that is generated from EDA-5 will discharge downstream into the French Broad River. Proposed Drainage Area 5B (PDA-5B): This drainage area is 1.35 acres and is approximately 76.2% impervious. PDA-513 contains the proposed truck loading dock area north of the building, a portion of the circulating drive, and minor areas of interior landscaping. Runoff is collected in curb inlet catch basins that convey runoff into a subsurface stormwater detention facility SWMB- 7. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm events are routed through the outlet control portion of the structure. Stormwater discharges to a flared end structure discharging to the drainage ditch between "Wetland 2" and "Stream 1". "Stream 1" then discharges through a concrete headwall and into a 30" RCP culvert that conveys runoff under Boylston Highway, Point of Interest 5 (POI-5). Ultimately, all the stormwater that is generated from EDA-5 will discharge downstream into the French Broad River. Proposed Drainage Area 5C (PDA-5C): This drainage area is 4.39 acres and is approximately 77.9% impervious. PDA-5C contains the southern van parking lot and associated landscaped areas. Runoff is collected in curb inlet catch basins that convey runoff into a subsurface stormwater detention facility SWMB-8. The water quality design storm is then routed through an ADS BayFilter filtration device and the larger storm events are routed through the outlet control portion of the structure. Stormwater discharges to a flared end structure discharging to "Wetland 2". This pocket of wetlands is located in the center of the site and is hydrologically connected to "Stream 1" through a drainage ditch. "Stream 1" then discharges through a concrete headwall and into a 30" RCP culvert that conveys runoff under Boylston Highway, Point of Interest 5 (POI-5). Ultimately, all the stormwater that is generated from EDA-5 will discharge downstream into the French Broad River. Proposed Drainage Area 6 (PDA-6): PDA-6 remains untouched by the proposed development and is therefore identical in drainage characteristics to EDA-6. This drainage area is 3.53 acres and is approximately 0.0% impervious, consisting primarily of woodland with a portion of pasture, grassland or range. PDA-6 encompasses the small northeastern corner of the site, located east of "Stream 1". A small ridge sends stormwater runoff north through an existing concrete headwall and into a 30" RCP culvert connecting into the Boylston Highway storm sewer system, Point of Interest 6 (POI-6). Ultimately, all of the stormwater that is generated from EDA-6 discharges downstream of the site into the French Broad River. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 10 E 1, Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report Land Surveying 0'WW_ Companies Table 3 - Post Development Drainage Characteristics Drainage Area Total Area SF Composite Curve Number Imperviousness Cover % Time of Concentration Minutes PDA-1 22,320 77 0.0% 5.80 PDA-2 190,420 76 1.1 % 19.70 PDA-2A 73,628 85 55.8% 6.00 PDA-2 B 192,969 95 88.9% 6.00 PDA-2C 24,778 87 42.5% 6.00 PDA-3 23,763 75 0.0% 8.00 PDA-3A 151,834 96 91.9% 6.00 PDA-4 38,421 75 0.0% 17.60 PDA-4A 23,953 85 34.2% 6.00 PDA-5 1,109, 344 72 1.1 % 16.90 PDA-5A 185,459 95 88.1 % 6.00 PDA-513 58,608 93 76.2% 6.00 Table 4 - Post -Development Conditions Peak Flows Analysis Peak Flows CFS Point Description 2-YR 10-YR 25-YR 100-YR POI-1 Flow to Drainage Ditch and 24" RCP at corner of 0.98 1.75 2.22 2.98 Miles View Drive and Fanning Field Road Flow to Wetland 3 and Streams 3 & 4 and 30" P0I-2 RCP along Boylston Highway 7.69 16.58 22.13 36.09 Flow to Drainage Ditch & 30" RCP along P0I-3 Boylston Highway 5.38 9.51 12.47 17.92 P0I-4 Flow to Drainage Ditch & 15" RCP along 1.23 2.60 3.37 5.73 Boylston Highway P0I-5 Flow to Wetland 1 and Stream 1 and 30" RCP 31.08 66.63 91.20 136.36 along Boylston Highway P0I-6 Flow to northeastern corner of site and 30" RCP 2.22 4.88 6.66 9.75 along Boylston Highway 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 11 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report . � Land Surveying Companies Table 5 - Existing vs Proposed Peak Rates of Runoff Peak Flow (cfs) Design Storms Analysis Point 2-YR 10-YR 25-YR 100-YR POI-1 Existing 1.88 3.29 4.15 5.52 Proposed 0.98 1.75 2.22 2.98 Percent Change 47.87% -46.81% -46.51% -46.01% POI-2 Existing 9.81 19.00 24.93 34.96 Proposed 7.69 16.58 22.13 36.09 Percent Change -21.61% -12.74% -11.23% 3.23% POI-3 Existing 5.53 9.94 12.68 17.13 Proposed 5.38 9.51 12.47 17.92 Percent Change -2.71% -4.33% -1.66% 4.61% POI-4 Existing 1.37 2.66 3.49 4.90 Proposed 1.23 2.60 3.37 5.73 Percent Change -10.22% -2.26% -3.44% 16.94% POI-5 Existing 35.55 70.26 92.59 129.95 Proposed 31.08 66.63 91.20 136.36 Percent Change -12.57% -5.17% -1.50% 4.93% POI-6 Existing 2.22 4.88 6.66 9.75 Proposed 2.22 4.88 6.66 9.75 Percent Change 0.00% 0.00% 0.00% 0.00% Overall Total Existing 56.36 110.03 144.50 202.21 Proposed 48.58 101.95 138.05 208.83 Percent Change -13.80% -7.34% -4.46% 3.27% 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 12 E 1, Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report Land Surveying 0'WW_ Companies Stormwater Management Hydrologic Modeling of the Entire Site The hydrologic analysis to determine peak stormwater discharge rates was performed using the HydroCAD stormwater modeling system computer program, version 10.00 developed by HydroCAD Software Solutions, LLC. Hydrographs for each watershed were developed using the SCS Synthetic Unit Hydrograph Method. Rainfall depths and distribution per the NOAA Atlas 14 for Mills River, NC were used for the calculation of peak flow rates and are listed in Table 6. The drainage areas, or subcatchments as labeled by the program, are depicted by hexagons on the attached drainage diagrams. Pre -development HydroCAD output can be found in Appendix B and Post -development HydroCAD output can be found in Appendix C. Table 6 — Rainfall Depths per NOAA Atlas 14 Appendix A - 24-hour Rainfall Data Return Period 24-hour Rainfall Depth Water Quality Storm 1.001, 2-year 3.54" 10- ear 5.00" 25- ear 5.89" 100- ear 7.36" Hydraulic Modeling of the Entire Site The hydraulic study of the onsite drainage system and design complies with the requirements set forth in the North Carolina Department of Environmental Quality (NCDEQ) Stormwater Design Manual. The proposed drainage systems have been sized to convey the 10-year storm event to their respective discharge points without ponding or surcharging above the catch basin / manhole grates. The system has been designed to comply with the requirements set forth in the North Carolina Department of Environmental Quality (NCDEQ) Stormwater Design Manual. Mills River, NC Rainfall Intensity -Duration (Table 7) was utilized. StormCAD Version 8i by Haestad Methods, utilizing the Rational Method, was used to model the proposed drainage system. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 13 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report . � Land Surveying Companies Table 7 — Rainfall Intensities per NOAA Atlas 14 Appendix A - 24-hour Rainfall Data Return Period 24-hour Rainfall Intensity 2-year 0.147 in/hr 10- ear 0.208 in/hr 25- ear 0.245 in/hr 100- ear 0.307 in/hr Summary The post -development peak discharge rates for the developed site have been decreased for the 2- year, 10-year and the 25-year storm events. All post development stormwater discharged will mimic existing drainage patterns. The proposed surface stormwater detention system has been designed to attenuate peak flows and detain stormwater for the design storm through the 25-year storm event. Stormwater quality is being addressed by underground detention basins and ADS BayFilter filtration structures. These features will adhere to the minimum permeance standards for stormwater control measures as required in the NCDEQ Stormwater Design Manual. The proposed stormwater management system will meet the stormwater quality requirements of the State of North Carolina. 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com 14 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report b � Land Surveying Companies APPENDIX A LOCATION MAPS Figure 1: USGS Location Map Figure 2: Aerial Location Map Figure 3: NRCS Soil Survey Map with Hydrologic Soil Group Data Figure 4.0: FEMA Federal Insurance Rate Map Figure 4.1: FEMA Firmette Map Figure 5.0: NOAA Atlas 14 Storm Depths Figure 5.1: NOAA Atlas 14 Storm Intensities 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com ,o 0 'SS RD i7 Mills River Bridge I Airport P� JO�� 280 74 Fanning 52 Bridge _ m PROJECT LOCATION Alit ES m ARCHITECTURE Designed H.J.L. . ENGINEERING PROPOSED DEVELOPMENT ENVIRONMENTAL LAND SURVEYING BOYLSTON HIGHWAY Checked Approved A.B.U. A.B.U. 119017 0' FIGURE 1 .� MILLS RIVER, NC Project Project No. 1901780 Date USCS LOCATION MAP COrY�Qi66 CAD File LOC19017 0101 - air 5-Ad" PROJECT LOCATION ARCHITECTURE Designed H.J.L. . ENGINEERING PROPOSED DEVELOPMENT ENVIRONMENTAL LAND SURVEYING BOYLSTON HIGHWAY Checked Approved Scale A.B.U. A.B.U. 119017 0' FIGURE 2 .� MILLS RIVER, NC Project No. 1901780 Date 1CAD AERIAL LOCATION MAP COrY�Qi66 File LOC19017 001 Custom Soil Resource Report Map —Soil Taxonomy Classification in E 359200 359300 359400 359500 359600 359700 359800 35° 25' 14" N I I a I I 4^ `� I 35° 25' 14" N tP+ w s! w • a Ab N o r:r f - 1 i' ' y X'•J •• Soil Map may not 19 valid at this scale. 35° 24'42"N � i� 350 24'42" N 359200 359300 359400 359500 359600 359700 359800 3: 3: in En Map Scale: 1:4,790 if printed on A portrait (8.5" x 11") sheet. N Meters ° 0 50 100 200 300 Feet 0 200 400 800 1200 Map projection: Web Mercator Comermordinates: WGS84 Edge tics: UTM 7_a3e 17N WGS84 20 -t O Q N N U L O Q' O U) E O (n U O 0 U) U) m , O a) '0 a) m z m o a) a) a) m a) _0 a) LO o m m w m U) _ rn E CL O_ O U m E `p O > 7 m 'O o O CL m N O m E E a) Q .6 m y 0 m 0 � Q 3 m m a) U U °� o m U) U) E m y s U) a) O a) -O z O O Utl) 5 aa) U y 76 Q 2i _ y O O O O O L O m y (n C d U) -0 m U) -O U) 3 m Q N z 2i O 6 U) O , a) O O- �, U W m m O 0 U) `m >• m N m N Q m cma) i m s y Q N c Q a) o m Q O O m U) E U) m O U 46 (6 .0 O O 2� O (n N 0 O- uj m LL >+ , p 0 U) O U >+ O '� U O O O) U) O E �+ m u) Z U)O N O O N U) 2 O ,O N m 7 y U O 2-0 N O N a- In E U) _ Q U m y E U 3 J 0 N -'E O m— O i = Q y t -O O O (6 E O_ 6 U) m -0 m z E Q Q U C Q N Utl) m U) 0 N O .E y Q m 0) E C y a) >+ a) m O t N N jp aai a) O) M m U) m U) � E 0 0) N� >' p 'O O y O_ a) U) U) U N (6 7 ,U) '6 U) Q U) ._ O 'O T -0m O_ O U) C m U) y a) N E o) D a) 2 3 (a) U) °? ".' C m (6 U .O U) Q m 2 '� O 0 L C N E Q m U) .30 0 E U) .c N 'O y N E 0= m O C E m U O a : s o w -6 O> aa) m o a) m O 'O y O E m 2 C m Q a) U) 7 rn y O i U) '6 y U C 2 m CL a) 7 >+ U) a) E O O O) o 'Q N C L ON. O 'N a) O U a) a) 09 O m O y o Q 'O L 0 7 O N m W t O m L W E— U U) a E u) > U Q m H O U) U) U) N H U. U) y N L T L CL � °' y y y o o R r a) O C R O R a U) R U J Q C O Z 0.O u W t* R F ,w V F R m W a a o Q R "w a° a) a U > a) R a > a) a R > R E a a) y R x a) o E a a) y R x a) o E a a) y x a) R CC Uw o U —' E E w�— E E w�— E E `o`O a O o Of o E .> w a R Co R +_ a) Y U o y R Co Y f .> w a R w• a) U o f .> w .y. R R R Y m a R a) y Q o Y O a — (4 (� y Y O a — (4 (` Y O a — (4 E y d U C U C E N O r_ U J C U C E N p U d C U C E N R O y d Q y O) c LL HT LL N 2 Z O) LL HT c LL N 2 Z O) LL HT LL N 2 c Z fn 16 , ❑ '0 R LL 0 R❑ y p In fn it 0 fn a) is Q g cn r N Custom Soil Resource Report Table —Soil Taxonomy Classification Map unit symbol Map unit name Rating Acres in AOI Percent of AOI DeB Delanco (dillard) loam, 2 to 7 percent slopes Fine -loamy, mixed, semiactive, mesic Aquic Hapludults 1.8 3.5% HyB Hayesville loam, 2 to 7 percent slopes Fine, kaolinitic, mesic Typic Kanhapludults 9.2 18.0% HyC Hayesville loam, 7 to 15 percent slopes Fine, kaolinitic, mesic Typic Kanhapludults 37.3 73.3% HyE Hayesville loam, 15 to 25 percent slopes Fine, kaolinitic, mesic Typic Kanhapludults 2.7 5.2% Totals for Area of Interest 51.0 100.0% Rating Options —Soil Taxonomy Classification Aggregation Method: Dominant Condition Component Percent Cutoff.- None Specified Tie -break Rule: Lower 22 w •,:§$ $8 bb �g Xvg 2 � 8$*€ - i _•�` - 3 8e s m� €•€• Y � is nE� $r gXg � a'& m n ;� a G g e 3beS i �F�. i �E�E Z 89. E5 e8�8 p a =6 Egg '� LLIge L5 rc $ g�$ 3e$ F' z $Fs g€ ,fig y $� e� �. � na $:o •e & s $ s$ $2 �f �,� � 6 s V' ��.€gsEg �b€a 8oas5a�4 E��£s a a8a agmB lit Kg m�paS€$$P wxa§ a8I as9gboos $ 99e �o s$58 `XE92 ��$€8E� �$si �<�S a? S C m i bbCe r: a KY r Q � e e9, YS.• oa oaa oa aoo 0 0 0 9 $g g F c - -fie ess�az HAN r a Mg 5 lip m, s $ CI-`s �WR .Fi sE_Ok"s g2$ H $$ ��m 6` f e�s®m ifthE \\\ 8s$ a 6IM 0F@ ® :eOUR"-- - Nil! �g� £ ! a3 rvs„w orvMo. #5 €imp- N� 1 M 8e �SSg 2§ QQ 77 Rg gs8 ;85$O6e¢ Y E$i;$ 6 g $kd g e £ 'jig, HU \ a �CL `s gaUNg Ems; " LO fee " Eus 0 =.5� g6 o2ry- �5 �a 8gE L.L Cl)VJ �\6Pg8i��X� s$a 8@E&g ? g ul a _ p�i %�6e 8be SSE H ig � EH ^.&y$ s LE6 1MM 8��_P2 EH a gs a s � €€IH 8""saF y O 5 8E�6� %S�gE E 3e d3 �vp a s 3 Yn £Eoa6 ssgy�3� l$§b E ¢9 4 � o oms b$ s a 3 i € BsFss a �ma ss" g 3sV€oainI im1,141 Bp IM G a 12 3 �ms�s wag $ ❑ Q Q (iN = N O 1 N C O 6 (i N j _ N C N N L <..) z Q O Q Q = E_ (6 (6 E a� tlllwo Z ¢ = (6 N 2 S J C 2 N S LL 3 O (Q6 = O i in in .O+ O = _ Vo N 6 w (0 o mC ='Xa N ° (0 0 E-.�' E N'Q(N>_6 > OO .��_ O X '0 '0 O O Eo CO0¢v ❑ONa❑Zw❑oFa 'O 0 N N U=O = eW N n O O N E N TW (6 OU w NO o o ((O= w_ dU LLwUNZ o > > d ate=E E E E'oa o4=U(N(aNE06=`36�) LL d meLLwvCQ � �(y �❑ U= �� O ° a a°z° ° ° wa w .0 ° 0 02 4).-cy) EE(o m�N W = O x N O LL N C C.)O UF OO U) Q(0 (0 N Q LL y- >> M � N = i O ❑ U U) N > 0 m d n 'y - N Q (6 Y .o3 N Q O) ��° (6 (o 'o 0. nn (a o w - ° E > 0�dc= co E �o c ❑ CO 'o (6 O (6 4 (0) O O Z J= {y1 0 Q O o f3 � w `6 ^ �Qa NO Q = O NwN E o_ E0Eo_ oQZ �° C O 0 (0 �0❑�n Q O ZO- E' °O ..W��..�� O W W W U'p 6 Z CL o= _QO 'O (o O <N WWM x LLI Z EL!M Q O (0 w 'oyOL0 C N Q = N Cyi (6 (0Cp ¢ ¢ Z �� w LL (0 E nE_EQ= E_j nan = WN W Q H (6 F N li 3 J N O vai= �LL 82°32'31.75"W �CD CD CD N 0 0 0 O Lo N 11 /11 /2019 Precipitation Frequency Data Server NOAA Atlas 14, Volume 2, Version 3 Location name: Mills River, North Carolina, USA* ""�'° Latitude: 35.4173*, Longitude:-82.5499* Elevation: 2109.79 ft * *source: ESRI Maps 'w,�w, �d source: USGS POINT PRECIPITATION FREQUENCY ESTIMATES G.M. Bonnin, D. Martin, B. Lin, T. Parzybok, M.Yekta, and D. Riley NOAA, National Weather Service, Silver Spring, Maryland PF tabular I PF graphical I Maps & aerials PF tabular PDS-based point precipitation frequency estimates with 90% confidence intervals (in inches)1 Average recurrence interval (years) 1 2 5 10 25 50 100 200 500 1000 0.367 0.437 0.523 0.589 0.675 0.740 0.806 0.872 0.958 1.03 5-min (0.330-0.408) (0.394-0.485) (0.471-0.581) (0.529-0.653) (0.602-0.747) (0.656-0.819) (0.712-0.893) (0.764-0.969) (0.829-1.07) (0.880-1.15) 0.586 0.698 0.838 0.942 1.08 1.18 1.28 1.38 1.52 1.62 10-min (0.527-0.651) (0.630-0.775) (0.755-0.931) (0.846-1.04) (0.959-1.19) 1 (1.05-1.30) 1 (1.13-1.42) 1 (1.21-1.54) (1.31-1.69) (1.39-1.82) 0.732 0.878 1.06 1.19 1.36 1.49 1.62 1.74 1.91 2.03 15-min (0.659-0.814) (0.792-0.975) (0.955-1.18) 1 (1.07-1.32) 1 (1.22-1.51) 1 (1.32-1.65) 1 (1.43-1.80) 1 (1.53-1.94) (1.65-2.13) (1.74-2.28) 1.00 1.21 1.51 1.73 2.02 2.25 2.48 2.72 3.03 3.29 30-min (0.904-1.12) 1 (1.09-1.35) 1 (1.36-1.67) 1 (1.80-2.24) (1.99-2.49) (2.19-2.75) (2.38-3.02) (2.63-3.39) (2.82-3.70) 1.25 1.52 1.93 2.25 2.69 3.05 3.42 3.81 4.35 4.80 60-min (1.13-1.39) (1.37-1.69) (1.74-2.15) (2.02-2.49) (2.40-2.98) (2.70-3.37) (3.02-3.79) (3.34-4.23) (3.77-4.87) (4.11-5.39) 1.47 1.78 2.25 2.62 3.14 3.57 4.01 4.49 5.15 5.69 2-hr (1.32-1.63) (1.60-1.97) (2.02-2.49) (2.34-2.90) (2.79-3.48) (3.15-3.95) (3.51-4.45) (3.90-4.99) (4.42-5.75) (4.83-6.40) 1.57 1.89 2.38 2.77 3.35 3.83 4.33 4.89 5.68 6.34 3-hr (1.42-1.76) 1 (1.71-2.11) 1 (2.14-2.64) (2.48-3.08) (2.97-3.72) (3.37-4.25) (3.78-4.82) (4.22-5.45) (4.83-6.38) (5.33-7.16) 1.97 2.35 2.90 3.37 4.05 4.62 5.25 5.93 6.92 7.75 6-hr (1.80-2.17) 1 (2.14-2.58) 1 (2.64-3.18) (3.05-3.70) (3.64-4.44) (4.13-5.08) (4.64-5.78) (5.18-6.54) (5.94-7.67) (6.57-8.65) 2.48 2.96 3.63 4.17 4.92 5.53 6.16 6.82 7.74 8.46 12-hr (2.28-2.71) 1 (2.72-3.23) 1 (3.33-3.96) (3.82-4.55) (4.48-5.37) (5.02-6.04) (5.56-6.74) 1 (6.11-7.49) (6.86-8.56) (7.43-9.43) 2.95 3.54 4.35 5.00 5.89 6.61 7.36 8.13 9.21 10.1 24-hr (2.73-3.20) 1 (3.28-3.84) 1 (4.02-4.71) (4.61-5.41) (5.42-6.37) (6.07-7.15) (6.72-7.94) 1 (7.39-8.78) (8.29-9.96) (8.99-10.9) 3.51 4.18 5.10 5.82 6.82 7.63 8.45 9.31 10.5 11.4 2-day (3.27-3.77) 1 (3.90-4.51) (4.74-5.49) (5.41-6.26) (6.31-7.33) (7.04-8.19) (7.77-9.09) 1 (8.51-10.0) (9.51-11.3) (10.3-12.3) 3.74 4.46 5.39 6.12 7.12 7.91 8.72 9.55 10.7 11.6 3-day (3.49-4.01) 1 (4.16-4.78) (5.02-5.78) (5.70-6.56) (6.61-7.62) (7.32-8.48) (8.04-9.36) 1 (8.76-10.3) (9.72-11.5) (10.5-12.5) 3.98 4.73 5.68 6.42 7.42 8.20 8.99 9.79 10.9 11.7 4-day (3.72-4.25) (4.43-5.06) (5.30-6.06) (5.99-6.86) (6.90-7.92) (7.60-8.76) (8.31-9.62) 1 (9.01-10.5) (9.93-11.7) (10.7-12.6) 4.64 5.51 6.60 7.47 8.65 9.59 10.5 11.5 F 12.8 13.9 7-day (4.35-4.97) (5.16-5.90) (6.18-7.07) (6.98-8.00) (8.06-9.24) (8.91-10.3) 1 (9.76-11.3) 1 (10.6-12.3) (11.7-13.8) (12.6-14.9) 5.32 6.29 7.46 8.38 9.64 10.6 11.6 12.6 F 14.0 15.1 10-day (5.02-5.64) (5.94-6.68) (7.04-7.93) (7.91-8.90) (9.06-10.2) (9.96-11.3) 1 (10.9-12.4) 1 (11.8-13.4) (12.9-14.9) (13.8-16.1) 7.23 8.49 9.87 10.9 12.3 13.3 14.4 15.4 16.6 17.6 20-day (6.84-7.63) 1 (8.05-8.98) 1 (9.34-10.4) (10.3-11.5) (11.6-13.0) (12.6-14.1) 1 (13.5-15.2) 1 (14.4-16.3) (15.5-17.7) (16.4-18.7) 8.86 10.4 11.9 13.0 14.4 15.5 16.5 17.4 F 18.6 19.4 30-day (8.42-9.34) (9.87-10.9) (11.3-12.5) (12.4-13.7) (13.7-15.2) (14.7-16.3) 1 (15.6-17.4) 1 (16.4-18.4) (17.4-19.7) (18.2-20.6) 11.3 13.2 14.8 16.1 17.5 18.6 19.5 20.4 F 21.4 22.1 45-day (10.7-11.8) (12.5-13.8) (14.1-15.6) (15.3-16.9) (16.7-18.4) (17.6-19.5) 1 (18.5-20.5) 1 (19.3-21.4) (20.3-22.5) (20.9-23.3) 13.5 15.8 17.6 18.9 20.5 21.6 22.6 23.5 24.5 25.2 60-day (12.9-14.2) (15.0-16.6) (16.8-18.5) (18.0-19.9) (19.5-21.6) (20.6-22.8) (21.5-23.8) (22.3-24.8) (23.2-25.9) (23.9-26.7) Precipitation frequency (PF) estimates in this table are based on frequency analysis of partial duration series (PDS). Numbers in parenthesis are PF estimates at lower and upper bounds of the 90% confidence interval. The probability that precipitation frequency estimates (for a given duration and average recurrence interval) will be greater than the upper bound (or less than the lower bound) is 5%. Estimates at upper bounds are not checked against probable maximum precipitation (PMP) estimates and may be higher than currently valid PMP values. Please refer to NOAA Atlas 14 document for more information. Back to Top PF graphical https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.html?lat=35.4173&Ion=-82.5499&data=depth&units=english&series=pds 1 /4 11 /11 /2019 Precipitation Frequency Data Server MIDI 25 c t 20 C a di U 15 49 10 CL a i 30 25 c s 20 a m a 15 A, 49 a 18 a Pas -based depth -duration -frequency (DDF) curves Latitude: 35.4173`, Longitude: -82.5499' --------------------- t t Jr t L N N O r{4 N rq rq rq N rq N f1�5 lb N rV A q O O O Ln O ,1 r-I rn w � N rn v Ln Duration 5 _ �.-r. 0 1 2 5 10 25 50 100 200 500 1000 Average recurrence interval (years) NOAA Atlas 14, Volume 2, Version 3 Created (GMT): Mon Nov 11 19:12:03 2019 Back to Top Maps & aerials Small scale terrain Average recurrence mlerva I f years} — 1 2 — 5 — 14 — 25 54 100 200 500 1000 Duration — 6-min — 2-day — 14-min — 3-day 15-min — 4-dmy — 30-min — 7-day — 60-min — 10-day — 2fir — 20-day — 3-hr — 30-day — Sfir — 45-day — 12-hr — 60-day 24-Mr https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.4173&Ion=-82.5499&data=depth&units=engIish&series=pds 2/4 11 /11 /2019 Precipitation Frequency Data Server AMEViL, P r R C.'V.L ti at or 3km 2mi Large scale terrain Kingsport' B I Istol J0111150 n Cit Knoxville y " �.-11 rlildl.A N 0 RT H C Charli )o9a Greenville 100km SOUTH CARO 6L I V Large scale map Kingsport J d, i t; QUA arl ot le 100km %. I i --ti L Large scale aerial https://hdsc.nws.noaa.gov/hdsc/pfds/pfds—printpage.htmI?Iat=35.4173&Ion=-82.5499&data=depth&units=english&series=pds 3/4 Precipitation Frequency Data Server Back to Top US Department of Commerce National Oceanic and Atmospheric Administration National Weather Service National Water Center 1325 East West Highway Silver Spring, MD 20910 Questions?: HDSC.Questions@noaa.gov Disclaimer https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.4173&Ion=-82.5499&data=depth&units=english&series=pds 4/4 11 /11 /2019 Precipitation Frequency Data Server NOAA Atlas 14, Volume 2, Version 3 Location name: Mills River, North Carolina, USA* ""�'° Latitude: 35.4173*, Longitude:-82.5499* Elevation: 2109.79 ft * *source: ESRI Maps 'w,�w, �d source: USGS POINT PRECIPITATION FREQUENCY ESTIMATES G.M. Bonnin, D. Martin, B. Lin, T. Parzybok, M.Yekta, and D. Riley NOAA, National Weather Service, Silver Spring, Maryland PF tabular I PF graphical I Maps & aerials PF tabular PDS-based point precipitation frequency estimates with 90% confidence intervals (in inches/hourp Duration Average recurrence interval (years) 1 2 5 10 25 50 1 100 100 200 500 1000 5-min 4.40 (3.96-4.90) 11 5.24 (4.73-5.82) 11 6.28 (5.65-6.97) 11 7.07 (6.35-7.84) 11 8.10 (7.22-8.96) 8.88 1 (7.87-9.83) 9.67 1 (8.54-10.7) 10.5 1 (9.17-11.6) 11.5 1 (9.95-12.9) 12.3 1 (10.6-13.8) 3.52 4.19 5.03 5.65 6.46 7.07 7.69 8.29 9.09 9.70 10-min (3.16-3.91) 11 (3.78-4.65) 11 (4.53-5.59) 11 (5.08-6.26) 11 (5.75-7.15) 1 (6.27-7.82) 1 (6.79-8.52) 1 (7.27-9.22) 1 (7.87-10.2) 1 (8.32-10.9) 2.93 3.51 4.24 4.77 5.45 5.97 6.48 6.98 7.63 8.12 15-min (2.64-3.26) 1 1 (4.86-6.04) 1 (5.29-6.60) 1 (5.72-7.18) 1 (6.11-7.75) 1 (6.60-8.53) 1 (6.96-9.13) 2.01 2.42 3.01 3.45 4.04 4.50 4.96 5.43 6.07 6.57 30-min (1.81-2.23) 11 (2.19-2.69) 11 (2.71-3.35) 11 (3.10-3.83) 11 (3.60-4.47) 1 (3.99-4.97) 1 (4.38-5.50) 1 (4.76-6.03) 1 (5.26-6.78) 1 (5.63-7.39) 1.25 1.52 1.93 2.25 2.69 3.05 3.42 3.81 4.35 4.80 60-min (1.13-1.39) (1.37-1.69) (1.74-2.15) 1 (2.40-2.98) 1 (2.70-3.37) 1 (3.02-3.79) 1 (3.34-4.23) 1 (3.77-4.87) 1 (4.11-5.39) 0.734 0.890 1.12 1.31 1.57 1.78 2.01 2.24 2.58 2.85 2-hr (0.658-0.814) (0.800-0.986)1 1 (1.39-1.74) (1.57-1.98) 1 (1.76-2.23) 1 (1.95-2.49) 1 (2.21-2.88) 1 (2.42-3.20) 0.524 0.631 0.791 0.923 1.12 117 1.44 1.63 1.89 2.11 3-hr (0.472-0.585) (0.568-0.703) (0.711-0.879) (0.826-1.03) (0.988-1.24) 1 (1.12-1.42) 1 (1.26-1.61) 1 (1.41-1.82) 1 (1.61-2.13) 1 (1.77-2.38) 0.329 0.392 0.484 0.562 0.676 0.772 F 0.876 F 0.990 1.16 1.29 6-hr (0.301-0.363) (0.358-0.431) (0.441-0.531) (0.510-0.617) (0.608-0.742) (0.689-0.848) (0.774-0.965) (0.865-1.09) (0.992-1.28) 1 (1.10-1.44) 0.206 0.246 0.301 0.346 0.408 0.459 0.511 0.566 0.642 0.702 12-hr (0.190-0.225) (0.226-0.268) (0.277-0.329) (0.317-0.378) (0.372-0.445) (0.417-0.501) (0.462-0.559) (0.507-0.622) (0.569-0.710) (0.617-0.783) 0.123 0.147 0.181 0.208 0.245 0.276 0.307 0.339 0.384 0.419 24-hr (0.114-0.133) (0.137-0.160) (0.168-0.196) (0.192-0.225) (0.226-0.265) (0.253-0.298) (0.280-0.331) (0.308-0.366) (0.345-0.415) (0.374-0.454) 0.073 0.087 0.106 0.121 0.142 0.159 0.176 0.194 0.218 0.238 2-day (0.068-0.079) (0.081-0.094) (0.099-0.114) (0.113-0.130) (0.132-0.153) (0.147-0.171) (0.162-0.189) (0.177-0.209) (0.198-0.236) (0.214-0.257) 0.052 0.062 0.075 0.085 0.099 0.110 0.121 0.133 0.148 0.161 3-day (0.049-0.056) (0.058-0.066) (0.070-0.080) (0.079-0.091) (0.092-0.106) (0.102-0.118) (0.112-0.130) (0.122-0.142) (0.135-0.160) (0.145-0.173) 0.041 0.049 0.059 0.067 0.077 0.085 0.094 0.102 0.113 0.122 4-day (0.039-0.044) (0.046-0.053) (0.055-0.063) (0.062-0.071) (0.072-0.083) (0.079-0.091) (0.087-0.100) (0.094-0.109) (0.103-0.122) (0.111-0.132) 0.028 0.033 0.039 0.044 0.051 0.057 0.063 0.069 0.076 0.083 7-day (0.026-0.030) (0.031-0.035) (0.037-0.042) (0.042-0.048) (0.048-0.055) (0.053-0.061) (0.058-0.067) (0.063-0.073) (0.070-0.082) (0.075-0.089) 0.022 0.026 0.031 0.035 0.040 0.044 0.048 0.053 0.058 0.063 10-day (0.021-0.024) (0.025-0.028) (0.029-0.033) (0.033-0.037) (0.038-0.043) (0.042-0.047) (0.045-0.051) (0.049-0.056) (0.054-0.062) (0.058-0.067) 0.015 0.018 0.021 0.023 0.026 0.028 0.030 0.032 0.035 0.037 20-day (0.014-0.016) (0.017-0.019) (0.019-0.022) (0.022-0.024) (0.024-0.027) (0.026-0.029) (0.028-0.032) (0.030-0.034) (0.032-0.037) (0.034-0.039) 0.012 0.014 0.017 0.018 0.020 0.021 0.023 0.024 0.026 0.027 30-day (0.012-0.013) (0.014-0.015) (0.016-0.017) (0.017-0.019) (0.019-0.021) (0.020-0.023) (0.022-0.024) (0.023-0.026) (0.024-0.027) (0.025-0.029) 0.010 0.012 0.014 0.015 0.016 0.017 0.018 0.019 0.020 0.020 45-day (0.010-0.011) (0.012-0.013) (0.013-0.014) (0.014-0.016) (0.015-0.017) (0.016-0.018) (0.017-0.019) (0.018-0.020) (0.019-0.021) (0.019-0.022) 0.009 0.011 0.012 0.013 0.014 0.015 0.016 0.016 0.017 0.018 60-day (0.009-0.010) (0.010-0.012) (0.012-0.013) (0.013-0.014) (0.014-0.015) (0.014-0.016) (0.015-0.017) (0.015-0.017) (0.016-0.018) (0.017-0.019) Precipitation frequency (PF) estimates in this table are based on frequency analysis of partial duration series (PDS). Numbers in parenthesis are PF estimates at lower and upper bounds of the 90% confidence interval. The probability that precipitation frequency estimates (for a given duration and average recurrence interval) will be greater than the upper bound (or less than the lower bound) is 5%. Estimates at upper bounds are not checked against probable maximum precipitation (PMP) estimates and may be higher than currently valid PMP values. Please refer to NOAA Atlas 14 document for more information. Back to Top PF graphical https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.html?lat=35.4173&Ion=-82.5499&data=intensity&units=english&series=pds 1 /4 11 /11 /2019 Precipitation Frequency Data Server I161616I6161 10.000 C 41 1.000 C GJ a-� C � 0.100 L Ld a 0.010 PD5-based intensity -duration -frequency (IDF) curves Latitude: 35.4173°, Longitude: -32.5499' 0.001 t t Jr t L N N O r{4 N rq rq rq N rq N Alb A q r, O O O Ln O ,1 r-1 rn w 1-4N rn v Ln Duration 100.000 10.000 L k 1.000 w c e 0.100 4.1 49 0.010 0.001 i 1 1 1 1 1 1 1 1 1 1 2 5 10 25 50 100 200 500 1000 Average recurrence interval (years) NOAA Atlas 14, Volume 2, Version 3 Created (GMT): Mon Nov 11 19:13:09 2019 Back to Top Maps & aerials Small scale terrain Average recurrence interval {years} — 1 2 — 5 — 14 — 25 54 100 200 500 1000 Duration — 6-min — 2-day — 14-min — 3-day 15-min — 4-dmy — 3"in — 7-day — 60-min — 10-day — 2fir — 20-day — 3-hr — 30-day — Sfir — 45-day — 12-hr — 60-day 24-Mr https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.4173&Ion=-82.5499&data=intensity&units=english&series=pds 2/4 11 /11 /2019 Precipitation Frequency Data Server AMEViL, P r R C.'V.L ti at or 3km 2mi Large scale terrain Kingsport' B I Istol J0111150 n Cit Knoxville y " �.-11 rlildl.A N 0 RT H C Charli )o9a Greenville 100km SOUTH CARO 6L I V Large scale map Kingsport J d, i t; QUA arl ot le 100km %. 6L Large scale aerial https://hdsc.nws.noaa.gov/hdsc/pfds/pfds—printpage.htmI?Iat=35.4173&Ion=-82.5499&data=intensity&units=english&series=pds 3/4 Precipitation Frequency Data Server Back to Top US Department of Commerce National Oceanic and Atmospheric Administration National Weather Service National Water Center 1325 East West Highway Silver Spring, MD 20910 Questions?: HDSC.Questions@noaa.gov Disclaimer https://hdsc.nws.noaa.gov/hdsc/pfds/pfds_printpage.htmI?Iat=35.4173&Ion=-82.5499&data=intensity&units=english&series=pds 4/4 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report D � Land Surveying Companies APPENDIX E ENGINEERING CALCULATIONS Riprap Outlet Protection Calculations Water Quality Calculations for BayFilter and Stormtech 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com User Input Data Calculated Value Reference Data Designed By: A.B.J. Date: 12/3/2019 Checked By: Revised Date: 1/30/202C Company: BL Companies Project Name: Mills River Development Project No.: 1901780 Site Location (City/Town) Mills River Culvert Id. FES-100 Total Drainage Area (acres) 0.57 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 minimum 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 minimum tailwater condition unless reliable flood stage elevations show- otherwise. Outlet pipe diameter, Do (in.) 15 Tailwater depth (in.) 0 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 0.95 Velocity (ft./s) 2.93 Step 2. Based on the tailwater conditions detennured in step 1. enter Figure 8.05a or Figure 8.06b, and detennine dsa riprap size and minimum apron length (I.)_ The d, size is the median stone size in a well -graded nprap 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 Fiaure 8.06a Fiaure 8.06b Riprap d50, (ft.) 0.25 Minimum apron length, La (ft.) 9 Apron width at pipe outlet (ft.) 3.75 3.75 Apron shape Apron width at outlet end (ft.) 10.25 1.25 Step 4. Determine the maximum stone diameter d.=1.5xd,, Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.375 0 Step 5. Determine the apron thickness: Apron thickness =1.5 x d . Minimum TW Maximum TW Apron Thickness(ft.) 0.5625 0 Stop 6. Fit the nprap apron to the site by making it level for the mimmnm length, L., from Figure 8.06a or Figure 8.06b. Extend the apron farther downstream and along chamiel banks until stability is assured_ Keep the apron as straight as possible acid 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 tic size of riprap where protection of the channel side slopes is necessary (Appendix 8.05). Where overfalls exist at pipe outlets or flows are excessive, a plunge pool should be considered, see page 8.06.8. User Input Data Calculated Value Reference Data Designed By: A.B.J. Date: 12/3/2019 Checked By: Revised Date: 1/30/202C Company: BL Companies Project Name: Mills River Development Project No.: 1901780 Site Location (City/Town) Mills River Culvert Id. FES-200 Total Drainage Area (acres) 1.66 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 minimum 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 minimum tailwater condition unless reliable flood stage elevations show- otherwise. Outlet pipe diameter, Do (in.) 18 Tailwater depth (in.) 0 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 3.53 Velocity (ft./s) 4.68 Step 2. Based on the tailwater conditions detennured in step 1. enter Figure 8.05a or Figure 8.06b, and detennine dsa riprap size and minimum apron length (I.)_ The d, size is the median stone size in a well -graded nprap 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 Fiaure 8.06a Fiaure 8.06b Riprap d50, (ft.) 0.3 Minimum apron length, La (ft.) 11 Apron width at pipe outlet (ft.) 4.5 4.5 Apron shape Apron width at outlet end (ft.) 12.5 1.5 Step 4, Determine the maximum stone diameter d.=1.5xd,, Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.45 0 Step 5. Determine the apron thickness: Apron thickness =1.5 x d . Minimum TW Maximum TW Apron Thickness(ft.) 0.675 0 Stop 6. Fit the nprap apron to the site by making it level for the mimmnm length, L., 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 acid 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 size of riprap where protection of the channel side slopes is necessary (Appendix 8.05). Where overfalls exist at pipe outlets or flows are excessive, a plunge pool should be considered, see page 8.06.8. User Input Data Calculated Value Reference Data Designed By: A.B.J. Date: 12/3/2019 Checked By: Revised Date: 1/30/202C Company: BL Companies Project Name: Mills River Development Project No.: 1901780 Site Location (City/Town) Mills River Culvert Id. FES-300 Total Drainage Area (acres) 4.93 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 minimum 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 minimum tailwater condition unless reliable flood stage elevations show- otherwise. Outlet pipe diameter, Do (in.) 18 Tailwater depth (in.) 0 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 4.86 Velocity (ft./s) 5.94 Step 2. Based on the tailwater conditions detenni ned in step 1. enter Figure 8.05a or Figure 8.06b, and detennine dsa riprap size and minimum apron length (I.)_ The d, size is the median stone size in a well -graded nprap apron. Step 3. Determine apron width at the pipe outlet, the apron shape, and the apron width at the outlet end from the satire figure used in Step 2. Minimum TW Maximum TW Fiaure 8.06a Fiaure 8.06b Riprap d50, (ft.) 0.3 Minimum apron length, La (ft.) 11 Apron width at pipe outlet (ft.) 4.5 4.5 Apron shape Apron width at outlet end (ft.) 12.5 1.5 Step 4. Determine the maximum stone diameter: d.=1.5xd,, Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.45 0 Step 5. Determine the apron thickness: Apron thickness =1.5 x d . Minimum TW Maximum TW Apron Thickness(ft.) 0.675 0 Stop 6. Fit the nprap apron to the site by making it level for the minimum length, L., from Figure 8.06a or Figure 8.06b. Extend the apron farther downstream and along chamiel banks until stability is assured_ Keep the apron as straight as possible acid 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 size of riprap where protection of the channel side slopes is necessary (Appendix 8.05). Where overfalls exist at pipe outlets or flows are excessive, a plunge pool should be considered, we page 8.06.8. User Input Data Calculated Value Reference Data Designed By: A.B.J. Date: 12/3/2019 Checked By: Revised Date: 1/30/202C Company: BL Companies Project Name: Mills River Development Project No.: 1901780 Site Location (City/Town) Mills River Culvert Id. FES-400 Total Drainage Area (acres) 3.49 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 minimum 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 minimum tailwater condition unless reliable flood stage elevations show- otherwise. Outlet pipe diameter, D. (in.) 18 Tailwater depth (in.) 0 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 8.55 Velocity (ft./s) 5.97 Step 2. Based on the tailwater conditions detennured in step 1. enter Figure 8.05a or Figure 8.06b, and detennine dsa riprap size and minimum apron length (I.)_ The d, size is the median stone size in a well -graded nprap apron. Step 3. Determine apron width at the pipe outlet, the apron shape, and the apron width at the outlet end from the satire figure used in Step 2. Minimum TW Maximum TW Fiaure 8.06a Fiaure 8.06b Riprap d50, (ft.) 0.4 Minimum apron length, La (ft.) 11 Apron width at pipe outlet (ft.) 4.5 4.5 Apron shape Apron width at outlet end (ft.) 12.5 1.5 Step 4. Determine the maxitntuu stone diameter: d.=1.5xd,, Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.6 0 Step 5. Determine the apron thickness: Apron thickness =1.5 x d . Minimum TW Maximum TW Apron Thickness(ft.) 0.9 0 Step 6. Fit the nprap apron to the site by making it level for the minimtrm length, L., 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 beads 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 size of riprap where protection of the channel side slopes is necessary (Appendix 8.05). Where overfalls exist at pipe outlets or flows are excessive, a plunge pool should be considered, see a...anA2 User Input Data Calculated Value Reference Data Designed By: A.B.J. Date: 12/3/2019 Checked By: Revised Date: 1/30/202C Company: BL Companies Project Name: Mills River Development Project No.: 1901780 Site Location (City/Town) Mills River Culvert Id. FES-600 Total Drainage Area (acres) 4.27 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 minimum 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 minimum tailwater condition unless reliable flood stage elevations show- otherwise. Outlet pipe diameter, Do (in.) 24 Tailwater depth (in.) 0 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 14.03 Velocity (ft./s) 16.23 Step 2. Based on the tailwater conditions detennured in steep 1. enter Figure 8.05a or Figure 8.06b, and detennine dsa riprap size and minimum apron length (l.)_ The d, size is the median stone size in a well -graded nprap 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 Fiaure 8.06a Fiaure 8.06b Riprap d50, (ft.) 0.5 Minimum apron length, La (ft.) 11 Apron width at pipe outlet (ft.) 6 6 Apron shape Apron width at outlet end (ft.) 13 2 Step 4. Determine the maxitmuu stone diameter d.=1.5xd,, Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.75 0 Step 5. Determine the apron thickness: Apron thickness =1.5 x d . Minimum TW Maximum TW Apron Thickness(ft.) 1.125 0 Step 6. Fit the rprap apron to the site by making it level for the mi*+ mum length, L., from Figure 8.06a or Figure 8 06b. Extend the apron farther downstream and along channel banks umtii 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 size of nprap where protection of the channel side slopes is necessary (Appendix 8,05). Where overfalls exist at pipe outlets or flows are excessive, a plunge pool should be considered, see page 8.06.8. User Input Data Calculated Value Reference Data Designed By: A.B.J. Date: 12/3/2019 Checked By: Revised Date: 1/30/202C Company: BL Companies Project Name: Mills River Development Project No.: 1901780 Site Location (City/Town) Mills River Culvert Id. FES-700 Total Drainage Area (acres) 1.30 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 minimum 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 minimum tailwater condition unless reliable flood stage elevations show- otherwise. Outlet pipe diameter, Do (in.) 18 Tailwater depth (in.) 0 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 4 Velocity (ft./s) 7.77 Step 2. Based on the tailwater conditions detennured in step 1. enter Figure 8.05a or Figure 8.06b, and detennine dsa riprap size and minimum apron length (l.)_ The d, size is the median stone size in a well -graded nprap 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 Fiaure 8.06a Fiaure 8.06b Riprap d50, (ft.) 0.3 Minimum apron length, La (ft.) 11 Apron width at pipe outlet (ft.) 4.5 4.5 Apron shape Apron width at outlet end (ft.) 12.5 1.5 Step 4. Determine the maximum stone diameter d.=1.5xd,, Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.45 0 Step 5. Determine the apron thickness: Apron thickness =1.5 x d,a Minimum TW Maximum TW Apron Thickness(ft.) 0.675 0 Step 6. Fit the nprap apron to the site by makin it level for the minimum length, L,, 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 size of nprap where protection of the channel side slopes is necessary (Appendix 8,05). Where overfalls exist at pipe outlets or flows are excessive, a plunge pool should be considered, see page 8.06.8. W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-1 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 0.24 ac Total Acreage 0.57 ac Time of Concentration 6 min 1 42.1 % Rv(Runoff Coefficient) 0.43 WQv 888 cf 75% WQv (Treatment Volume) 666 cf qu(Unit Peak Discharge) 990 csm/in From Type 11 Chart Qp(Water Quality Storm) 0.38 cfs VOLUME BASED SIZING Volume per cartridge 1250 CF Cartridge Type 522 Min. Number of cartridge required 1 Cartridge Flow rate 15 gpm (0.25 gpm/SF) System Flow Rate 0.03 cfs Release time 5.5 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 144 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 144 Ibs 80% Capture Capacity 116 Ibs Cartridge Type 522 Sediment load per cartridge 131 Ibs Min. Number of cartridge required 1 Anticipated Maintenance Cycle 1.13 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 522 Number of Cartridges 1 Precast Size 5X7 Equivalent Orifice Size 0.93 inch 1 /30/2020 W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-2 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 0.94 ac Total Acreage 1.69 ac Time of Concentration 6 min 1 55.6 % Rv(Runoff Coefficient) 0.55 WQv 3378 cf 75% WQv (Treatment Volume) 2533 cf qu(Unit Peak Discharge) 990 csm/in From Type 11 Chart Qp(Water Quality Storm) 1.44 cfs VOLUME BASED SIZING Volume per cartridge 2500 CF Cartridge Type 530 Min. Number of cartridge required 2 Cartridge Flow rate 15 gpm (0.25 gpm/SF) System Flow Rate 0.07 cfs Release time 10.5 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 550 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 550 Ibs 80% Capture Capacity 440 Ibs Cartridge Type 530 Sediment load per cartridge 262 Ibs Min. Number of cartridge required 2 Anticipated Maintenance Cycle 1.19 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 530 Number of Cartridges 2 Precast Size 5x7 Equivalent Orifice Size 1.16 inch 1 /30/2020 W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-3 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 3.94 ac Total Acreage 4.43 ac Time of Concentration 6 min 1 88.9 % Rv(Runoff Coefficient) 0.85 WQv 13676 cf 75% WQv (Treatment Volume) 10257 cf qu(Unit Peak Discharge) 990 csm/in From Type 11 Chart Qp(Water Quality Storm) 5.83 cfs VOLUME BASED SIZING Volume per cartridge 2500 CF Cartridge Type 530 Min. Number of cartridge required 5 Cartridge Flow rate 15 gpm (0.25 gpm/SF) System Flow Rate 0.17 cfs Release time 17.0 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 2226 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 2226 Ibs 80% Capture Capacity 1781 Ibs Cartridge Type 530 Sediment load per cartridge 262 Ibs Min. Number of cartridge required 7 Anticipated Maintenance Cycle 1.03 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 530 Number of Cartridges 7 Precast Size 8x12 Equivalent Orifice Size 2.19 inch 1 /30/2020 W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-4 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 3.20 ac Total Acreage 3.49 ac Time of Concentration 6 min 1 91.7 % Rv(Runoff Coefficient) 0.88 WQv 11088 cf 75% WQv (Treatment Volume) 8316 cf qu(Unit Peak Discharge) 1000 csm/in From Type 11 Chart Qp(Water Quality Storm) 4.77 cfs VOLUME BASED SIZING Volume per cartridge 2500 CF Cartridge Type 530 Min. Number of cartridge required 4 Cartridge Flow rate 15 gpm (0.25 gpm/SF) System Flow Rate 0.13 cfs Release time 17.3 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 1805 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 1805 Ibs 80% Capture Capacity 1444 Ibs Cartridge Type 530 Sediment load per cartridge 262 Ibs Min. Number of cartridge required 6 Anticipated Maintenance Cycle 1.09 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 530 Number of Cartridges 6 Precast Size 6x12 Equivalent Orifice Size 2.00 inch 1 /30/2020 BAYSAVER,TECHNOLOGIES Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-5 at Str. HDS-500 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 0.19 ac Total Acreage 0.55 ac Time of Concentration 6 min 1 34.5 % Rv(Runoff Coefficient) 0.36 WQV 721 cf 75% WQv (Treatment Volume) 540 cf qu(Unit Peak Discharge) 990 csm/in From Type 11 Chart Qp(Water Quality Storm) 0.31 cfs FLOW BASED SIZING Flow per cartridge 0.1 CFS Cartridge Type 545 Min. Number of cartridge required 4 Cartridge Flow rate 45 gpm (0.25 gpm/SF) System Flow Rate 0.40 cfs SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 117 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 117 Ibs 80% Capture Capacity 94 Ibs Cartridge Type 545 Sediment load per cartridge 262 Ibs Min. Number of cartridge required 1 Anticipated Maintenance Cycle 2.79 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 545 Number of Cartridges 4 Precast Size 6x8 Equivalent Orifice Size 2.97 inch 1 /30/2020 W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-6 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 3.75 ac Total Acreage 4.26 ac Time of Concentration 6 min 1 88.0 % Rv(Runoff Coefficient) 0.84 WQv 13024 cf 75% WQv (Treatment Volume) 9768 cf qu(Unit Peak Discharge) 1000 csm/in From Type 11 Chart Qp(Water Quality Storm) 5.61 cfs VOLUME BASED SIZING Volume per cartridge 2500 CF Cartridge Type 530 Min. Number of cartridge required 4 Cartridge Flow rate 15 gpm (0.25 gpm/SF) System Flow Rate 0.13 cfs Release time 20.3 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 2120 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 2120 Ibs 80% Capture Capacity 1696 Ibs Cartridge Type 530 Sediment load per cartridge 262 Ibs Min. Number of cartridge required 7 Anticipated Maintenance Cycle 1.08 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 530 Number of Cartridges 7 Precast Size 8x12 Equivalent Orifice Size 2.15 inch 1 /30/2020 W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-7 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 1.02 ac Total Acreage 1.34 ac Time of Concentration 6 min 1 76.1 % Rv(Runoff Coefficient) 0.74 WQv 3576 cf 75% WQv (Treatment Volume) 2682 cf qu(Unit Peak Discharge) 1000 csm/in From Type 11 Chart Qp(Water Quality Storm) 1.54 cfs VOLUME BASED SIZING Volume per cartridge 1250 CF Cartridge Type 522 Min. Number of cartridge required 3 Cartridge Flow rate 11.25 gpm (0.25 gpm/SF) System Flow Rate 0.08 cfs Release time 9.9 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 582 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 582 Ibs 80% Capture Capacity 466 Ibs Cartridge Type 522 Sediment load per cartridge 131 Ibs Min. Number of cartridge required 4 Anticipated Maintenance Cycle 1.13 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 522 Number of Cartridges 4 Precast Size 6x9 Equivalent Orifice Size 1.53 inch 1 /30/2020 W,*4TllECHNOt1L GVER I Project Name: Proposed Development - Mills River Date Location: Mills River, NC Site Designation: BF-8 SITE CONDITIONS Rainfall Depth 1 in Impervious Acreage 3.42 ac Total Acreage 4.39 ac Time of Concentration 6 min 1 77.9 % Rv(Runoff Coefficient) 0.75 WQv 11970 cf 75% WQv (Treatment Volume) 8977 cf qu(Unit Peak Discharge) 1000 csm/in From Type 11 Chart Qp(Water Quality Storm) 5.15 cfs VOLUME BASED SIZING Volume per cartridge 2500 CF Cartridge Type 530 Min. Number of cartridge required 4 Cartridge Flow rate 15 gpm (0.25 gpm/SF) System Flow Rate 0.13 cfs Release time 18.7 hours SEDIMENT BASED SIZING Influent Concentration 70 mg/L Annual Rainfall (P) 41.5 in Annual Sediment Load 1948 Ibs Pretreatment reduction 0% Sediment Load to BayFilter 1948 Ibs 80% Capture Capacity 1559 Ibs Cartridge Type 530 Sediment load per cartridge 262 Ibs Min. Number of cartridge required 6 Anticipated Maintenance Cycle 1.01 years (must be greater than 1 year) FINAL DESIGN Cartridge Type 530 Number of Cartridges 6 Precast Size 8X10 Equivalent Orifice Size 1.99 inch 1 /30/2020 Project: Proposed Delivery Station BMP-1 �A StormTech® Chamber Model - SC-740 Units - imperial Click Here for Metric A d-.n- f "T-OW Number of chambers - 52 Voids in the stone (porosity) - 40 Base Of STONE Elevation - 2124.27 ft Q Include Perimeter Stone in Calculations Amount of Stone Above Chambers - 6 in Amount of Stone Below Chambers - 6 in Area of system - 2165 sf Min. Area - 1758 sf min. area 42 0.00 0.00 72.17 72.17 4464.67 2127.77 41 0.00 0.00 72.17 72.17 4392.50 2127.69 40 0.00 0.00 72.17 72.17 4320.33 2127.60 39 0.00 0.00 72.17 72.17 4248.17 2127.52 38 0.00 0.00 72.17 72.17 4176.00 2127.44 37 0.00 0.00 72.17 72.17 4103.83 2127.35 36 0.05 2.86 71.02 73.88 4031.67 2127.27 35 0.16 8.47 68.78 77.25 3957.78 2127.19 34 0.28 14.66 66.30 80.96 3880.53 2127.10 33 0.60 31.41 59.60 91.01 3799.57 2127.02 32 0.80 41.69 55.49 97.18 3708.56 2126.94 31 0.95 49.43 52.39 101.83 3611.38 2126.85 30 1.07 55.87 49.82 105.69 3509.55 2126.77 29 1.18 61.39 47.61 109.00 3403.86 2126.69 28 1.27 65.81 45.84 111.66 3294.86 2126.60 27 1.36 70.46 43.98 114.44 3183.21 2126.52 26 1.45 75.61 41.92 117.53 3068.76 2126.44 25 1.52 79.29 40.45 119.74 2951.23 2126.35 24 1.58 82.28 39.25 121.54 2831.49 2126.27 23 1.64 85.40 38.01 123.41 2709.96 2126.19 22 1.70 88.37 36.82 125.19 2586.55 2126.10 21 1.75 91.15 35.71 126.86 2461.36 2126.02 20 1.80 93.75 34.67 128.41 2334.50 2125.94 19 1.85 96.46 33.58 130.04 2206.09 2125.85 18 1.89 98.44 32.79 131.23 2076.04 2125.77 17 1.93 100.57 31.94 132.51 1944.81 2125.69 16 1.97 102.70 31.09 133.79 1812.31 2125.60 15 2.01 104.52 30.36 134.88 1678.52 2125.52 14 2.04 106.34 29.63 135.97 1543.64 2125.44 13 2.07 107.90 29.01 136.91 1407.67 2125.35 12 2.10 109.46 28.38 137.84 1270.77 2125.27 11 2.13 110.85 27.83 138.68 1132.93 2125.19 10 2.15 112.00 27.37 139.37 994.25 2125.10 9 2.18 113.21 26.88 140.09 854.88 2125.02 8 2.20 114.31 26.44 140.76 714.79 2124.94 7 2.21 114.78 26.25 141.04 574.04 2124.85 6 0.00 0.00 72.17 72.17 433.00 2124.77 5 0.00 0.00 72.17 72.17 360.83 2124.69 4 0.00 0.00 72.17 72.17 288.67 2124.60 3 0.00 0.00 72.17 72.17 216.50 2124.52 2 0.00 0.00 72.17 72.17 144.33 2124.44 1 0.00 0.00 72.17 72.17 72.17 2124.35 WQ Volume: 666 System Outlet: 2124.27 Volume Below Outlet: 1 0.00 Volume Subtotal: 666.00 WQ Elevation: 2124.91 BayFilter model 522 Volume per filter 1250 Required Head 20 Minimum Outlet 2122.60 Filter outlet invert 2122.6 Number of filters Project: Proposed Delivery Station BMP-2 Chamber Model - Units - Number of Chambers - Number of End Caps - Voids in the stone (porosity) - Base of STONE Elevation - Amount of Stone Above Chambers - Amount of Stone Below Chambers - Area of system - MC-350C Imperial 56 8 40 2137.30 12 9 3289 StormTech® �mA, A S-'wn of "T-O . ❑� Include Perimeter Stone in Calculations Min. Area - 3011 sf min. area Height of System (inches) Incremental Single Chamber (cubic feet) Incremental Single End Cap (cubic feet) Incremental Chambers (cubic feet) Incremental End Cap (cubic feet) Incremental Stone (cubic feet) Incremental Ch, Cumulative EC and Stone System (cubic feet) (cubic feet) Elevation (feet) 66 0.00 0.00 0.00 0.00 109.63 109.63 11001.81 2142.80 65 0.00 0.00 0.00 0.00 109.63 109.63 10892.18 2142.72 64 0.00 0.00 0.00 0.00 109.63 109.63 10782.55 2142.63 63 0.00 0.00 0.00 0.00 109.63 109.63 10672.91 2142.55 62 0.00 0.00 0.00 0.00 109.63 109.63 10563.28 2142.47 61 0.00 0.00 0.00 0.00 109.63 109.63 10453.65 2142.38 60 0.00 0.00 0.00 0.00 109.63 109.63 10344.01 2142.30 59 0.00 0.00 0.00 0.00 109.63 109.63 10234.38 2142.22 58 0.00 0.00 0.00 0.00 109.63 109.63 10124.75 2142.13 57 0.00 0.00 0.00 0.00 109.63 109.63 10015.11 2142.05 56 0.00 0.00 0.00 0.00 109.63 109.63 9905.48 2141.97 55 0.00 0.00 0.00 0.00 109.63 109.63 9795.85 2141.88 54 0.06 0.00 3.25 0.00 108.33 111.59 9686.21 2141.80 53 0.19 0.02 10.87 0.19 105.21 116.27 9574.63 2141.72 52 0.29 0.04 16.46 0.30 102.93 119.69 9458.36 2141.63 51 0.40 0.05 22.60 0.41 100.43 123.44 9338.67 2141.55 50 0.69 0.07 38.48 0.54 94.02 133.05 9215.23 2141.47 49 1.03 0.09 57.58 0.71 86.32 144.61 9082.18 2141.38 48 1.25 0.11 69.97 0.86 81.30 152.13 8937.57 2141.30 47 1.42 0.13 79.64 1.01 77.37 158.03 8785.44 2141.22 46 1.57 0.14 88.10 1.16 73.93 163.18 8627.41 2141.13 45 1.71 0.16 95.60 1.30 70.87 167.78 8464.23 2141.05 44 1.83 0.18 102.40 1.45 68.09 171.94 8296.45 2140.97 43 1.94 0.20 108.52 1.60 65.59 175.70 8124.51 2140.88 42 2.04 0.22 114.29 1.75 63.22 179.25 7948.81 2140.80 41 2.13 0.23 119.54 1.88 61.06 182.49 7769.55 2140.72 40 2.22 0.25 124.56 2.00 59.01 185.57 7587.07 2140.63 39 2.31 0.27 129.18 2.12 57.11 188.42 7401.50 2140.55 38 2.38 0.28 133.55 2.24 55.32 191.11 7213.08 2140.47 37 2.46 0.29 137.71 2.35 53.61 193.67 7021.97 2140.38 36 2.53 0.31 141.58 2.46 52.02 196.06 6828.30 2140.30 35 2.59 0.32 145.25 2.57 50.51 198.32 6632.25 2140.22 34 2.66 0.33 148.74 2.68 49.07 200.48 6433.92 2140.13 33 2.72 0.35 152.05 2.78 47.70 202.53 6233.44 2140.05 32 2.77 0.36 155.19 2.88 46.40 204.48 6030.91 2139.97 31 2.82 0.37 158.18 2.98 45.17 206.33 5826.44 2139.88 30 2.88 0.38 161.03 3.07 43.99 208.09 5620.11 2139.80 29 2.92 0.40 163.75 3.17 42.87 209.79 5412.01 2139.72 28 2.97 0.41 166.31 3.26 41.80 211.38 5202.23 2139.63 27 3.01 0.42 168.70 3.35 40.81 212.86 4990.85 2139.55 26 3.05 0.43 170.98 3.44 39.87 214.29 4777.99 2139.47 25 3.09 0.44 173.28 3.52 38.91 215.71 4563.70 2139.38 24 3.13 0.45 175.31 3.61 38.07 216.98 4347.99 2139.30 23 3.17 0.46 177.28 3.69 37.25 218.21 4131.01 2139.22 22 3.20 0.47 179.17 3.77 36.46 219.39 3912.79 2139.13 21 3.23 0.48 180.94 3.84 35.72 220.50 3693.40 2139.05 20 3.26 0.49 182.64 3.91 35.01 221.56 3472.90 2138.97 19 3.29 0.50 184.25 3.98 34.34 222.58 3251.33 2138.88 WQ Volume: 2667 System Outlet: 2137.3 Volume Below Outlet: 0.00 Volume Subtotal: 2667.00 WQ Elevation: 2138.67 BayFilter model 530 Volume per filter 2500 Required Head 32 Minimum Outlet 2134.63 Filter outlet invert 2134.63 Number of filters Project: Proposed Delivery Station BMP-3 Chamber Model - Units - Number of Chambers - Number of End Caps - Voids in the stone (porosity) - Base of STONE Elevation - Amount of Stone Above Chambers Amount of Stone Below Chambers Area of system - MC-3500 Imperial cua, Hara rormamo 270 36 40 2134.54 ft 12 in ❑' inc 9 in 15526 sf Min. Area - StormTech® A dvinarz of '�1irv�J s lute Perimeter Stone in Calculations 14474 sf min. area Height of System inches Incremental Single Chamber cubic feet Incremental Single End Cap cubic feet Incremental Chambers cubic feet Incremental End Cap cubic feet Incremental Stone cubic feet �IncrementalClh, EC and Stone cubic feet Cumulative System cubic feet Elevation feet 66 0.00 0.00 0.00 0.00 517.53 517.53 52291.69 2140.04 65 0.00 0.00 0.00 0.00 517.53 517.53 51774.16 2139.96 64 0.00 0.00 0.00 0.00 517.53 517.53 51256.63 2139.87 63 0.00 0.00 0.00 0.00 517.53 517.53 50739.09 2139.79 62 0.00 0.00 0.00 0.00 517.53 517.53 50221.56 2139.71 61 0.00 0.00 0.00 0.00 517.53 517.53 49704.03 2139.62 60 0.00 0.00 0.00 0.00 517.53 517.53 49186.49 2139.54 59 0.00 0.00 0.00 0.00 517.53 517.53 48668.96 2139.46 58 0.00 0.00 0.00 0.00 517.53 517.53 48151.43 2139.37 57 0.00 0.00 0.00 0.00 517.53 517.53 47633.89 2139.29 56 0.00 0.00 0.00 0.00 517.53 517.53 47116.36 2139.21 55 0.00 0.00 0.00 0.00 517.53 517.53 46598.83 2139.12 54 0.06 0.00 15.68 0.00 511.26 526.94 46081.29 2139.04 53 0.19 0.02 52.41 0.86 496.23 549.49 45554.35 2138.96 52 0.29 0.04 79.37 1.35 485.24 565.97 45004.86 2138.87 51 0.40 0.05 108.98 1.86 473.20 584.04 44438.89 2138.79 50 0.69 0.07 185.54 2.43 442.34 630.32 43854.85 2138.71 49 1.03 0.09 277.64 3.18 405.21 686.02 43224.54 2138.62 48 1.25 0.11 337.37 3.86 381.04 722.27 42538.51 2138.54 47 1.42 0.13 384.00 4.55 362.11 750.66 41816.24 2138.46 46 1.57 0.14 424.75 5.20 345.56 775.50 41065.58 2138.37 45 1.71 0.16 460.93 5.86 330.82 797.61 40290.08 2138.29 44 1.83 0.18 493.69 6.54 317.44 817.67 39492.47 2138.21 43 1.94 0.20 523.20 7.22 305.37 835.78 38674.79 2138.12 42 2.04 0.22 551.02 7.86 293.98 852.86 37839.01 2138.04 41 2.13 0.23 576.37 8.46 283.60 868.43 36986.15 2137.96 40 2.22 0.25 600.54 9.02 273.71 883.27 36117.72 2137.87 39 2.31 0.27 622.83 9.56 264.58 896.97 35234.45 2137.79 38 2.38 0.28 643.89 10.08 255.95 909.91 34337.48 2137.71 37 2.46 0.29 663.96 10.58 247.72 922.26 33427.57 2137.62 36 2.53 0.31 682.61 11.08 240.06 933.75 32505.31 2137.54 35 2.59 0.32 700.31 11.56 232.78 944.66 31571.57 2137.46 34 2.66 0.33 717.14 12.04 225.86 955.04 30626.91 2137.37 33 2.72 0.35 733.08 12.49 219.31 964.88 29671.87 2137.29 32 2.77 0.36 748.25 12.96 213.05 974.26 28706.99 2137.21 31 2.82 0.37 762.66 13.40 207.11 983.17 27732.74 2137.12 30 2.88 0.38 776.37 13.84 201.45 991.66 26749.57 2137.04 29 2.92 0.40 789.52 14.26 196.02 999.80 25757.91 2136.96 28 2.97 0.41 801.87 14.67 190.92 1007.46 24758.11 2136.87 27 3.01 0.42 813.36 15.07 186.16 1014.59 23750.65 2136.79 26 3.05 0.43 824.38 15.47 181.59 1021.44 22736.06 2136.71 25 3.09 0.44 835.45 15.85 177.01 1028.32 21714.62 2136.62 24 3.13 0.45 845.25 16.23 172.94 1034.42 20686.30 2136.54 23 3.17 0.46 854.73 16.59 169.01 1040.33 19651.88 2136.46 22 3.20 0.47 863.85 16.94 165.22 1046.01 18611.55 2136.37 21 3.23 0.48 872.40 17.28 161.66 1051.34 17565.54 2136.29 20 3.26 0.49 880.58 17.61 158.26 1056.45 16514.20 2136.21 19 3.29 0.50 888.37 17.93 155.01 1061.31 15457.75 2136.12 18 3.32 0.51 895.85 18.23 151.90 1065.98 14396.44 2136.04 17 3.34 0.51 902.91 18.52 148.96 1070.39 13330.46 2135.96 16 3.37 0.52 909.53 18.80 146.20 1074.53 12260.06 2135.87 15 3.39 0.53 915.98 19.06 143.52 1078.56 11185.53 2135.79 14 3.41 0.54 921.93 19.32 141.04 1082.28 10106.97 2135.71 13 3.44 0.54 927.99 19.55 138.51 1086.06 9024.70 2135.62 12 3.46 0.55 933.58 19.78 136.19 1089.55 7938.63 2135.54 11 3.48 0.56 939.25 19.99 133.84 1093.07 6849.08 2135.46 10 3.51 0.59 946.37 21.42 130.42 1098.21 5756.01 2135.37 9 0.00 0.00 0.00 0.00 517.53 517.53 4657.80 2135.29 8 0.00 0.00 0.00 0.00 517.53 517.53 4140.27 2135.21 7 0.00 0.00 0.00 0.00 517.53 517.53 3622.73 2135.12 6 0.00 0.00 0.00 0.00 517.53 517.53 3105.20 2135.04 5 0.00 0.00 0.00 0.00 517.53 517.53 2587.67 2134.96 4 0.00 0.00 0.00 0.00 517.53 517.53 2070.13 2134.87 3 0.00 0.00 0.00 0.00 517.53 517.53 1552.60 2134.79 2 0.00 0.00 0.00 0.00 517.53 517.53 1035.07 2134.71 1 0.00 0.00 0.00 0.00 517.53 517.53 517.53 2134.62 WQ Volume: 1 want to fi, System Outlet: This is the 1 �AThisisthec Volume Below Outlet: Volume Subtotal: 8316.00 Dead stora WQ Elevation: 2135.57 The calcula BayFilter model 530 Volume per filter 2500 cf Required Head 32 in Minimum Outlet 2131.87 Filter outlet invert 2131.87 The reques Number of filters 4 Project: Proposed Delivery Station BMP-4 Chamber Model - Units - Number of Chambers - Number of End Caps - Voids in the stone (porosity) - Base of STONE Elevation - Amount of Stone Above Chambers Amount of Stone Below Chambers Area of system - MC-3500 Imperial ci.... m &,a 163 16 40 2125.15 ft 12 in ❑' in 9 in 9106 sf Min. Area - StormTech® A dvinarz of '�1irv�J s elude Perimeter Stone in Calculations 8641 sf min. area Height of System inches Incremental Single Chamber cubic feet Incremental Single End Cap cubic feet Incremental Chambers cubic feet Incremental End Cap cubic feet Incremental Stone cubic feet �IncrementalClh, EC and Stone cubic feet Cumulative System cubic feet Elevation feet 66 0.00 0.00 0.00 0.00 303.53 303.53 30929.61 2130.65 65 0.00 0.00 0.00 0.00 303.53 303.53 30626.08 2130.57 64 0.00 0.00 0.00 0.00 303.53 303.53 30322.55 2130.48 63 0.00 0.00 0.00 0.00 303.53 303.53 30019.01 2130.40 62 0.00 0.00 0.00 0.00 303.53 303.53 29715.48 2130.32 61 0.00 0.00 0.00 0.00 303.53 303.53 29411.95 2130.23 60 0.00 0.00 0.00 0.00 303.53 303.53 29108.41 2130.15 59 0.00 0.00 0.00 0.00 303.53 303.53 28804.88 2130.07 58 0.00 0.00 0.00 0.00 303.53 303.53 28501.35 2129.98 57 0.00 0.00 0.00 0.00 303.53 303.53 28197.81 2129.90 56 0.00 0.00 0.00 0.00 303.53 303.53 27894.28 2129.82 55 0.00 0.00 0.00 0.00 303.53 303.53 27590.75 2129.73 54 0.06 0.00 9.47 0.00 299.75 309.21 27287.21 2129.65 53 0.19 0.02 31.64 0.38 290.72 322.75 26978.00 2129.57 52 0.29 0.04 47.92 0.60 284.13 332.64 26655.25 2129.48 51 0.40 0.05 65.79 0.82 276.89 343.50 26322.61 2129.40 50 0.69 0.07 112.01 1.08 258.30 371.39 25979.10 2129.32 49 1.03 0.09 167.61 1.41 235.92 404.95 25607.72 2129.23 48 1.25 0.11 203.67 1.71 221.38 426.77 25202.77 2129.15 47 1.42 0.13 231.82 2.02 210.00 443.84 24776.00 2129.07 46 1.57 0.14 256.42 2.31 200.04 458.77 24332.16 2128.98 45 1.71 0.16 278.27 2.61 191.18 472.06 23873.39 2128.90 44 1.83 0.18 298.05 2.91 183.15 484.10 23401.33 2128.82 43 1.94 0.20 315.86 3.21 175.91 494.97 22917.23 2128.73 42 2.04 0.22 332.65 3.49 169.07 505.22 22422.26 2128.65 41 2.13 0.23 347.95 3.76 162.85 514.56 21917.04 2128.57 40 2.22 0.25 362.55 4.01 156.91 523.47 21402.47 2128.48 39 2.31 0.27 376.01 4.25 151.43 531.69 20879.01 2128.40 38 2.38 0.28 388.72 4.48 146.25 539.45 20347.32 2128.32 37 2.46 0.29 400.83 4.70 141.32 546.85 19807.87 2128.23 36 2.53 0.31 412.09 4.93 136.73 553.74 19261.01 2128.15 35 2.59 0.32 422.78 5.14 132.37 560.28 18707.27 2128.07 34 2.66 0.33 432.94 5.35 128.22 566.51 18146.98 2127.98 33 2.72 0.35 442.56 5.55 124.29 572.40 17580.48 2127.90 32 2.77 0.36 451.72 5.76 120.54 578.02 17008.08 2127.82 31 2.82 0.37 460.42 5.96 116.98 583.36 16430.05 2127.73 30 2.88 0.38 468.70 6.15 113.59 588.44 15846.70 2127.65 29 2.92 0.40 476.63 6.34 110.34 593.32 15258.25 2127.57 28 2.97 0.41 484.09 6.52 107.29 597.90 14664.94 2127.48 27 3.01 0.42 491.03 6.70 104.44 602.17 14067.04 2127.40 26 3.05 0.43 497.68 6.87 101.71 606.27 13464.87 2127.32 25 3.09 0.44 504.37 7.05 98.97 610.38 12858.60 2127.23 24 3.13 0.45 510.28 7.21 96.54 614.03 12248.22 2127.15 23 3.17 0.46 516.00 7.37 94.18 617.56 11634.19 2127.07 22 3.20 0.47 521.51 7.53 91.92 620.96 11016.63 2126.98 21 3.23 0.48 526.67 7.68 89.79 624.15 10395.67 2126.90 20 3.26 0.49 531.61 7.83 87.76 627.20 9771.53 2126.82 19 3.29 0.50 536.31 7.97 85.82 630.10 9144.33 2126.73 18 3.32 0.51 540.83 8.10 83.96 632.89 8514.23 2126.65 17 3.34 0.51 545.09 8.23 82.20 635.53 7881.34 2126.57 16 3.37 0.52 549.08 8.36 80.56 638.00 7245.81 2126.48 15 3.39 0.53 552.98 8.47 78.95 640.40 6607.81 2126.40 14 3.41 0.54 556.57 8.58 77.47 642.63 5967.41 2126.32 13 3.44 0.54 560.23 8.69 75.96 644.89 5324.78 2126.23 12 3.46 0.55 563.61 8.79 74.57 646.97 4679.89 2126.15 11 3.48 0.56 567.03 8.88 73.17 649.08 4032.92 2126.07 10 3.51 0.59 571.33 9.52 71.19 652.04 3383.84 2125.98 9 0.00 0.00 0.00 0.00 303.53 303.53 2731.80 2125.90 8 0.00 0.00 0.00 0.00 303.53 303.53 2428.27 2125.82 7 0.00 0.00 0.00 0.00 303.53 303.53 2124.73 2125.73 6 0.00 0.00 0.00 0.00 303.53 303.53 1821.20 2125.65 5 0.00 0.00 0.00 0.00 303.53 303.53 1517.67 2125.57 4 0.00 0.00 0.00 0.00 303.53 303.53 1214.13 2125.48 3 0.00 0.00 0.00 0.00 303.53 303.53 910.60 2125.40 2 0.00 0.00 0.00 0.00 303.53 303.53 607.07 2125.32 1 0.00 0.00 0.00 0.00 303.53 303.53 303.53 2125.23 WQ Volume: 8 1 want to fi, System Outlet: 212 This is the 1 �hisisthec Volume Below Outlet: Volume Subtotal: 8316.00 Dead stora WQ Elevation: 2126.63 The calcula BayFilter model 530 Volume per filter 2500 cf Required Head 32 in Minimum Outlet 2122.48 Filter outlet invert 2122.48 The reques Number of filters 4 Project: Proposed Delivery Station BMP-5 Chamber Model - Units - Number of Chambers - Number of End Caps - Voids in the stone (porosity) - Base of STONE Elevation - Amount of Stone Above Chambers Amount of Stone Below Chambers Area of system - MC-3500 Imperial c Herefo, ma" 20 4 40 % 2109.78 ft 12 in 30 in 1322 sf Min. Area - AA StormTech- o�,�n�� lude Perimeter Stone in Calculations 1095 sf min. area Height of System inches Incremental Single Chamber cubic feet Incremental Single End Cap cubic feet Incremental Chambers cubic feet Incremental End Cap cubic feet Incremental Stone cubic feet Incremental Ch, EC and Stone cubic feet Cumulative System I (cubic feet) Elevation I feet) 0.00 0.00 0.00 0.00 44.07 44.07 5189.06 2117.03 0.00 0.00 0.00 0.00 44.07 44.07 5144.99 2116.95 0.00 0.00 0.00 0.00 44.07 44.07 5100.93 2116.86 0.00 0.00 0.00 0.00 44.07 44.07 5056.86 2116.78 0.00 0.00 0.00 0.00 44.07 44.07 5012.79 2116.70 0.00 0.00 0.00 0.00 44.07 44.07 4968.73 2116.61 0.00 0.00 0.00 0.00 44.07 44.07 4924.66 2116.53 0.00 0.00 0.00 0.00 44.07 44.07 4880.59 2116.45 0.00 0.00 0.00 0.00 44.07 44.07 4836.53 2116.36 0.00 0.00 0.00 0.00 44.07 44.07 4792.46 2116.28 0.00 0.00 0.00 0.00 44.07 44.07 4748.39 2116.20 0.00 0.00 0.00 0.00 44.07 44.07 4704.33 2116.11 0.06 0.00 1.16 0.00 43.60 44.76 4660.26 2116.03 0.19 0.02 3.88 0.10 42.48 46.45 4615.50 2115.95 0.29 0.04 5.88 0.15 41.65 47.68 4569.04 2115.86 0.40 0.05 8.07 0.21 40.76 49.03 4521.36 2115.78 0.69 0.07 13.74 0.27 38.46 52.48 4472.33 2115.70 1.03 0.09 2057. 0.35 35.70 56.62 4419.85 2115.61 1.25 0.11 24.99 0.43 33.90 59.32 4363.23 2115.53 1.42 0.13 28.44 0.51 32.49 61.44 4303.91 2115.45 1.57 0.14 31.46 0.58 31.25 63.29 4242.48 2115.36 1.71 0.16 34.14 0.65 30.15 64.94 4179.19 2115.28 1.83 0.18 36.57 0.73 29.15 66.44 4114.24 2115.20 1.94 0.20 38.76 0.80 28.24 67.80 4047.80 2115.11 2.04 0.22 40.82 0.87 27.39 69.08 3980.00 2115.03 2.13 0.23 42.69 0.94 26.61 70.25 3910.92 2114.95 2.22 0.25 44.48 1.00 25.87 71.36 3840.67 2114.86 2.31 0.27 46.14 1.06 25.19 72.39 3769.31 2114.78 2.38 0.28 47.70 1.12 24.54 73.36 3696.93 2114.70 2.46 0.29 49.18 1.18 23.92 74.28 3623.57 2114.61 2.53 0.31 50.56 1.23 23.35 75.14 3549.29 2114.53 2.59 0.32 51.87 1.28 22.80 75.96 3474.15 2114.45 2.66 0.33 53.12 1.34 22.28 76.74 3398.18 2114.36 2.72 0.35 54.30 1.39 21.79 77.48 3321.44 2114.28 2.77 0.36 55.43 1.44 21.32 78.19 3243.96 2114.20 2.82 0.37 56.49 1.49 20.87 78.86 3165.77 2114.11 2.88 0.38 57.51 1.54 20.45 79.49 3086.92 2114.03 2.92 0.40 58.48 1.58 20.04 80.11 3007.42 2113.95 2.97 0.41 59.40 1.63 19.66 80.68 2927.32 2113.86 3.01 0.42 60.25 1.67 19.30 81.22 2846.63 2113.78 3.05 0.43 61.07 1.72 18.95 81.74 2765.41 2113.70 3.09 0.44 61.89 1.76 18.61 82.25 2683.68 2113.61 3.13 0.45 62.61 1.80 18.30 82.72 2601.42 2113.53 3.17 0.46 63.31 1.84 18.00 83.16 2518.71 2113.45 3.20 0.47 63.99 1.88 17.72 83.59 2435.54 2113.36 3.23 0.48 64.62 1.92 17.45 83.99 2351.95 2113.28 3.26 0.49 65.23 1.96 17.19 84.38 2267.96 2113.20 3.29 0.50 65.81 1.99 16.95 84.74 2183.58 2113.11 3.32 0.51 66.36 2.03 16.71 85.10 2098.84 2113.03 3.34 0.51 66.88 2.06 16.49 85.43 2013.74 2112.95 3.37 0.52 67.37 2.09 16.28 85.74 1928.31 2112.86 3.39 0.53 67.85 2.12 16.08 86.05 1842.57 2112.78 3.41 0.54 68.29 2.15 15.89 86.33 1756.52 2112.70 3.44 0.54 68.74 2.17 15.70 86.61 1670.19 2112.61 3.46 0.55 69.15 2.20 15.53 86.88 1583.58 2112.53 3.48 0.56 69.57 2.22 15.35 87.14 1496.70 2112.45 3.51 0.59 70.10 2.38 15.07 87.56 1409.56 2112.36 0.00 0.00 0.00 0.00 44.07 44.07 1322.00 2112.28 0.00 0.00 0.00 0.00 44.07 44.07 1277.93 2112.20 0.00 0.00 0.00 0.00 44.07 44.07 1233.87 2112.11 0.00 0.00 0.00 0.00 44.07 44.07 1189.80 2112.03 0.00 0.00 0.00 0.00 44.07 44.07 1145.73 2111.95 0.00 0.00 0.00 0.00 44.07 44.07 1101.67 2111.86 0.00 0.00 0.00 0.00 44.07 44.07 1057.60 2111.78 0.00 0.00 0.00 0.00 44.07 44.07 1013.53 2111.70 0.00 0.00 0.00 0.00 44.07 44.07 969.47 2111.61 0.00 0.00 0.00 0.00 44.07 44.07 925.40 2111.53 0.00 0.00 0.00 0.00 44.07 44.07 881.33 2111.45 0.00 0.00 0.00 0.00 44.07 44.07 837.27 2111.36 0.00 0.00 0.00 0.00 44.07 44.07 793.20 2111.28 0.00 0.00 0.00 0.00 44.07 44.07 749.13 2111.20 0.00 0.00 0.00 0.00 44.07 44.07 705.07 2111.11 0.00 0.00 0.00 0.00 44.07 44.07 661.00 2111.03 0.00 0.00 0.00 0.00 44.07 44.07 616.93 2110.95 0.00 0.00 0.00 0.00 44.07 44.07 572.87 2110.86 0.00 0.00 0.00 0.00 44.07 44.07 528.80 2110.78 0.00 0.00 0.00 0.00 44.07 44.07 484.73 2110.70 0.00 0.00 0.00 0.00 44.07 44.07 440.67 2110.61 0.00 0.00 0.00 0.00 44.07 44.07 396.60 2110.53 0.00 0.00 0.00 0.00 44.07 44.07 352.53 2110.45 0.00 0.00 0.00 0.00 44.07 44.07 308.47 2110.36 0.00 0.00 0.00 0.00 44.07 44.07 264.40 2110.28 0.00 0.00 0.00 0.00 44.07 44.07 220.33 2110.20 0.00 0.00 0.00 0.00 44.07 44.07 176.27 2110.11 0.00 0.00 0.00 0.00 44.07 44.07 132.20 2110.03 0.00 0.00 0.00 0.00 44.07 44.07 88.13 2109.95 0.00 0.00 0.00 0.00 44.07 44.07 44.07 2109.86 Project: Proposed Delivery Station BMP-6 �A StormTech® Chamber Model - MC-3500 Units- Imperial Click Here for Metric euaT-O Number of Chambers - 257 4 S-nan f . Number of End Caps - 14 Voids in the stone (porosity) - 40 Base Of STONE Elevation - 2124.67 ft Q Include Perimeter Stone in Calculations Amount of Stone Above Chambers - 12 in Amount of Stone Below Chambers - 9 in Area of system - 1 13891 Isf Min. Area - 13436 sf min. area Height of System (inches) Incremental Single Chamber (cubic feet) Incremental Single End Cap (cubic feet) Incremental Chambers (cubic feet) Incremental End Cap (cubic feet) Incremental Stone (cubic feet) Incremental Ch, Cumulative EC and Stone System (cubic feet) (cubic feet) Elevation (feet) 66 0.00 0.00 0.00 0.00 463.03 463.03 47639.69 2130.17 65 0.00 0.00 0.00 0.00 463.03 463.03 47176.65 2130.09 64 0.00 0.00 0.00 0.00 463.03 463.03 46713.62 2130.00 63 0.00 0.00 0.00 0.00 463.03 463.03 46250.59 2129.92 62 0.00 0.00 0.00 0.00 463.03 463.03 45787.55 2129.84 61 0.00 0.00 0.00 0.00 463.03 463.03 45324.52 2129.75 60 0.00 0.00 0.00 0.00 463.03 463.03 44861.49 2129.67 59 0.00 0.00 0.00 0.00 463.03 463.03 44398.45 2129.59 58 0.00 0.00 0.00 0.00 463.03 463.03 43935.42 2129.50 57 0.00 0.00 0.00 0.00 463.03 463.03 43472.39 2129.42 56 0.00 0.00 0.00 0.00 463.03 463.03 43009.35 2129.34 55 0.00 0.00 0.00 0.00 463.03 463.03 42546.32 2129.25 54 0.06 0.00 14.93 0.00 457.06 471.99 42083.29 2129.17 53 0.19 0.02 49.88 0.33 442.95 493.16 41611.29 2129.09 52 0.29 0.04 75.55 0.53 432.60 508.68 41118.13 2129.00 51 0.40 0.05 103.74 0.72 421.25 525.71 40609.45 2128.92 50 0.69 0.07 176.61 0.95 392.01 569.56 40083.74 2128.84 49 1.03 0.09 264.27 1.24 356.83 622.34 39514.18 2128.75 48 1.25 0.11 321.13 1.50 333.98 656.61 38891.84 2128.67 47 1.42 0.13 365.51 1.77 316.12 683.40 38235.23 2128.59 46 1.57 0.14 404.30 2.02 300.51 706.82 37551.83 2128.50 45 1.71 0.16 438.74 2.28 286.63 727.64 36845.01 2128.42 44 1.83 0.18 469.92 2.54 274.05 746.51 36117.36 2128.34 43 1.94 0.20 498.01 2.81 262.71 763.52 35370.85 2128.25 42 2.04 0.22 524.49 3.06 252.01 779.56 34607.33 2128.17 41 2.13 0.23 548.61 3.29 242.27 794.18 33827.76 2128.09 40 2.22 0.25 571.63 3.51 232.98 808.11 33033.59 2128.00 39 2.31 0.27 592.85 3.72 224.41 820.97 32225.48 2127.92 38 2.38 0.28 612.89 3.92 216.31 833.12 31404.50 2127.84 37 2.46 0.29 631.99 4.12 208.59 844.69 30571.39 2127.75 36 2.53 0.31 649.74 4.31 201.41 855.46 29726.69 2127.67 35 2.59 0.32 666.59 4.50 194.60 865.69 28871.23 2127.59 34 2.66 0.33 682.61 4.68 188.12 875.41 28005.54 2127.50 33 2.72 0.35 697.78 4.86 181.98 884.62 27130.14 2127.42 32 2.77 0.36 712.22 5.04 176.13 893.39 26245.52 2127.34 31 2.82 0.37 725.94 5.21 170.57 901.72 25352.13 2127.25 30 2.88 0.38 738.99 5.38 165.28 909.66 24450.41 2127.17 29 2.92 0.40 751.50 5.54 160.21 917.26 23540.75 2127.09 28 2.97 0.41 763.26 5.71 155.45 924.41 22623.49 2127.00 27 3.01 0.42 774.20 5.86 151.01 931.07 21699.07 2126.92 26 3.05 0.43 784.69 6.02 146.75 937.45 20768.00 2126.84 25 3.09 0.44 795.23 6.17 142.48 943.87 19830.55 2126.75 24 3.13 0.45 804.55 6.31 138.69 949.55 18886.68 2126.67 23 3.17 0.46 813.58 6.45 135.02 955.05 17937.13 2126.59 22 3.20 0.47 822.26 6.59 131.49 960.34 16982.08 2126.50 21 3.23 0.48 830.40 6.72 128.19 965.30 16021.73 2126.42 20 3.26 0.49 838.18 6.85 125.02 970.05 15056.43 2126.34 19 3.29 0.50 845.60 6.97 122.01 974.57 14086.38 2126.25 18 3.32 0.51 852.72 7.09 119.11 978.92 13111.80 2126.17 17 3.34 0.51 859.44 7.20 116.38 983.02 12132.89 2126.09 16 3.37 0.52 865.73 7.31 113.82 986.86 11149.87 2126.00 15 3.39 0.53 871.87 7.41 111.32 990.61 10163.01 2125.92 14 3.41 0.54 877.54 7.51 109.01 994.06 9172.40 2125.84 13 3.44 0.54 883.31 7.60 106.67 997.58 8178.34 2125.75 12 3.46 0.55 888.63 7.69 104.50 1000.83 7180.76 2125.67 11 3.48 0.56 894.02 7.77 102.31 1004.11 6179.93 2125.59 10 3.51 0.59 900.81 8.33 99.38 1008.52 5175.82 2125.50 9 0.00 0.00 0.00 0.00 463.03 463.03 4167.30 2125.42 8 0.00 0.00 0.00 0.00 463.03 463.03 3704.27 2125.34 7 0.00 0.00 0.00 0.00 463.03 463.03 3241.23 2125.25 6 0.00 0.00 0.00 0.00 463.03 463.03 2778.20 2125.17 5 0.00 0.00 0.00 0.00 463.03 463.03 2315.17 2125.09 4 0.00 0.00 0.00 0.00 463.03 463.03 1852.13 2125.00 3 0.00 0.00 0.00 0.00 463.03 463.03 1389.10 2124.92 2 0.00 0.00 0.00 0.00 463.03 463.03 926.07 2124.84 1 0.00 0.00 0.00 0.00 463.03 463.03 463.03 2124.75 WQ Volume: 9889 System Outlet: 2124.67 Volume Below Outlet: 1 0.00 Volume Subtotal: 9889.00 WQ Elevation: 2125.90 BayFilter model 530 Volume per filter 2500 Required Head 32 Minimum Outlet 2122.00 Filter outlet invert 2122 Number of filters Project: Proposed Delivery Station BMP-7 Chamber Model - Units - Number of Chambers - Number of End Caps - Voids in the stone (porosity) - Base of STONE Elevation - Amount of Stone Above Chambers Amount of Stone Below Chambers Area of system - MC-3500 Imperial ci.... m &,a 45 6 40 2123.00 ft 12 in ❑' in 9 in 2702 sf Min. Area - StormTech® A dvinarz of '�1irv�J s elude Perimeter Stone in Calculations 2412 sf min. area Height of System inches Incremental Single Chamber cubic feet Incremental Single End Cap cubic feet Incremental Chambers cubic feet Incremental End Cap cubic feet Incremental Stone cubic feet �IncrementalClh, EC and Stone cubic feet Cumulative System cubic feet Elevation feet 66 0.00 0.00 0.00 0.00 90.07 90.07 8966.82 2128.50 65 0.00 0.00 0.00 0.00 90.07 90.07 8876.75 2128.42 64 0.00 0.00 0.00 0.00 90.07 90.07 8786.68 2128.33 63 0.00 0.00 0.00 0.00 90.07 90.07 8696.62 2128.25 62 0.00 0.00 0.00 0.00 90.07 90.07 8606.55 2128.17 61 0.00 0.00 0.00 0.00 90.07 90.07 8516.48 2128.08 60 0.00 0.00 0.00 0.00 90.07 90.07 8426.42 2128.00 59 0.00 0.00 0.00 0.00 90.07 90.07 8336.35 2127.92 58 0.00 0.00 0.00 0.00 90.07 90.07 8246.28 2127.83 57 0.00 0.00 0.00 0.00 90.07 90.07 8156.22 2127.75 56 0.00 0.00 0.00 0.00 90.07 90.07 8066.15 2127.67 55 0.00 0.00 0.00 0.00 90.07 90.07 7976.08 2127.58 54 0.06 0.00 2.61 0.00 89.02 91.63 7886.02 2127.50 53 0.19 0.02 8.73 0.14 86.52 95.39 7794.38 2127.42 52 0.29 0.04 13.23 0.23 84.69 98.14 7698.99 2127.33 51 0.40 0.05 18.16 0.31 82.68 101.15 7600.85 2127.25 50 0.69 0.07 30.92 0.41 77.54 108.86 7499.70 2127.17 49 1.03 0.09 46.27 0.53 71.35 118.15 7390.83 2127.08 48 1.25 0.11 56.23 0.64 67.32 124.19 7272.69 2127.00 47 1.42 0.13 64.00 0.76 64.16 128.92 7148.50 2126.92 46 1.57 0.14 70.79 0.87 61.40 133.06 7019.57 2126.83 45 1.71 0.16 76.82 0.98 58.95 136.75 6886.51 2126.75 44 1.83 0.18 82.28 1.09 56.72 140.09 6749.77 2126.67 43 1.94 0.20 87.20 1.20 54.71 143.11 6609.68 2126.58 42 2.04 0.22 91.84 1.31 52.81 145.95 6466.57 2126.50 41 2.13 0.23 96.06 1.41 51.08 148.55 6320.61 2126.42 40 2.22 0.25 100.09 1.50 49.43 151.02 6172.06 2126.33 39 2.31 0.27 103.81 1.59 47.91 153.31 6021.04 2126.25 38 2.38 0.28 107.31 1.68 46.47 155.46 5867.74 2126.17 37 2.46 0.29 110.66 1.76 45.10 157.52 5712.27 2126.08 36 2.53 0.31 113.77 1.85 43.82 159.44 5554.75 2126.00 35 2.59 0.32 116.72 1.93 42.61 161.25 5395.32 2125.92 34 2.66 0.33 119.52 2.01 41.45 162.98 5234.06 2125.83 33 2.72 0.35 122.18 2.08 40.36 164.62 5071.08 2125.75 32 2.77 0.36 124.71 2.16 39.32 166.19 4906.45 2125.67 31 2.82 0.37 127.11 2.23 38.33 167.67 4740.27 2125.58 30 2.88 0.38 129.40 2.31 37.39 169.09 4572.59 2125.50 29 2.92 0.40 131.59 2.38 36.48 170.44 4403.51 2125.42 28 2.97 0.41 133.64 2.45 35.63 171.72 4233.06 2125.33 27 3.01 0.42 135.56 2.51 34.84 172.91 4061.34 2125.25 26 3.05 0.43 137.40 2.58 34.08 174.05 3888.43 2125.17 25 3.09 0.44 139.24 2.64 33.31 175.20 3714.38 2125.08 24 3.13 0.45 140.88 2.70 32.63 176.21 3539.18 2125.00 23 3.17 0.46 142.45 2.77 31.98 177.20 3362.97 2124.92 22 3.20 0.47 143.98 2.82 31.35 178.15 3185.77 2124.83 21 3.23 0.48 145.40 2.88 30.75 179.04 3007.62 2124.75 20 3.26 0.49 146.76 2.94 30.19 179.89 2828.59 2124.67 19 3.29 0.50 148.06 2.99 29.65 180.70 2648.70 2124.58 18 3.32 0.51 149.31 3.04 29.13 181.47 2468.01 2124.50 17 3.34 0.51 150.49 3.09 28.64 182.21 2286.53 2124.42 16 3.37 0.52 151.59 3.13 28.18 182.90 2104.32 2124.33 15 3.39 0.53 152.66 3.18 27.73 183.57 1921.42 2124.25 14 3.41 0.54 153.65 3.22 27.32 184.19 1737.85 2124.17 13 3.44 0.54 154.67 3.26 26.90 184.82 1553.66 2124.08 12 3.46 0.55 155.60 3.30 26.51 185.40 1368.84 2124.00 11 3.48 0.56 156.54 3.33 26.12 185.99 1183.44 2123.92 10 3.51 0.59 157.73 3.57 25.55 186.85 997.45 2123.83 9 0.00 0.00 0.00 0.00 90.07 90.07 810.60 2123.75 8 0.00 0.00 0.00 0.00 90.07 90.07 720.53 2123.67 7 0.00 0.00 0.00 0.00 90.07 90.07 630.47 2123.58 6 0.00 0.00 0.00 0.00 90.07 90.07 540.40 2123.50 5 0.00 0.00 0.00 0.00 90.07 90.07 450.33 2123.42 4 0.00 0.00 0.00 0.00 90.07 90.07 360.27 2123.33 3 0.00 0.00 0.00 0.00 90.07 90.07 270.20 2123.25 2 0.00 0.00 0.00 0.00 90.07 90.07 180.13 2123.17 1 0.00 0.00 0.00 0.00 90.07 90.07 90.07 2123.08 WQ Volume: 1 want to fi, System Outlet: This is the 1 Volume Below Outlet:[�IThisisthec Volume Subtotal: 2682.00 Dead stora WQ Elevation: 2124.60 The calcula BayFilter model 522 Volume per filter 1250 cf Required Head 20 in Minimum Outlet 2121.33 Filter outlet invert 2121.33 The reques Number of filters 3 Project: Proposed Delivery Station BMP-8 Chamber Model - Units - Number of Chambers - Number of End Caps - Voids in the stone (porosity) - Base of STONE Elevation - Amount of Stone Above Chambers Amount of Stone Below Chambers Area of system - MC-3500 Imperial ci.... m &,a 141 28 40 2123.00 ft 12 in ❑' in 9 in 8519 sf Min. Area - StormTech® A dvinarz of '�1irv�J s elude Perimeter Stone in Calculations 7713 sf min. area Height of System inches Incremental Single Chamber cubic feet Incremental Single End Cap cubic feet Incremental Chambers cubic feet Incremental End Cap cubic feet Incremental Stone cubic feet �IncrementalClh, EC and Stone cubic feet Cumulative System cubic feet Elevation feet 66 0.00 0.00 0.00 0.00 283.97 283.97 28294.59 2128.50 65 0.00 0.00 0.00 0.00 283.97 283.97 28010.63 2128.42 64 0.00 0.00 0.00 0.00 283.97 283.97 27726.66 2128.33 63 0.00 0.00 0.00 0.00 283.97 283.97 27442.69 2128.25 62 0.00 0.00 0.00 0.00 283.97 283.97 27158.73 2128.17 61 0.00 0.00 0.00 0.00 283.97 283.97 26874.76 2128.08 60 0.00 0.00 0.00 0.00 283.97 283.97 26590.79 2128.00 59 0.00 0.00 0.00 0.00 283.97 283.97 26306.83 2127.92 58 0.00 0.00 0.00 0.00 283.97 283.97 26022.86 2127.83 57 0.00 0.00 0.00 0.00 283.97 283.97 25738.89 2127.75 56 0.00 0.00 0.00 0.00 283.97 283.97 25454.93 2127.67 55 0.00 0.00 0.00 0.00 283.97 283.97 25170.96 2127.58 54 0.06 0.00 8.19 0.00 280.69 288.88 24886.99 2127.50 53 0.19 0.02 27.37 0.67 272.75 300.79 24598.11 2127.42 52 0.29 0.04 41.45 1.05 266.97 309.47 24297.32 2127.33 51 0.40 0.05 56.91 1.44 260.62 318.98 23987.86 2127.25 50 0.69 0.07 96.89 1.89 244.45 343.24 23668.87 2127.17 49 1.03 0.09 144.99 2.47 224.98 372.44 23325.64 2127.08 48 1.25 0.11 176.18 3.00 212.29 391.48 22953.19 2127.00 47 1.42 0.13 200.53 3.54 202.34 406.41 22561.72 2126.92 46 1.57 0.14 221.81 4.04 193.62 419.48 22155.31 2126.83 45 1.71 0.16 240.71 4.56 185.86 431.13 21735.83 2126.75 44 1.83 0.18 257.82 5.09 178.80 441.71 21304.70 2126.67 43 1.94 0.20 273.23 5.61 172.43 451.27 20862.99 2126.58 42 2.04 0.22 287.76 6.11 166.42 460.29 20411.72 2126.50 41 2.13 0.23 300.99 6.58 160.94 468.51 19951.43 2126.42 40 2.22 0.25 313.62 7.01 155.71 476.34 19482.92 2126.33 39 2.31 0.27 325.26 7.44 150.89 483.58 19006.58 2126.25 38 2.38 0.28 336.25 7.84 146.33 490.42 18523.00 2126.17 37 2.46 0.29 346.73 8.23 141.98 496.94 18032.57 2126.08 36 2.53 0.31 356.47 8.62 137.93 503.02 17535.63 2126.00 35 2.59 0.32 365.72 8.99 134.08 508.79 17032.61 2125.92 34 2.66 0.33 374.50 9.36 130.42 514.29 16523.81 2125.83 33 2.72 0.35 382.83 9.72 126.95 519.49 16009.53 2125.75 32 2.77 0.36 390.75 10.08 123.63 524.47 15490.03 2125.67 31 2.82 0.37 398.28 10.42 120.49 529.19 14965.57 2125.58 30 2.88 0.38 405.44 10.76 117.49 533.69 14436.38 2125.50 29 2.92 0.40 412.30 11.09 114.61 538.00 13902.69 2125.42 28 2.97 0.41 418.75 11.41 111.90 542.07 13364.69 2125.33 27 3.01 0.42 424.76 11.72 109.38 545.85 12822.62 2125.25 26 3.05 0.43 430.51 12.03 106.95 549.49 12276.77 2125.17 25 3.09 0.44 436.29 12.33 104.52 553.14 11727.28 2125.08 24 3.13 0.45 441.41 12.62 102.35 556.39 11174.14 2125.00 23 3.17 0.46 446.36 12.90 100.26 559.52 10617.75 2124.92 22 3.20 0.47 451.12 13.18 98.25 562.55 10058.23 2124.83 21 3.23 0.48 455.59 13.44 96.35 565.38 9495.68 2124.75 20 3.26 0.49 459.86 13.70 94.54 568.10 8930.30 2124.67 19 3.29 0.50 463.93 13.94 92.82 570.69 8362.20 2124.58 18 3.32 0.51 467.83 14.18 91.16 573.17 7791.51 2124.50 17 3.34 0.51 471.52 14.41 89.60 575.52 7218.33 2124.42 16 3.37 0.52 474.98 14.62 88.13 577.72 6642.81 2124.33 15 3.39 0.53 478.34 14.83 86.70 579.87 6065.09 2124.25 14 3.41 0.54 481.45 15.02 85.38 581.85 5485.22 2124.17 13 3.44 0.54 484.62 15.21 84.04 583.86 4903.37 2124.08 12 3.46 0.55 487.54 15.38 82.80 585.72 4319.50 2124.00 11 3.48 0.56 490.50 15.55 81.55 587.59 3733.78 2123.92 10 3.51 0.59 494.22 16.66 79.62 590.49 3146.19 2123.83 9 0.00 0.00 0.00 0.00 283.97 283.97 2555.70 2123.75 8 0.00 0.00 0.00 0.00 283.97 283.97 2271.73 2123.67 7 0.00 0.00 0.00 0.00 283.97 283.97 1987.77 2123.58 6 0.00 0.00 0.00 0.00 283.97 283.97 1703.80 2123.50 5 0.00 0.00 0.00 0.00 283.97 283.97 1419.83 2123.42 4 0.00 0.00 0.00 0.00 283.97 283.97 1135.87 2123.33 3 0.00 0.00 0.00 0.00 283.97 283.97 851.90 2123.25 2 0.00 0.00 0.00 0.00 283.97 283.97 567.93 2123.17 1 0.00 0.00 0.00 0.00 283.97 283.97 283.97 2123.08 WQ Volume: 1 want to fi, System Outlet: This is the 1 Volume Below Outlet:[�IThisisthec Volume Subtotal: 8977.00 Dead stora WQ Elevation: 2124.68 The calcula BayFilter model 530 Volume per filter 2500 cf Required Head 32 in Minimum Outlet 2120.33 Filter outlet invert 2020.33 The reques Number of filters 4 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report b � Land Surveying Companies APPENDIX F DRAINAGE MAPS ED-1 —Existing Drainage Area Map PD-1 —Proposed Drainage Area Map PD-2 — Proposed Catchment Drainage Area Map 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com imo I 3N'NIAIN SIIIW BO1Ao^'"sv°O� �``rr lowow"o,�� kVMHOIH NO1SlA09 Z Ire 1N3Wd013n34 43SOdOild o y as HaW L1J m �a Pei, o a a 8 0 5 w W e �uE Vo� `�AA(III II iii��iiil�l(llllll _ o nJ` ii II V Illlli (liiil llll l o �,� y��VAQAAA�AI(((�AIA �IIIIIIIIIII��III��I ��iii'i �'d z O a O z O 0 n r z z w imo I 3N'NIAIN SIIIW ± & BuiAan1n5 Puo� �, lowau,uo,��' `. _ AVMH9IH NO1SlA09 n W W a < g Bui�aauiB [ a,n\ au4 ro 1N3Wd013n34 43SOdOild 0 e e i a> O Z C `o a d m o as 8o 56 ic¢ \ oaf ,3z A��pAOAV vV�.'VOw�o�(OY��i,/r �� V�VAvvvv BO1noti"sv°O� �� 3s ti m= 3N'NIAIN SIIIW AVMHOIH NO1SlA09 m & W w d B�i�a�i4Bro 1 r efi�o= 1N3 Wd013n34 43SOdOild P z a a 8 0 5 6 U o¢ I A . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report b � Land Surveying Companies APPENDIX G SOIL REPORT 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com USDA united states Department of Agriculture N RCS Natural Resources Conservation Service A product of the National Cooperative Soil Survey, a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local participants Custom Soil Resource Report for Henderson County, North Carolina January 30, 2020 Preface Soil surveys contain information that affects land use planning in survey areas. They highlight soil limitations that affect various land uses and provide information about the properties of the soils in the survey areas. Soil surveys are designed for many different users, including farmers, ranchers, foresters, agronomists, urban planners, community officials, engineers, developers, builders, and home buyers. Also, conservationists, teachers, students, and specialists in recreation, waste disposal, and pollution control can use the surveys to help them understand, protect, or enhance the environment. Various land use regulations of Federal, State, and local governments may impose special restrictions on land use or land treatment. Soil surveys identify soil properties that are used in making various land use or land treatment decisions. The information is intended to help the land users identify and reduce the effects of soil limitations on various land uses. The landowner or user is responsible for identifying and complying with existing laws and regulations. Although soil survey information can be used for general farm, local, and wider area planning, onsite investigation is needed to supplement this information in some cases. Examples include soil quality assessments (http://www.nres.usda.gov/wps/ portal/nres/main/soils/health/) and certain conservation and engineering applications. For more detailed information, contact your local USDA Service Center (https:Hoffices.sc.egov.usda.gov/locator/app?agency=nres) or your NRCS State Soil Scientist (http://www.nres.usda.gov/wps/portal/nres/detail/soils/contactus/? cid=nres142p2_053951). Great differences in soil properties can occur within short distances. Some soils are seasonally wet or subject to flooding. Some are too unstable to be used as a foundation for buildings or roads. Clayey or wet soils are poorly suited to use as septic tank absorption fields. A high water table makes a soil poorly suited to basements or underground installations. The National Cooperative Soil Survey is a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local agencies. The Natural Resources Conservation Service (NRCS) has leadership for the Federal part of the National Cooperative Soil Survey. Information about soils is updated periodically. Updated information is available through the NRCS Web Soil Survey, the site for official soil survey information. The U.S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin, age, disability, and where applicable, sex, marital status, familial status, parental status, religion, sexual orientation, genetic information, political beliefs, reprisal, or because all or a part of an individual's income is derived from any public assistance program. (Not all prohibited bases apply to all programs.) Persons with disabilities who require alternative means for communication of program information (Braille, large print, audiotape, etc.) should contact USDA's TARGET Center at (202) 720-2600 (voice and TDD). To file a complaint of discrimination, write to USDA, Director, Office of Civil Rights, 1400 Independence Avenue, S.W., Washington, D.C. 20250-9410 or call (800) 795-3272 (voice) or (202) 720-6382 (TDD). USDA is an equal opportunity provider and employer. Contents Preface.................................................................................................................... 2 How Soil Surveys Are Made..................................................................................5 SoilMap.................................................................................................................. 8 SoilMap................................................................................................................9 Legend................................................................................................................10 MapUnit Legend................................................................................................ 11 MapUnit Descriptions.........................................................................................11 Henderson County, North Carolina.................................................................13 DeB—Delanco (dillard) loam, 2 to 7 percent slopes ................................... 13 HyB—Hayesville loam, 2 to 7 percent slopes ............................................. 14 HyC—Hayesville loam, 7 to 15 percent slopes ........................................... 15 HyE—Hayesville loam, 15 to 25 percent slopes ......................................... 16 Soil Information for All Uses...............................................................................18 Suitabilities and Limitations for Use....................................................................18 Land Classifications........................................................................................18 Soil Taxonomy Classification.......................................................................18 References............................................................................................................ 23 How Soil Surveys Are Made Soil surveys are made to provide information about the soils and miscellaneous areas in a specific area. They include a description of the soils and miscellaneous areas and their location on the landscape and tables that show soil properties and limitations affecting various uses. Soil scientists observed the steepness, length, and shape of the slopes; the general pattern of drainage; the kinds of crops and native plants; and the kinds of bedrock. They observed and described many soil profiles. A soil profile is the sequence of natural layers, or horizons, in a soil. The profile extends from the surface down into the unconsolidated material in which the soil formed or from the surface down to bedrock. The unconsolidated material is devoid of roots and other living organisms and has not been changed by other biological activity. Currently, soils are mapped according to the boundaries of major land resource areas (MLRAs). MLRAs are geographically associated land resource units that share common characteristics related to physiography, geology, climate, water resources, soils, biological resources, and land uses (USDA, 2006). Soil survey areas typically consist of parts of one or more MLRA. The soils and miscellaneous areas in a survey area occur in an orderly pattern that is related to the geology, landforms, relief, climate, and natural vegetation of the area. Each kind of soil and miscellaneous area is associated with a particular kind of landform or with a segment of the landform. By observing the soils and miscellaneous areas in the survey area and relating their position to specific segments of the landform, a soil scientist develops a concept, or model, of how they were formed. Thus, during mapping, this model enables the soil scientist to predict with a considerable degree of accuracy the kind of soil or miscellaneous area at a specific location on the landscape. Commonly, individual soils on the landscape merge into one another as their characteristics gradually change. To construct an accurate soil map, however, soil scientists must determine the boundaries between the soils. They can observe only a limited number of soil profiles. Nevertheless, these observations, supplemented by an understanding of the soil -vegetation -landscape relationship, are sufficient to verify predictions of the kinds of soil in an area and to determine the boundaries. Soil scientists recorded the characteristics of the soil profiles that they studied. They noted soil color, texture, size and shape of soil aggregates, kind and amount of rock fragments, distribution of plant roots, reaction, and other features that enable them to identify soils. After describing the soils in the survey area and determining their properties, the soil scientists assigned the soils to taxonomic classes (units). Taxonomic classes are concepts. Each taxonomic class has a set of soil characteristics with precisely defined limits. The classes are used as a basis for comparison to classify soils systematically. Soil taxonomy, the system of taxonomic classification used in the United States, is based mainly on the kind and character of soil properties and the arrangement of horizons within the profile. After the soil Custom Soil Resource Report scientists classified and named the soils in the survey area, they compared the individual soils with similar soils in the same taxonomic class in other areas so that they could confirm data and assemble additional data based on experience and research. The objective of soil mapping is not to delineate pure map unit components; the objective is to separate the landscape into landforms or landform segments that have similar use and management requirements. Each map unit is defined by a unique combination of soil components and/or miscellaneous areas in predictable proportions. Some components may be highly contrasting to the other components of the map unit. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The delineation of such landforms and landform segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, onsite investigation is needed to define and locate the soils and miscellaneous areas. Soil scientists make many field observations in the process of producing a soil map. The frequency of observation is dependent upon several factors, including scale of mapping, intensity of mapping, design of map units, complexity of the landscape, and experience of the soil scientist. Observations are made to test and refine the soil -landscape model and predictions and to verify the classification of the soils at specific locations. Once the soil -landscape model is refined, a significantly smaller number of measurements of individual soil properties are made and recorded. These measurements may include field measurements, such as those for color, depth to bedrock, and texture, and laboratory measurements, such as those for content of sand, silt, clay, salt, and other components. Properties of each soil typically vary from one point to another across the landscape. Observations for map unit components are aggregated to develop ranges of characteristics for the components. The aggregated values are presented. Direct measurements do not exist for every property presented for every map unit component. Values for some properties are estimated from combinations of other properties. While a soil survey is in progress, samples of some of the soils in the area generally are collected for laboratory analyses and for engineering tests. Soil scientists interpret the data from these analyses and tests as well as the field -observed characteristics and the soil properties to determine the expected behavior of the soils under different uses. Interpretations for all of the soils are field tested through observation of the soils in different uses and under different levels of management. Some interpretations are modified to fit local conditions, and some new interpretations are developed to meet local needs. Data are assembled from other sources, such as research information, production records, and field experience of specialists. For example, data on crop yields under defined levels of management are assembled from farm records and from field or plot experiments on the same kinds of soil. Predictions about soil behavior are based not only on soil properties but also on such variables as climate and biological activity. Soil conditions are predictable over long periods of time, but they are not predictable from year to year. For example, soil scientists can predict with a fairly high degree of accuracy that a given soil will have a high water table within certain depths in most years, but they cannot predict that a high water table will always be at a specific level in the soil on a specific date. After soil scientists located and identified the significant natural bodies of soil in the survey area, they drew the boundaries of these bodies on aerial photographs and Custom Soil Resource Report identified each as a specific map unit. Aerial photographs show trees, buildings, fields, roads, and rivers, all of which help in locating boundaries accurately. Soil Map The soil map section includes the soil map for the defined area of interest, a list of soil map units on the map and extent of each map unit, and cartographic symbols displayed on the map. Also presented are various metadata about data used to produce the map, and a description of each soil map unit. in 359200 359300 35° 25'14"N I • � \\I Custom Soil Resource Report Soil Map 3594M 359500 359600 I I I 35° 24'42"N Iv\� 359200 359300 359400 359500 359600 in Map Scale: 1:4,790 if printed on A portrait (8.5" x 11") sheet. N Meters ° 0 50 100 200 300 Feet 0 200 400 �0 1200 Map projection: Web Mercator Comer coordinates: WGS84 Edge tics: lffM Zone 17N WGS84 9 359700 359700 En 359800 I 35° 25' 14" N 8 r y q•1 . �•L �s 35° 24' 42" N 359800 En O 0 a) U) m , O a) 'o a) m z m o a) a) a) m a) _0 a) LO o m m w m U) _ rn E CL O_ O U m E `p O > > 7 m '6 U O CL m N O m E E a) Q .6 m y 0 m 0 � Q 3 m m a) U U °� o m a) U) E m y s U) a) O a) z O O Utl) 5 aa) U y 6 Q 2i _ y O O O O O L O m y (n C d � a) -0 m a) -O U) 3 m Q N z 2i O 6 a) O , a) O O- �, U W m m O 0 a) `m >• m N m N Q m cma) i m s y Q N c Q a) o m Q O O m a) E U) m O U 46 (6 .0 0 0 2� O (n N 0 O- uj m LL >+ , p 0 a) O U >+ O '� U O O O) U) O E �+ m u) Z U)C O L O a) 2 '� a) m 7 y U O O-0 N C N a- In E a) _ Q U m y E U 3 J 0 N -'E O m— O i = Q y t -0 0 0 (6 E O_ 6 a) m -0 m z E Q Q U C Q N Utl) m a) 0).E 0 N O y Q m E 0) C y a) >+ a) m O t N N jp aai a) O) M m a) m a) E 0 0) N� T O U) C m N y a) N E o) O a) 2 3 U) °? .J 3 C m m U .O U) Q m 2 '� O L O N E Q m U) .30 0 E a) .c a) '6 y N E 0= m O C E m U O a O p U 0 '6 O> aa) m 0 a) m O '6 y O E m 2 O m Q a) a) 7 rn y O i U) 'O y U O N m Q a) 7 >+ U) a) E O O O) o 'Q a) C L ON. O 'N a) O U a) a) 09 O m O y �_ U Q 'O L 0 7 O N m W t O m L W E— U U) a E u) > U Q m H O U) U) U) N H U. U) Q y d y R O Li U R L L Q Q >. 00 0 0 L d Q 0 ° m E O m o y O a 0 CL O U) cn Z > ° aR N L_ y O cn cn � O ° a) R m U 3) .a Q 0 R N R 0 O C p O Z WR a fVn 4 � R F 5 R m W J y a a p y o o ) w o a o a y N y Q E �, R y Q a o a U C > C C a) > > Q Q w 3 R 3 y O > > 2O` w o o w Q _ o o a R R R R y C) LL 3 3 o T -O w > = FL O o `o y Q o cn 0 0 o cn cn p m o R m U o U (7 (7 > R E J J Mn a) a O m m U) R a) U) U) a in U) O U) w a R ❑ R +Vy� ■ y0 ❑ u ® �ap� <> { � yp� "V `} ! o o }� �O y Q y 0 r Custom Soil Resource Report Map Unit Legend Map Unit Symbol Map Unit Name Acres in AOI Percent of AOI DeB Delanco (dillard) loam, 2 to 7 percent slopes 1.8 3.5% HyB Hayesville loam, 2 to 7 percent slopes 9.2 18.0% HyC Hayesville loam, 7 to 15 percent slopes 37.3 73.3% HyE Hayesville loam, 15 to 25 percent slopes 2.7 5.2% Totals for Area of Interest 51.0 100.0% Map Unit Descriptions The map units delineated on the detailed soil maps in a soil survey represent the soils or miscellaneous areas in the survey area. The map unit descriptions, along with the maps, can be used to determine the composition and properties of a unit. A map unit delineation on a soil map represents an area dominated by one or more major kinds of soil or miscellaneous areas. A map unit is identified and named according to the taxonomic classification of the dominant soils. Within a taxonomic class there are precisely defined limits for the properties of the soils. On the landscape, however, the soils are natural phenomena, and they have the characteristic variability of all natural phenomena. Thus, the range of some observed properties may extend beyond the limits defined for a taxonomic class. Areas of soils of a single taxonomic class rarely, if ever, can be mapped without including areas of other taxonomic classes. Consequently, every map unit is made up of the soils or miscellaneous areas for which it is named and some minor components that belong to taxonomic classes other than those of the major soils. Most minor soils have properties similar to those of the dominant soil or soils in the map unit, and thus they do not affect use and management. These are called noncontrasting, or similar, components. They may or may not be mentioned in a particular map unit description. Other minor components, however, have properties and behavioral characteristics divergent enough to affect use or to require different management. These are called contrasting, or dissimilar, components. They generally are in small areas and could not be mapped separately because of the scale used. Some small areas of strongly contrasting soils or miscellaneous areas are identified by a special symbol on the maps. If included in the database for a given area, the contrasting minor components are identified in the map unit descriptions along with some characteristics of each. A few areas of minor components may not have been observed, and consequently they are not mentioned in the descriptions, especially where the pattern was so complex that it was impractical to make enough observations to identify all the soils and miscellaneous areas on the landscape. 11 Custom Soil Resource Report The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The objective of mapping is not to delineate pure taxonomic classes but rather to separate the landscape into landforms or landform segments that have similar use and management requirements. The delineation of such segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, however, onsite investigation is needed to define and locate the soils and miscellaneous areas. An identifying symbol precedes the map unit name in the map unit descriptions. Each description includes general facts about the unit and gives important soil properties and qualities. Soils that have profiles that are almost alike make up a soil series. Except for differences in texture of the surface layer, all the soils of a series have major horizons that are similar in composition, thickness, and arrangement. Soils of one series can differ in texture of the surface layer, slope, stoniness, salinity, degree of erosion, and other characteristics that affect their use. On the basis of such differences, a soil series is divided into soil phases. Most of the areas shown on the detailed soil maps are phases of soil series. The name of a soil phase commonly indicates a feature that affects use or management. For example, Alpha silt loam, 0 to 2 percent slopes, is a phase of the Alpha series. Some map units are made up of two or more major soils or miscellaneous areas. These map units are complexes, associations, or undifferentiated groups. A complex consists of two or more soils or miscellaneous areas in such an intricate pattern or in such small areas that they cannot be shown separately on the maps. The pattern and proportion of the soils or miscellaneous areas are somewhat similar in all areas. Alpha -Beta complex, 0 to 6 percent slopes, is an example. An association is made up of two or more geographically associated soils or miscellaneous areas that are shown as one unit on the maps. Because of present or anticipated uses of the map units in the survey area, it was not considered practical or necessary to map the soils or miscellaneous areas separately. The pattern and relative proportion of the soils or miscellaneous areas are somewhat similar. Alpha -Beta association, 0 to 2 percent slopes, is an example. An undifferentiated group is made up of two or more soils or miscellaneous areas that could be mapped individually but are mapped as one unit because similar interpretations can be made for use and management. The pattern and proportion of the soils or miscellaneous areas in a mapped area are not uniform. An area can be made up of only one of the major soils or miscellaneous areas, or it can be made up of all of them. Alpha and Beta soils, 0 to 2 percent slopes, is an example. Some surveys include miscellaneous areas. Such areas have little or no soil material and support little or no vegetation. Rock outcrop is an example. 12 Custom Soil Resource Report Henderson County, North Carolina DeB—Delanco (dillard) loam, 2 to 7 percent slopes Map Unit Setting National map unit symbol: Icl c Elevation: 1,500 to 3,000 feet Mean annual precipitation: 55 to 75 inches Mean annual air temperature: 50 to 57 degrees F Frost -free period: 150 to 185 days Farmland classification: All areas are prime farmland Map Unit Composition Dillard and similar soils: 95 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Dillard Setting Landform: Depressions on stream terraces Landform position (two-dimensional): Summit Landform position (three-dimensional): Tread Down -slope shape: Linear Across -slope shape: Concave Parent material: Alluvium and/or colluvium derived from igneous and metamorphic rock Typical profile Ap - 0 to 10 inches: loam Bt - 10 to 30 inches: clay loam BCg - 30 to 40 inches: sandy loam Cg - 40 to 80 inches: sandy loam Properties and qualities Slope: 2 to 7 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Moderately well drained Runoff class: Medium Capacity of the most limiting layer to transmit water (Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: About 30 to 42 inches Frequency of flooding: Occasional Frequency of ponding: None Available water storage in profile: Moderate (about 8.2 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 2e Hydrologic Soil Group: C Hydric soil rating: No 13 Custom Soil Resource Report HyB—Hayesville loam, 2 to 7 percent slopes Map Unit Setting National map unit symbol: Icl s Elevation: 1,760 to 2,360 feet Mean annual precipitation: 50 to 62 inches Mean annual air temperature: 46 to 57 degrees F Frost -free period: 130 to 180 days Farmland classification: All areas are prime farmland Map Unit Composition Hayesville and similar soils: 90 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Hayesville Setting Landform: Mountain slopes, ridges Landform position (two-dimensional): Summit Landform position (three-dimensional): Mountaintop, crest Down -slope shape: Convex Across -slope shape: Convex Parent material: Residuum weathered from igneous and metamorphic rock Typical profile A - 0 to 5 inches: loam Bt - 5 to 38 inches: clay BC - 38 to 48 inches: sandy clay loam C - 48 to 80 inches: fine sandy loam Properties and qualities Slope: 2 to 8 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water (Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water storage in profile: High (about 9.9 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 2e Hydrologic Soil Group: B Hydric soil rating: No 14 Custom Soil Resource Report HyC—Hayesville loam, 7 to 15 percent slopes Map Unit Setting National map unit symbol: Icl t Elevation: 1,110 to 2,580 feet Mean annual precipitation: 48 to 60 inches Mean annual air temperature: 46 to 57 degrees F Frost -free period: 124 to 176 days Farmland classification: Farmland of statewide importance Map Unit Composition Hayesville and similar soils: 90 percent Minor components: 10 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Hayesville Setting Landform: Ridges Landform position (two-dimensional): Summit Landform position (three-dimensional): Interfluve Down -slope shape: Linear Across -slope shape: Convex Parent material: Residuum weathered from amphibolite Typical profile A - 0 to 5 inches: loam Bt - 5 to 38 inches: clay BC - 38 to 48 inches: sandy clay loam C - 48 to 80 inches: fine sandy loam Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water (Ksat): Moderately low to moderately high (0.06 to 0.20 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water storage in profile: High (about 9.9 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3e Hydrologic Soil Group: C Hydric soil rating: No 15 Custom Soil Resource Report Minor Components Evard, stony Percent of map unit: 6 percent Landform: Ridges Landform position (two-dimensional): Summit, shoulder Landform position (three-dimensional): Interfluve Down -slope shape: Convex Across -slope shape: Linear Hydric soil rating: No Cowee, stony Percent of map unit: 4 percent Landform: Ridges Landform position (two-dimensional): Summit, shoulder Landform position (three-dimensional): Interfluve Down -slope shape: Convex Across -slope shape: Linear Hydric soil rating: No HyE—Hayesville loam, 15 to 25 percent slopes Map Unit Setting National map unit symbol: Icl v Elevation: 1,060 to 1,950 feet Mean annual precipitation: 48 to 60 inches Mean annual air temperature: 46 to 57 degrees F Frost -free period: 124 to 176 days Farmland classification: Farmland of local importance Map Unit Composition Hayesville and similar soils: 90 percent Minor components: 10 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Hayesville Setting Landform: Ridges on hillslopes Landform position (two-dimensional): Summit Landform position (three-dimensional): Interfluve Down -slope shape: Convex, linear Across -slope shape: Linear, convex Parent material: Residuum weathered from amphibolite Typical profile A - 0 to 5 inches: loam Bt - 5 to 38 inches: clay BC - 38 to 48 inches: sandy clay loam C - 48 to 80 inches: fine sandy loam it. Custom Soil Resource Report Properties and qualities Slope: 15 to 30 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Well drained Runoff class: High Capacity of the most limiting layer to transmit water (Ksat): Moderately low to moderately high (0.06 to 0.20 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water storage in profile: High (about 9.9 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 4e Hydrologic Soil Group: C Hydric soil rating: No Minor Components Evard, stony Percent of map unit. 6 percent Landform: Ridges Landform position (two-dimensional): Summit, shoulder Landform position (three-dimensional): Mountaintop, interfluve Down -slope shape: Linear Across -slope shape: Convex Hydric soil rating: No Cowee, stony Percent of map unit. 4 percent Landform: Ridges Landform position (two-dimensional): Summit, shoulder Landform position (three-dimensional): Mountaintop Down -slope shape: Linear Across -slope shape: Convex Hydric soil rating: No 17 Soil Information for All Uses Suitabilities and Limitations for Use The Suitabilities and Limitations for Use section includes various soil interpretations displayed as thematic maps with a summary table for the soil map units in the selected area of interest. A single value or rating for each map unit is generated by aggregating the interpretive ratings of individual map unit components. This aggregation process is defined for each interpretation. Land Classifications Land Classifications are specified land use and management groupings that are assigned to soil areas because combinations of soil have similar behavior for specified practices. Most are based on soil properties and other factors that directly influence the specific use of the soil. Example classifications include ecological site classification, farmland classification, irrigated and nonirrigated land capability classification, and hydric rating. Soil Taxonomy Classification This rating presents the taxonomic classification based on Soil Taxonomy. The system of soil classification used by the National Cooperative Soil Survey has six categories (Soil Survey Staff, 1999 and 2003). Beginning with the broadest, these categories are the order, suborder, great group, subgroup, family, and series. Classification is based on soil properties observed in the field or inferred from those observations or from laboratory measurements. This table shows the classification of the soils in the survey area. The categories are defined in the following paragraphs. ORDER. Twelve soil orders are recognized. The differences among orders reflect the dominant soil -forming processes and the degree of soil formation. Each order is identified by a word ending in sol. An example is Alfisols. SUBORDER. Each order is divided into suborders primarily on the basis of properties that influence soil genesis and are important to plant growth or properties that reflect the most important variables within the orders. The last syllable in the 18 Custom Soil Resource Report name of a suborder indicates the order. An example is Udalfs (Ud, meaning humid, plus alfs, from Alfisols). GREAT GROUP. Each suborder is divided into great groups on the basis of close similarities in kind, arrangement, and degree of development of pedogenic horizons; soil moisture and temperature regimes; type of saturation; and base status. Each great group is identified by the name of a suborder and by a prefix that indicates a property of the soil. An example is Hapludalfs (Hapl, meaning minimal horizonation, plus udalfs, the suborder of the Alfisols that has a udic moisture regime). SUBGROUP. Each great group has a typic subgroup. Other subgroups are intergrades or extragrades. The typic subgroup is the central concept of the great group; it is not necessarily the most extensive. Intergrades are transitions to other orders, suborders, or great groups. Extragrades have some properties that are not representative of the great group but do not indicate transitions to any other taxonomic class. Each subgroup is identified by one or more adjectives preceding the name of the great group. The adjective Typic identifies the subgroup that typifies the great group. An example is Typic Hapludalfs. FAMILY. Families are established within a subgroup on the basis of physical and chemical properties and other characteristics that affect management. Generally, the properties are those of horizons below plow depth where there is much biological activity. Among the properties and characteristics considered are particle - size class, mineralogy class, cation -exchange activity class, soil temperature regime, soil depth, and reaction class. A family name consists of the name of a subgroup preceded by terms that indicate soil properties. An example is fine -loamy, mixed, active, mesic Typic Hapludalfs. SERIES. The series consists of soils within a family that have horizons similar in color, texture, structure, reaction, consistence, mineral and chemical composition, and arrangement in the profile. References: Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys. 2nd edition. Natural Resources Conservation Service. U.S. Department of Agriculture Handbook 436. Soil Survey Staff. 2006. Keys to soil taxonomy. 10th edition. U.S. Department of Agriculture, Natural Resources Conservation Service. (The soils in a given survey area may have been classified according to earlier editions of this publication.) 19 Custom Soil Resource Report Map —Soil Taxonomy Classification in E 359200 359300 359400 359500 359600 359700 359800 35° 25' 14" N I I a I I 4^ `� I 35° 25' 14" N tP+ w s! w • a Ab N o r:r f - 1 i' ' y X'•J •• Soil Map may not 19 valid at this scale. 35° 24'42"N � i� 350 24'42" N 359200 359300 359400 359500 359600 359700 359800 3: 3: in En Map Scale: 1:4,790 if printed on A portrait (8.5" x 11") sheet. N Meters ° 0 50 100 200 300 Feet 0 200 400 800 1200 Map projection: Web Mercator Comermordinates: WGS84 Edge tics: UTM 7_a3e 17N WGS84 20 -t O Q N N U L O Q' O U) E O (n U O 0 U) U) m , O a) '0 a) m z m o a) a) a) m a) _0 a) LO o m m w m U) _ rn E CL O_ O U m E `p O > 7 m 'O o O CL m N O m E E a) Q .6 m y 0 m 0 � Q 3 m m a) U U °� o m U) U) E m y s U) a) O a) -O z O O Utl) 5 aa) U y 76 Q 2i _ y O O O O O L O m y (n C d U) -0 m U) -O U) 3 m Q N z 2i O 6 U) O , a) O O- �, U W m m O 0 U) `m >• m N m N Q m cma) i m s y Q N c Q a) o m Q O O m U) E U) m O U 46 (6 .0 O O 2� O (n N 0 O- uj m LL >+ , p 0 U) O U >+ O '� U O O O) U) O E �+ m u) Z U)O N O O N U) 2 O ,O N m 7 y U O 2-0 N O N a- In E U) _ Q U m y E U 3 J 0 N -'E O m— O i = Q y t -O O O (6 E O_ 6 U) m -0 m z E Q Q U C Q N Utl) m U) 0 N O .E y Q m 0) E C y a) >+ a) m O t N N jp aai a) O) M m U) m U) � E 0 0) N� >' p 'O O y O_ a) U) U) U N (6 7 ,U) '6 U) Q U) ._ O 'O T -0m O_ O U) C m U) y a) N E o) D a) 2 3 (a) U) °? ".' C m (6 U .O U) Q m 2 '� O 0 L C N E Q m U) .30 0 E U) .c N 'O y N E 0= m O C E m U O a : s o w -6 O> aa) m o a) m O 'O y O E m 2 C m Q a) U) 7 rn y O i U) '6 y U C 2 m CL a) 7 >+ U) a) E O O O) o 'Q N C L ON. O 'N a) O U a) a) 09 O m O y o Q 'O L 0 7 O N m W t O m L W E— U U) a E u) > U Q m H O U) U) U) N H U. U) y N L T L CL � °' y y y o o R r a) O C R O R a U) R U J Q C O Z 0.O u W t* R F ,w V F R m W a a o Q R "w a° a) a U > a) R a > a) a R > R E a a) y R x a) o E a a) y R x a) o E a a) y x a) R CC Uw o U —' E E w�— E E w�— E E `o`O a O o Of o E .> w a R Co R +_ a) Y U o y R Co Y f .> w a R w• a) U o f .> w .y. R R R Y m a R a) y Q o Y O a — (4 (� y Y O a — (4 (` Y O a — (4 E y d U C U C E N O r_ U J C U C E N p U d C U C E N R O y d Q y O) c LL HT LL N 2 Z O) LL HT c LL N 2 Z O) LL HT LL N 2 c Z fn 16 , ❑ '0 R LL 0 R❑ y p In fn it 0 fn a) is Q g cn r N Custom Soil Resource Report Table —Soil Taxonomy Classification Map unit symbol Map unit name Rating Acres in AOI Percent of AOI DeB Delanco (dillard) loam, 2 to 7 percent slopes Fine -loamy, mixed, semiactive, mesic Aquic Hapludults 1.8 3.5% HyB Hayesville loam, 2 to 7 percent slopes Fine, kaolinitic, mesic Typic Kanhapludults 9.2 18.0% HyC Hayesville loam, 7 to 15 percent slopes Fine, kaolinitic, mesic Typic Kanhapludults 37.3 73.3% HyE Hayesville loam, 15 to 25 percent slopes Fine, kaolinitic, mesic Typic Kanhapludults 2.7 5.2% Totals for Area of Interest 51.0 100.0% Rating Options —Soil Taxonomy Classification Aggregation Method: Dominant Condition Component Percent Cutoff.- None Specified Tie -break Rule: Lower 22 References American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing. 24th edition. American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes. ASTM Standard D2487-00. Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe. 1979. Classification of wetlands and deep -water habitats of the United States. U.S. Fish and Wildlife Service FWS/OBS-79/31. Federal Register. July 13, 1994. Changes in hydric soils of the United States. Federal Register. September 18, 2002. Hydric soils of the United States. Hurt, G.W., and L.M. Vasilas, editors. Version 6.0, 2006. Field indicators of hydric soils in the United States. National Research Council. 1995. Wetlands: Characteristics and boundaries. Soil Survey Division Staff. 1993. Soil survey manual. Soil Conservation Service. U.S. Department of Agriculture Handbook 18. http://www.nres.usda.gov/wps/portal/ n res/d eta i I/n ati o n a I/s o i Is/?cid = n res 142 p2_0 54262 Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys. 2nd edition. Natural Resources Conservation Service, U.S. Department of Agriculture Handbook 436. http:// www. nres. usda.gov/wps/portal/nres/detail/national/soils/?cid=nres142p2_053577 Soil Survey Staff. 2010. Keys to soil taxonomy. 11th edition. U.S. Department of Agriculture, Natural Resources Conservation Service. http:// www. nres. usda.gov/wps/portal/nres/detail/national/soils/?cid=nres142p2_053580 Tiner, R.W., Jr. 1985. Wetlands of Delaware. U.S. Fish and Wildlife Service and Delaware Department of Natural Resources and Environmental Control, Wetlands Section. United States Army Corps of Engineers, Environmental Laboratory. 1987. Corps of Engineers wetlands delineation manual. Waterways Experiment Station Technical Report Y-87-1. United States Department of Agriculture, Natural Resources Conservation Service. National forestry manual. http://www.nres.usda.gov/wps/portal/nres/detail/soils/ home/?cid=nres142p2_053374 United States Department of Agriculture, Natural Resources Conservation Service. National range and pasture handbook. http://www.nres.usda.gov/wps/portal/nres/ detail/national/landuse/rangepastu re/?cid=stelprdb1043084 23 Custom Soil Resource Report United States Department of Agriculture, Natural Resources Conservation Service. National soil survey handbook, title 430-VI. http://www.nres.usda.gov/wps/portal/ n res/d eta i I/so i Is/scie ntists/?cid=n res 142 p2_054242 United States Department of Agriculture, Natural Resources Conservation Service. 2006. Land resource regions and major land resource areas of the United States, the Caribbean, and the Pacific Basin. U.S. Department of Agriculture Handbook 296. http://www.nres.usda.gov/wps/portal/nres/detail/national/soils/? cid = n res 142 p2_05 3624 United States Department of Agriculture, Soil Conservation Service. 1961. Land capability classification. U.S. Department of Agriculture Handbook 210. http:H www.nrcs.usda.gov/lnternet/FSE—DOCUMENTS/nrcsl 42p2_052290. pdf 24 . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report b � Land Surveying Companies APPENDIX H GEOTECHNICAL REPORT 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com ECS Southeast, LLP Subsurface Exploration / Preliminary Geotechnical Evaluation Project AV — Broadpointe Site Mills River, Henderson County, North Carolina Samet Corporation ECS Project Number 31-3861 October 2, 2019 Revised October 3, 20191 Revised November 20, 20192 ' This report was revised to add our estimates of seismic site classification and our estimates of preliminary pavement section. 2 This report was revised to correct the B-2 surface elevation. Changes were made to the boring log and profile. ECS SOUTHEAST, LLP "Setting the Standard for Service' Geotechnical • Construction Materials • Environmental • Facilities NC Registered EngineeFirm F NC Registered Geologisktt s Firm C-405-406 SC Registered Engineering Firm 3239 October 2, 2019 Revised October 3, 2019 Revised November 20, 2019 Mr. Brian Hall, LEED AP BD+C Director of Development 309 Gallimore Dairy Road, Suite 102 Greensboro, North Carolina 27409 Reference: Revised Report of Subsurface Exploration / Preliminary Geotechnical Evaluation Project AV — Broadpointe Site Boylston Highway (NC Highway 280) Mills River, Henderson County, North Carolina ECS Project No. 31-3861 Mr. Hall: ECS Southeast, LLC (ECS) has completed the subsurface exploration, laboratory testing, and geotechnical engineering analyses for the above -referenced lot. Our services were performed in general accordance with our Proposal Number 31-5865-P, dated May 30, 2019. This preliminary report presents the findings of our subsurface exploration and our evaluations, as well as preliminary recommendations regarding geotechnical-related design and construction considerations for the site. It has been our pleasure to be of service to you. We would appreciate the opportunity to provide continuing services during planning, design, and construction to help carry out some of the recommendations contained herein. Please contact us should you have any questions about the information contained in this report, or if we can be of further assistance to you. Respectfully submitted, ECS SOUTHEAST, LLP represented by: Matthew D. Monteith, P.E. Geotechnical Department Manager NC License No. 047853 Matthew S. Fogleman, P.E. Principal Engineer 1900 Hendersonville Road, Suite 10, Asheville, NC 28803 • T: 828.665.2307 • F: 828.665.8128 • ecslimited.com ECS Capitol Services, PLLC • ECS Florida, LLC • ECS Mid -Atlantic, LLC • ECS Midwest, LLC • ECS Southeast, LLP • ECS Southwest, LLP Project AV—BroadpointeSite November 20, 2019 ECS Project No. 31-3861 Page 3 TABLE OF CONTENTS PAGE 1.0 INTRODUCTION 5 1.1 General 5 1.2 Scope of Services 5 2.0 SITE INFORMATION 6 2.1 Site Information 6 2.2 Site History and Previous Uses 6 2.3 Proposed Construction 6 3.0 FIELD EXPLORATION 7 3.1 Mechanized Soil Test Borings 7 3.2 Laboratory Testing 7 4.0 SITE AND SUBSURFACE CONDITIONS 8 4.1 Soil and Geologic Maps 8 4.2 Site Observations 10 5.0 PRELIMINARY RECOMMENDATIONS 11 5.1 Building Locations and Site Grades 12 5.2 Foundations 13 5.3 Floor Systems 14 5.4 Pavement Sections 15 5.5 Seismic Site Classification 16 6.0 PRELIMINARY CONSTRUCTION CONSIDERATIONS 16 6.1 Subgrade Preparation 16 6.2 Excavation 17 6.3 Dewatering 18 6.4 Engineered Fill Materials 18 6.5 Compaction 19 6.6 Slope Construction and Erosion Protection 20 6.7 Additional Considerations 20 7.0 CLOSING 21 Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 4 EXECUTIVE SUMMARY This executive summary is solely provided to give a brief overview of the project findings. The summary is abbreviated. Information gleaned from the Executive Summary should not be utilized in lieu of reading the entire geotechnical report. Substrata generally consisted of residual sandy silt (ML) underlain by residual silty fine to medium sand (SM). The silt was generally stiff and the sand was generally medium dense. Partially weathered rock, weathered rock, and crystalline bedrock were not encountered within the drilled depths or observed during site reconnaissance. Groundwater was encountered during drilling at B-3 and B-5 at depths of 15 feet and 14 feet, respectively, or elevation 2113' and 2116', respectively. Groundwater was not encountered in the remaining four (4) borings during drilling. The strata encountered in the test borings appear to be suitable for reuse as engineered fill as they did not contain organics or highly plastic soils. The data implies that conventional excavation techniques are likely during site development. Materials hard enough to cause concern for heavy ripping or blasting excavation were not encountered. Moisture -sensitive soils may be present and could create material workability and reuse issues if not properly protected from water. The primary geotechnical considerations identified on this property include (1) the potential for buried debris, vegetation, and organic laden soil from historical timber logging operations, (2) soft compressible alluvial/colluvial soils and groundwater in the drainage basins, and (3) the massive 2H:1V cut slope along Boylston Highway. Risks related to buried debris can be managed by carefully observing earthwork operations, and perhaps by observing additional exploratory test excavations prior to site development. Highly to moderately compressible substrata were not found during the field exploration; however, compressible soils may be present in low lying drainage areas. Compressible soils can be further investigated through additional field exploration such as test excavations and/or soil borings, and should be considered during the design -level geotechnical evaluation. Slope stability of the massive cut slope along Boylston Highway is unknown. Care should be exercised when siting buildings and other structures near the slope. Structures built within a distance of about half of the slope height from the slope's crest may be damaged if slope movement occurs. Ideally, the buildings should not be sited within the zone of potential movement unless additional geotechnical slope evaluation indicates otherwise. Site grades should be designed and finished floor elevations should be established to provide at least 5 feet of clearance between the finished elevation and groundwater. Buried stormwater structures planned near areas of groundwater should ideally be deigned above groundwater; otherwise, they will need to be designed to be watertight and to resist buoyancy effects. Spread footing foundations can likely be used for lightly to moderately loaded structures, and maybe even heavily loaded structures. Some undercutting of soft soils may be required to allow use of footing foundations. Preliminary data implies that undercuts shouldn't exceed about 4 feet. Deep foundations such as auger cast piles, driven piles, drilled shafts, or micropiles may be required for foundations near the Boylston Highway cut slope. Heavier -loaded footing foundations may require the use of aggregate piers to mitigate damaging settlement effects. Project AV — Broadpointe Site ECS Project No. 31-3861 1.0 INTRODUCTION 1.1 General November 20, 2019 Page S The purpose of this evaluation was to explore and comment on the subsurface conditions at the subject property as it relates to potential industrial development, and provide preliminary recommendations regarding foundations, slabs, pavements, earthwork, construction, and other geotechnical-related considerations of design and construction. During the early planning stage of design and construction, this evaluation was focused on the natural site conditions and the general suitability of subsurface conditions and topography for the proposed use. 1.2 Scope of Services ECS' scope included drilling six (6) mechanized soil test borings at approximate locations shown in Appendix A. The purpose of the borings was to evaluate the general subsurface conditions. A laboratory testing program was also implemented to help characterize the physical and engineering properties of the subsurface strata. This report contains a description of the exploratory and testing procedures, presents our findings and evaluations, and includes the following. • Project description and site observations. • Information on site conditions including surface drainage, geologic information, and special site features. • Description of the field exploration tests performed. Representation of the field data obtained will be provided, including boring logs, boring location diagrams, and laboratory summaries. • A discussion of geotechnical site conditions which could impact the proposed construction, such as shallow rock, undocumented fill, or groundwater, if encountered. • General site grading recommendations and an evaluation of the on -site soils regarding the suitability of the materials for reuse as structural fill and backfill. • Preliminary considerations regarding suitable building foundation types. Although ECS offers other services for various projects, our scope of services for this geotechnical evaluation did not include detailed recommendations for foundation design, retaining all design, construction dewatering, excavation shoring, allowable temporary slopes or erosion control, pavement design, seismic site classification, cost of quantity estimates, or construction materials services. Project AV — Broadpointe Site ECS Project No. 31-3861 2.0 SITE INFORMATION 2.1 Site Information November 20, 2019 Page 6 The property is comprised of a 28.88-acre parcel designated as Henderson County PIN # 9642- 35-0270. The property is located east of the intersection of Boylston Highway and Fanning Fields Road, between Fanning Fields Road and the French Broad River in Mills River, North Carolina. The forested -and -farm -covered triangle -shaped property is bounded by Boylston Highway and industrial developments to the north and west, Miles View Drive and industrial properties to the south, residential and forested property to the east. Beyond the residential and forested property sits the French Broad River with a water surface elevation near 2050' which is approximately 40 to 120 feet lower than this property according to Google Earth. Topographically, the terrain consists of broadly sloping hills and drainage basins. The high point is near elevation 2180.7', located along the south portion of the east property line and a broad forming lobe, according to survey contours provided by Sacks Survey & Mapping. The broad forming lobe is oriented north -south and slopes down to the west, north, and east. A broadly - sloped north -south forming ephemeral drainage is located in the southwest portion of the property and on the west facing lobe -slope. Another north -south trending drainage is located in the north region of the parcel on the north to east facing lobe slope. The drainage contains water that flows to a culvert that crosses under Boylston Highway. Another north -south trending lobe or ridge, albeit steeper, is located in the east portion of the property and east of the north drainage. Boylston Highway is much lower than the property, and appears to have been cut to its current elevation. A 40-feet tall cut slope with an inclination in the range of 2H:1V spans the distance between the highway and the property line. With the exception of the Boylston Highway slopes, much of the site slopes appear to be natural with inclinations varying between flat to about 5H:1V. 2.2 Site History and Previous Uses A property's former use(s) can impact the geotechnical performance and construction costs of a project. In order to better understand these aspects, we reviewed published USGS topographic maps and Google EarthT`" aerial photographs. Review of USGS topographic maps dated between 1905 and 2019 indicate that the property has been used as forest and farm land over much of its modern history. Boylston Highway was constructed in the late 1980s or early 1990s according to date ranges on USGS topographic maps and aerial photographs As discussed previously, the portion of Boylston Highway next to the property was cut into place. Much of the landscape in Western North Carolina was harvested for timber at some point in the past. There was no direct evidence discovered during document review that imply that this property has been logged. Nevertheless, given previous site activity and uses, buried vegetation, stumps, and remnants of logging may be present. 2.3 Proposed Construction The property is being considered for industrial development. Building locations, conceptual site layouts, structural loading information, finished floor elevations, or site grading information was Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 7 not available at time this report was written. In addition to more site -specific geotechnical field exploration, building type(s), locations, elevations, a proposed grading plan, and estimated loading information will be required for a more detailed foundation analysis. Based on existing site terrain, we suspect that earthwork will consist of cutting of ridges/lobes and filling of the drainage basins to create a more level pad. We anticipate that some use of site retaining walls may be required to create grade transitions. 3.0 FIELD EXPLORATION 3.1 Mechanized Soil Test Borings Six (6) mechanized soil test borings (Borings B-1 through B-6) were drilled to depths of 15 to 25 feet below the existing ground surface at the approximate locations shown on the Boring Location Diagrams in Appendix A. The boring locations were established in the field by ECS personnel using GPS technology with a horizontal degree of accuracy of +/- 5 feet. The boring elevations were extracted from the surveyor's topographic map by overlaying the estimated locations onto the map. The boring locations and elevations shown should be considered approximate. A Subsurface Soil Profile and individual Boring Logs are provided in Appendix B for reference. The mechanized soil borings were performed using a track -mounted, CME550X drilling rig. Representative soil samples were obtained by means of the split -barrel sampling procedure in general accordance with ASTM D 1586. In this procedure, a 2-inch O.D., split -barrel sampler is driven into the soil a distance of 18 inches by a 140-pound hammer falling 30 inches. The number of blows required to drive the sampler through a 12-inch interval is termed the Standard Penetration Test value (N-value) and is indicated for each sample on the boring logs. This value can be used as a qualitative indication of the in -place relative density of non -cohesive soils. In a less reliable way, it also indicates the consistency of cohesive soils. This indication is qualitative, since many factors can significantly affect the standard penetration resistance value and prevent a direct correlation between drill crews, drill rigs, drilling procedures, and hammer -rod -sampler assemblies. Split -spoon samples were obtained at approximate 2% foot intervals within the upper 10 feet of the test borings and at approximate 5-foot intervals thereafter. The drilling crew maintained a field log of the strata encountered in the borings. After recovery, each sample was removed from the sampler and visually classified. Representative portions of each sample were then sealed in airtight bags and returned to our laboratory for visual examination by a geotechnical engineer and subsequent laboratory testing. 3.2 Laboratory Testing Representative soil samples obtained during our field exploration were reviewed by the ECS project engineer, and laboratory testing was assigned to select samples to aid in the field classifications and to help estimate pertinent index and engineering properties of the on -site soils. The geotechnical laboratory testing included: • Visual classification of soil samples in general conformance with ASTM D 2487, Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 8 • Index property testing of select soil samples including: o Natural moisture content determinations (ASTM D 2216), o Sieve Analysis (ASTM D 6913) o Atterberg Limits tests (ASTM D 4318) The laboratory test results are included on the Laboratory Testing Summary provided in Appendix C as well as on the individual laboratory reports. The moisture content test results are also presented on the individual Boring Logs. 4.0 SITE AND SUBSURFACE CONDITIONS 4.1 Soil and Geologic Maps Geologic mapping' indicates that this property is located within the Brevard Fault zone of the eastern Blue Ridge Physiographic Province of Western North Carolina. The eastern Blue Ridge consists of a variety of igneous and high-grade metamorphic rocks, including numerous granite bodies. The metamorphic rocks were originally part of the Precambrian basement, as were the volcanic and sedimentary rocks laid down as the proto-Atlantic Ocean began to close during the early Paleozoic era. Migmatites, rocks with both metamorphic and igneous characteristics, make up other eastern Blue Ridge rocks and reveal the very high temperatures reached by these rocks during mountain uplift. The soils in the Blue Ridge Province typically consist of residuum (weathered in -place soils) derived from the parent bedrock. According to a Geologic Map of North Carolina, the bedrock is comprised of Precambrian to Paleozoic age mica schist containing plagioclase, quartz, feldspars, biotitie, and muscovite. The schist contains local gneiss and at some places is interlayered with micaceous feldspathic metasandstone. 4.1.1 Soil Survey Maps The USDA Natural Resources Conservation Service Web Soil Survey, which provides soil information to a shallow depth (generally less than 5 feet), indicates that the site soils are mapped as: • DeB — This soil type covers a very small portion of the property and consists of alluvium and/or colluvium derived from igneous or metamorphic rock located within stream terraces with slopes between 2 to 7 percent grade. Depth to groundwater is reportedly in the 2.5 to 3.5 feet range. • HyB — This soil type consists of residuum weathered from igneous or metamorphic rock located on mountain slopes and ridges with slopes between 2 to 7 percent grade. Depth to groundwater is reported to be more than 5.5 feet. 3 Dabbagh, A.D., 1981, Geologic map and mineral resources summary ofthe Skyland quadrangle, North Carolina: North Carolina Geological Survey, Geologic Map - 7.5-minute quadrangle maps and mineral resource summary GM 193-NE, scale 1:24,000 Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 9 • HyC — This soil type covers most of the property and consists of residuum weathered from amphibolite located on ridges with slopes between 8 to 15 percent grade. Depth to groundwater is reported to be more than 5.5 feet. • HyE — This soil type consists of residuum weathered from amphibolite located on ridges with slopes between 15 to 25 percent grade. Depth to groundwater is reported to be more than 5.5 feet. LI Figure 4.1.1 USDA Soil Survey Map A' A Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 10 Residuum: The residual soils in this region are the product of the in -place chemical weathering of the parent bedrock. The mineral composition of the parent rock and the environment in which weathering occurs largely control the resulting soil's engineering characteristics. Residuum normally retains the structure of the original parent bedrock, but it typically has a much lower density and exhibits strengths and other engineering properties typical of soil, not bedrock. In a mature weathering profile, the residuum is generally found to be finer grained at the surface where more extensive weathering has occurred. The particle size of the soils generally becomes more granular with increasing depth and gradually changes first to weathered and finally to unweathered parent bedrock. The boundary between soil and rock in this geology is not sharply defined. A transitional zone termed "partially weathered rock" is normally found overlying the parent bedrock. Partially weathered rock is defined for engineering purposes as residual material with standard penetration test resistance exceeding 100 blows per foot but can still be penetrated with a power auger. The transition between hard/dense residual soils and partially weathered rock can occur at irregular depths due to variations in the degree of weathering. The variable weathering can also cause rock fragments and boulders to remain within the residual soil matrix. 4.2 Site Observations The property was observed in a similar condition that is described in the previous sections of this report. The property is covered with timber forest vegetation and farmland. The property was being farmed for corn during the time of our visit, and the crop locations limited drilling access. There were no significant geotechnical or geologic conditions observed at the ground surface during our site visit. 4.3 Subsurface Strata The observed subsurface conditions were generally consistent with published mapping. Table 4.3.1 includes a generalized characterization of the strata encountered in the borings. Please refer to the Subsurface Soil Profile and Boring Logs in Appendix B for subsurface information at specific locations. Table 4.3.1 Generalized Subsurface Stratigraphy Approximate Depth Stratum Description Surface X TOPSOIL (1"-3" thick) RESIDUUM: SANDY SILT (ML), contains no to slight mica, light brown, orangish brown, 0.1 to 0.25 1 gray, moist, soft to stiff (13-1 to B-5) RESIDUUM: 0.1 II CLAYEY SAND (SC), contains slight mica, orangish brown, moist, loose (B-6) Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 11 RESIDUUM: 3 to 12 III SILTY FINE SAND (SM), contains mica, reddish brown, light brown, tan, light gray, white, moist, loose to medium dense (All Borings) The residual soil generally consisted of sandy silt (MIL) underlain by silty fine to medium sand (SM). The SPT blow counts in the silt (MIL) ranged between 3 to 11 blows per foot and more typically between 5 and 9 blows per foot, implying that the silt is generally stiff. Two samples of silt contained 60.1% and 50.6% clay and silt size particles with liquid limits of 43 and 31, and plastic indexes of 7. The silt was generally moist and low plastic. Underlying the sandy silt (MIL), the strata was generally comprised of residual silty fine to medium sand (SM) to the maximum depths explored. The SPT blow counts in the sand (SM) ranged between 7 to 20 blows per foot and more typically between 12 and 17 blows per foot, implying that the sand is generally medium dense. The sandy was generally moist and non -plastic, wet below groundwater. Partially weathered rock, weathered rock, and crystalline bedrock were not encountered within the drilled depths or observed during site reconnaissance. Additionally, auger refusal indicative of very dense or hard strata did not occur within the drilled depths. Groundwater was encountered during drilling at B-3 and B-5 at depths of 15 feet and 14 feet, respectively, or elevation 2113' and 2116', respectively. Groundwater was not encountered in the remaining four (4) borings during drilling. Groundwater could develop within the explored depths and should be expected to fluctuate seasonally in response to precipitation, surface water absorption characteristics, and other factors. Groundwater should be anticipated in the drainage bottoms. The soil stratification shown on the test pit logs represents the interpreted soil conditions at the actual boring locations. Variations in the stratification can occur between locations. The subsurface conditions at other times and locations on the site may differ from those found at the boring locations. If different site conditions are encountered during construction, ECS should be contacted to review our recommendations relative to the new information. 5.0 PRELIMINARY RECOMMENDATIONS The primary geotechnical considerations identified on this property include (1) the potential for buried debris, vegetation, and organic laden soil from historical timber logging operations, (2) soft compressible alluvial/colluvial soils and groundwater in the drainage basins, and (3) the massive 2H:1V cut slope along Boylston Highway. There were no geotechnical challenges identified during this study that would preclude development. The risks associated with these considerations cannot be eliminated, but can be managed by proactively planning and designing the development with considering these potential considerations. Steps that can be taken to reduce and manage these risks are described in the following subsections. Risks related to buried debris can be managed by carefully observing earthwork operations, and perhaps by observing additional test excavations prior to site development. Buried debris that is Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 12 uncovered during site development and within structural areas will need to be completely removed, disposed of, and replaced with engineered fill. Highly to moderately compressible substrata were not found during the field exploration; however, compressible soils may be present in low lying drainage areas and may be subject to long term consolidation conveyed as surface settlement. Compressible soils can be further investigated through additional field exploration such as test excavations and/or soil borings, and should be considered during the design -level geotechnical evaluation. Slope stability of the massive cut slope along Boylston Highway is unknown. ECS did not evaluate the stability during this evaluation, but can do so upon request. The slope stability is considered a concern because it is unknown; the slope may indeed be stable and at this time we have no reason to characterize it as unstable based on visual observation and our general understanding of the subsurface conditions. Care should be exercised when siting buildings and other structures near the slope. Structures built within a distance of about half of the slope height from the slope's crest may be damaged if slope movement occurs. Ideally, the buildings should not be sited within the zone of potential movement unless additional geotechnical slope evaluation indicates otherwise. 5.1 Building Locations and Site Grades From a geotechnical perspective, the site grades should be designed and finished floor elevations should be established to provide at least 5 feet of clearance between the finished elevation and groundwater. Groundwater was encountered in B-3 and B-5, on the west sides of the parcel, at depths of 15 feet and 14 feet, respectively. Buried stormwater structures planned in this area should ideally be deigned above groundwater; otherwise, they will need to be designed to be watertight and to resist buoyancy effects. Buildings should also be carefully laid out such that they are not damaged by potential instability of the Boylston Highway cut slope. As previously mentioned, the slope stability is unknown. Building foundations should ideally be at a minimum distance of half the slope height from the slope crest. Soft compressible soils and shallow groundwater may be present in the basins. Buildings sited in basin areas should be elevated such that they will not be significantly impacted by groundwater. Furthermore, soft wet alluvium may be present and could compress and settle when new pressures like embankments or buildings are applied. There is some unknown probability that soft soil stabilization or settlement monitoring may be required for buildings sited over the basins. A delay period between site grading and building construction may be required to monitor settlement. Additional field exploration to help delineate areas and depths of soft soils can be considered to manage risks related to compressible alluvium, if present. Fill Slopes: Permanent fill embankments less than 20 feet tall should be inclined no steeper than 3H:1V (horizontal:vertical) for preliminary planning purposes until additional geotechnical testing and analysis can be performed during a subsequent study. Project AV—BroadpointeSite November 20, 2019 ECS Project No. 31-3861 Page 13 Cut Slopes: Permanent cut slopes in residual soils and bedrock should be inclined no steeper than 2H:1V for cuts less than 20 feet tall for preliminary planning purposes. Permanent cuts deeper than about 20 feet should be designed on a case -by -case basis by a licensed professional engineer. Slope design must account for global stability, and their construction must be monitored and tested to document that they meet design and specification requirements. ECS can design reinforced slopes or retaining walls if requested. Surface Drainage: Positive gravity drainage should be provided around the perimeter of structures. Surface water shall not be allowed to pond next to structures for extended periods of time. We recommend that the ground surface adjacent to the structures be sloped away to maintain a fall of at least 6 inches for the first 10 feet outward from the structures. Similarly, all roof drains should drain a sufficient distance from the structure perimeter and should not discharge onto cut or fill slopes unless the outfall flows are protected with energy dissipation structures; i.e., riprap. It is also important to divert surface runoff and roof drains into appropriate drainage channels and away from the top of site retaining walls or the crest of cut or fill slopes. Concentrated flows or sheet flows across slopes could cause slope erosion and instability. 5.2 Foundations Provided the site preparation recommendations in this report and/or subsequent geotechnical exploration reports are followed, we anticipate that lightly to moderately loaded structures, maybe even heavily loaded structures, can be supported by conventional spread footing foundations. Some undercutting of soft soils may be required to allow use of footing foundations. Preliminary data implies that undercuts shouldn't exceed about 4 feet. Deep foundations such as auger cast piles, driven piles, drilled shafts, or micropiles may be required for foundations near the Boylston Highway cut slope; additional geotechnical exploration and global stability analysis may indicate otherwise. Heavier -loaded footing foundations may require the use of aggregate piers to mitigate damaging settlement effects. For footings supported on firm or medium dense residual soils or properly placed and compacted new -engineered fill materials over residual soils, net allowable bearing pressures of 2,000 to 3,000 pounds per square foot (psf) should be available. To achieve adequate bearing capacity and reduce the potential for post construction settlements of the structures, loose/soft near -surface soils exposed during grading may require localized undercutting and replacement or other appropriate remedial activities, if they exist at the foundation subgrade elevation in building areas. Higher allowable bearing capacities and reduced settlement can be achieved if aggregate piers are used. Following the development of a conceptual site plan and structural plan, additional exploration of the site with SPT borings is required to develop final, project specific geotechnical recommendations, especially considering the variability of the subsurface profile of the overall site, as evidenced by the borings performed for this preliminary study. In order to provide adequate frost protection and embedment for bearing capacity, we recommend that footings be located at minimum depths of 18 inches below finished exterior grades. In order to prevent disproportionately small footing sizes, we recommend that strip Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 14 footings have a minimum width of 18 inches and that isolated column footings have a minimum lateral dimension of 24 inches. The minimum dimensions are recommended to reduce the potential for local shear or "punching" failure mechanism. Exposure to the environment, and especially inclement weather, may weaken the soils at the foundation bearing levels, especially if the foundation excavations remain open for an extended period of time. This is especially true for the fine-grained soils at the site. Therefore, foundation concrete should ideally be placed during the same day that excavations are made. If the bearing soils are softened by surface water intrusion or exposure, the softened soils must be removed from the foundation excavations prior to placement of concrete. Otherwise, a 2- to 3-inch layer of lean concrete "mudmat" may be placed in the excavation bottom, if the excavations must remain open overnight. The foundation subgrade should be evaluated for bearing by the geotechnical engineer's personnel, prior to the placement of the "mudmat." 5.3 Floor Systems Floor systems can consist of a conventional concrete slab -on -grade considering the subsurface conditions. Floor slabs should be underlain by medium dense or firm residual soils or new compacted structural fills that are stable when proofrolled. ECS recommends that the modulus of subgrade reaction to be used in the structural design of floor slabs be determined following completion of the final geotechnical exploration. The on -site lower plasticity natural soils and new engineered fill are considered suitable for support of the lowest floor slabs, although moisture control during earthwork operations, including the use of disking or appropriate drying equipment, may be necessary. A minimum separation of 2 feet should be maintained between the floor slab subgrade elevation and ELASTIC SILT (MH) or FAT CLAY (CH), if found. These soils were not found in the borings performed in this study. We assume the lowest level floor slabs will bear on new structural fill or natural soils. These materials are likely suitable for the support of a slab -on -grade. However, some undercut and replacement of loose/soft surface soils from beneath the proposed floor slabs should be anticipated in isolated areas, such as those encountered at Boring B-5. In order to allow for some relative displacement, the floor slabs should be structurally separated from both columns and load bearing walls. Monolithic slabs -on -grade with turned down footings can also be considered. We recommend a capillary cutoff layer be provided under the floor slabs to prevent the capillary rise of water through the slab. The capillary break layer should consist, at a minimum, of a 4-inch thick clean, crushed stone or washed gravel layer, having a maximum size of 1.5 inches with a maximum of 12 percent passing the No. 200 sieve. Prior to placing the stone for the capillary break layer, the floor slab subgrade soil should be properly compacted and should be free of standing water or mud. Project AV—BroadpointeSite November 20, 2019 ECS Project No. 31-3861 Page 15 Based on the results of our preliminary exploration, it appears unlikely that the floor slabs will be subjected to hydrostatic pressure from groundwater. However, water vapor transmission through the slabs is still a design consideration. Evaluating the need for and design of a vapor retarder or vapor barrier for moisture control is outside our scope of services and should be determined by the project architect/structural engineer based on the planned floor coverings and the corresponding design constraints, as outlined in ACI 302.1R-04 Guide for Concrete Floor and Slab Construction. Further, health and environmental considerations with respect to any potentially harmful vapor transmission are also outside of our scope of services for this project. 5.4 Pavement Sections Pavement subgrade is anticipated to consist of silty fine to medium sand (SM) or sandy silt (ML) residuum or engineered fill. Based on our past experience with similar facilities and subsurface conditions, we present the following estimated minimum pavement sections. We have developed these preliminary minimum pavement section estimates using AASHTO guidelines based on an estimated CBR value of 5. For heavy duty pavements, we assumed traffic conditions consisting of 50 passenger cars, 50 pick-up trucks, 40 package delivery trucks, and 20 fully loaded semi -tractor trailers, 7 days a week for 20 years. We also included allowances for construction traffic; i.e., 2 concrete trucks and 2 dump trucks 5 days per week for a span of 0.5 year. Garbage trucks were also included traffic budget on an occurrence of 5 days a week for 20 years. This traffic estimates result in a 541,325 18-kip ESAL's for heavy duty pavement. Heavy duty pavements should be designated for all entrances and exits, drive lanes, and any areas that may be exposed to frequent concentrated vehicle loading. For light duty pavements, we assumed traffic conditions consisting of 10 passenger cars, 10 pick- up trucks, 5 package delivery trucks, and 1 fully loaded semi -tractor trailers, 7 days a week for 20 years. We DID NOT include allowances for construction or garbage truck traffic. This traffic estimates result in a 32,541 18-kip ESAL's for light duty pavement, and a service period of 20 years. Light duty pavements should be designated for truck and car parking areas only. Should the actual traffic conditions be different than those stated, ECS should be allowed to carefully review these estimates and make appropriate revisions based upon the new traffic design criteria and/or determination of the engineering properties of the actual pavement subgrade soils. A final pavement design should be included in the design -level geotechnical investigation. Table 5.4.1 Preliminary Pavement Sections Estimates Material Designation Composite Option Light Duty Heavy Duty Asphalt Asphalt Pavement Pavement Asphalt Course (NCDOT S9.5B or 119.0B) 2.5 inches 4.0 inches Aggregate Base Course 8.0 inches 10.0 inches Concrete Option Portland Cement Concrete 5.0 inches 7.5 inches Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 16 5.5 Seismic Site Classification The 2018 North Carolina Building Code (NCBC) requires that a seismic Site Class be assigned for new structures. The method for determining the Site Class is presented in Section 1613.5.2 of the NCBC. The seismic Site Class is typically determined by calculating a weighted average of the N-values or shear wave velocities recorded in test borings or in cone penetration test soundings to a depth of 100 feet. Based upon preliminary boring data, we judge that the seismic site classification may range between "C" and "D" with a higher probability of use of "D" for structural design. 6.0 PRELIMINARY CONSTRUCTION CONSIDERATIONS 6.1 Subgrade Preparation Clearing and Grubbing: The first step in preparing the site for the proposed construction should be to remove the existing fill, vegetation and topsoil, and other soft, unsuitable, or deleterious material within the planned excavation limits. Generally, organic laden soil depths within wooded land typically range from 6 to 18 inches. The surficial organic laden soil is typically a dark -colored soil material containing roots, fibrous matter, and/or other organic components, and is generally unsuitable for support of engineering fill, foundations, or slabs -on -grade. We caution against removing surficial ground cover and topsoil outside of the immediate construction area due to potential erosion. Ground cover outside the limits of construction should generally remain undisturbed to the extent possible to minimize the risk for shallow surficial sloughing and erosion at other areas of the site. Undercutting: Any loose/soft surface soils that exist at the finished subgrade elevation in building and pavement areas may require localized undercutting and replacement or other appropriate remedial activities. The data collected during this and previous investigation do not imply significant undercutting during construction; however, we suspect that soft wet alluvium may be present in drainages and creek bottoms which may require undercutting. Soft subgrade should be evaluated on a case -by -case basis by an ECS engineer prior to the contractor commencing stabilization efforts. Proofrolling: The exposed subgrade soils should be proofrolled using a loaded dump truck, prior to placing any new fill to raise the grade. The subgrade soils in cut areas should also be proofrolled. The loaded dump truck should have an axle weight of at least 15 tons. Proofrolling should be observed by an experienced geotechnical engineer, or his personnel, at the time of construction to aid in identifying areas with soft or unsuitable materials. Soft or unsuitable materials encountered during proofrolling should be removed and replaced with an approved backfill compacted to the criteria herein Subgrade Observations: The preparation of subgrades in areas to receive fill should be observed periodically by ECS personnel. These observations should be performed by an experienced geotechnical engineer or their representative to document that the unsuitable materials, if encountered, have been removed and that any prepared subgrade is suitable for support of the proposed construction and/or fills. Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 17 6.2 Excavation Equipment: The near -surface subgrade soils, residuum, can be excavated with backhoes, front- end loaders, or other similar equipment using conventional means and methods. Weathered rock hard/dense enough to cause auger refusal was not encountered. OSHA Requirements: Excavation safety is the sole responsibility of the contractor. Slopes should be inclined to maintain the minimum excavation safety requirements per the most current version of OSHA 1926 Subpart P. OSHA requires that excavations deeper than 20 feet be designed by a licensed professional engineer. In no case should slope height, slope inclination, or excavation depth, including utility trench excavation depth, exceed those specified in local, state, and federal safety regulations. ECS is providing this information solely as a service to our client. ECS is not assuming responsibility for construction site safety or the Contractor's activities; such responsibility is not being implied and should not be inferred. Excavatability: The excavation of soil, partially weathered rock, and rock can have a substantial impact on the cost and schedule of the proposed construction. This discussion considers three general classes of materials for purposes of describing excavatability. Residuum, partially weathered rock, and rock will be used as the terms for the materials to be excavated. In mass excavations for general site work, overburden soils with SPT-N values of 30 bpf or less can usually be removed with conventional earth excavation equipment such as pans, bulldozers, front-end loaders, and track -mounted backhoes. Residual soils with N values of 30 to 60 bpf can generally be removed with conventional earth moving equipment after first being loosened with a large single tooth ripper attached to a large crawler tractor. Excavation of very dense and hard soils and more weathered zones of intermediate geomaterials (PWR) will generally require the use of a large dozer equipped with a single tooth ripper and/or large track mounted excavators. Typically, PWR that can be penetrated by soil augers (such as those used in this subsurface exploration) can usually be excavated after being loosened with a large single tooth ripper. Very dense soils or PWR were not encountered in the borings within the drilled depths. Materials exhibiting N values of 50 blows for 3 inch or less of penetration will be more difficult to excavate and generally require blasting and other rock excavation techniques. The actual excavatability of the bedrock material will be greatly controlled by in -situ jointing and bedding and may vary from location to location. Hard rock was not encountered in the borings within the drilled depths. In confined excavations, such as utility trenches, excavation of dense residual soils typically requires the use of large track mounted backhoes. Excavation of partially weathered rock typically requires the use of pneumatic hammers, hydraulic hammers, or light blasting. Refusal materials (apparent rock) normally require blasting in trench excavations. Blasting in utility trenches must be done carefully to prevent damage to the surrounding materials. Additional site -specific exploration with soil test borings and will be required to develop project specific excavation recommendations. Seismic refraction studies should be considered to further evaluate the excavation characteristics and the depth to rock between the boring depths. Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 18 6.3 Dewatering Based on the results of the borings, we do not anticipate that groundwater will significantly influence general site construction. However, given the presence of surface water features on this site and the surface water and shallow groundwater associated with these features, some groundwater control measures should be anticipated for any utility, retaining wall, culvert, or other such construction within low lying, floodplain areas. If groundwater or perched water is encountered during construction it probably can be controlled through the use of ditches, sumps, and pumps. If water is encountered that cannot be controlled by such procedures, ECS should be further consulted. Excavation through saturated materials usually requires sheeting and shoring, slope flattening, or benching to control sloughing and sidewall instability. If water collects in foundation excavations, it will be necessary to remove the water from the excavation, remove the saturated soils, and re -test the adequacy of the bearing surface to support the design bearing pressure prior to concrete placement. Establishing a system of drainage ditches to carry surface and shallow groundwater away from building sites and roadways may also reduce grading costs. Construction Dewatering Outside of Floodplain Areas: Based on the borings, our experience with groundwater fluctuations on similar sites, and anticipated design grades, most of the temporary excavations are unlikely to encounter groundwater. However, the contractor should be prepared to remove any precipitation or groundwater that may seep into temporary construction excavations using open pumping. Open pumping utilizes submersible sump pumps in pits or trenches dug below the bottom of the excavation and backfilled with No. 57 stone. Construction Dewatering in Floodplain Areas: Temporary excavations within floodplain areas are likely to encounter surface water and/or groundwater. Potential groundwater control methods for the temporary construction excavations for this project include open pumping, as described above. Pumping can be performed on an intermittent basis to remove water from the construction excavations, but should be continuous (24 hours a day) to maintain excavation bottom stability. 6.4 Engineered Fill Materials Submittals: Prior to the commencement of fill operations and/or utilization of off -site borrow materials, the contractor should provide representative samples of the soil materials to the geotechnical engineer. The geotechnical engineer will evaluate the material's suitability for use as an engineered fill and develop moisture -density relationships in accordance with the recommendations provided herein. Samples should be provided to the geotechnical engineer at least 5 days prior to their use in the field to allow for the appropriate laboratory testing to be performed. Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 19 Satisfactory Fill Materials: New fill should consist of an approved import or on -site material, free of organic matter and debris. Import fill materials should have a plasticity index less than 30 and a liquid limit less than 50. We also recommend that fill soil have a standard Proctor (ASTM D 698) maximum dry density of at least 100 pounds per cubic foot (pcf). The majority of the on -site soils consist of residual silty sand (SM) and sandy silt (MIL). The laboratory index testing indicates these soils meet the specifications for engineered fill outlined above, and theses soils appear generally suitable for reuse as new fill during construction. The on -site soils were noted to contain varying amounts of rock fragments, generally increasing with depth. Soils containing excessive amounts of rock fragments, cobbles, and boulders larger than 3 to 4 inches in diameter are not suitable for reuse unless the over -sized rock portions are screened out or are crushed and/or pulverized to a smaller nominal size. Unsatisfactory Fill Materials Unsatisfactory fill materials include materials which do not satisfy the requirements for suitable materials, as well as topsoil and organic materials (OH, OL), elastic Silt (MH) (with a PI greater than about 30), high plasticity Clay (CH), and nests of boulders and shotrock. Organic and highly plastic soils were not encountered in the test borings. Wet/Frost Heaved Soils: Fill should not be placed on or contain frozen soils or frost -heaved soils and/or soils which have been recently subjected to precipitation. Fill materials should not contain wet or frozen materials at the time of placement. Wet or frost -heaved soils should be removed prior to placement of engineered fill, granular sub -base materials, foundation or slab concrete, and asphalt pavement materials. 6.5 Compaction Fill Compaction: New engineered fill should be placed in relatively horizontal lifts not exceeding 8 inches in loose lift thickness. Fill placed on sloping subgrades should be properly benched into the natural grades as described previously. Each lift of new engineered fill should be compacted to a minimum of 95% of standard Proctor maximum dry density in accordance with ASTM D 698. The upper 24 inches of new fill below foundations, grade -supported slabs, or pavement areas should be compacted to a minimum of 98% of the standard Proctor maximum dry density. During placement, new fill must be maintained within working range of its optimum moisture content, or otherwise moisture conditioned (wetting or drying) to within working range of optimum. Our experience suggests that the typical working range of optimum for similar soils is typically within approximately 3 percent of the optimum moisture content depending on the fines content and plasticity, with finer -grained and more plastic soils being more moisture sensitive. Utility Trench Backfill: Similarly, isolated areas of engineered fill, such as trench backfill, should be placed in loose lifts not exceeding 6 inches and compacted as described above. Fill Compaction Testing: New fill within structural areas, including the building footprint, pavement areas, and fill slopes taller than 4 feet in vertical height, should be evaluated by a representative of a professional geotechnical engineer to document that the required degrees of compaction are achieved. We recommend that a minimum of one compaction test be performed for each lift of controlled fill placed in the areas outlined above. Areas which fail to achieve the required degree of compaction should be re -compacted and re -tested until the required Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 20 compaction is achieved. Failing test areas may require moisture adjustments or other suitable remedial activities in order to achieve the required compaction. 6.6 Slope Construction and Erosion Protection Slopes shall not be constructed using organic strippings, topsoil or other deleterious materials, and should be over -built slightly steeper and cut back to the required inclination in order to expose properly compacted soil at the slope face and to help enhance their long-term stability. Slopes should be properly vegetated to prevent erosion and shallow surficial sloughing which could lead to other shallow instabilities. Semi -Permanent Erosion Control: Permanent turf reinforcement matting (TRM) or flexible growth medium (FGM) should be applied to all slopes, cut or fill, exceeding a 2H:1V inclination in order to reduce erosion and shallow surficial sloughing. We recommend EnkaMat J, Tensar Vmax SC250 TRM, Tensar HydraCX hydraulic mulch FGM, or approved equivalent be used for permanent surficial stabilization on steep slopes. Slopes with inclinations of 2H:1V or flatter should receive temporary matting, such as Tensar EroNet S75 or approved equivalent. Slope matting should be applied per the manufacturer's specifications, including proper anchor trenches, staple patterns, and overlaps. Temporary Erosion Control: Most of the site soils are considered erodible. Therefore, the Contractor should provide and maintain good site drainage during earthwork operations to maintain the integrity of the surface soils. All erosion and sedimentation controls should be in accordance with sound engineering practices and local requirements. 6.7 Additional Considerations It is ECS's experience that grading operations will usually be more economical if performed during the drier periods of the year (typically late April to late September). This is due to the difficulty associated with moisture conditioning of wet soils during the wetter periods of the year (November to April). Although wet soils can sometimes be dried by using disking or other drying measures, it is important to note that attempts at disking or other "air" drying procedures are sometimes impractical due to frequent and extended periods of wet, cool, and cloudy weather characteristic of the wetter periods of the year. Consequently, during the wetter periods of the year, moisture conditioning procedures, such as lime stabilization, are sometimes required to achieve moisture contents necessary to facilitate adequate compaction. It is imperative to maintain good site drainage during earthwork operations to help maintain the integrity of the site soils. Ponding of water will results in softening of the near -surface soils. The surface of the site excavation should be kept properly graded to enhance drainage of surface water away from the construction areas. We recommend that surface drainage be diverted away from the building and pavement areas without significantly interrupting its flow. Other practices would involve sealing the exposed soils daily with a smooth -drum roller at the end of the day's work to reduce the potential for infiltration of surface water into the exposed soils. During the mass grading operations, building and pavement subgrades may be left higher and then cut to the required grade immediately prior to the construction of those areas. Once the final subgrade elevation is established and found stable during a final proofroll, the required thickness of crushed stone should be placed to help protect the final subgrades. Project AV—BroadpointeSite November20, 2019 ECS Project No. 31-3861 Page 21 7.0 CLOSING ECS has completed the above referenced service in general conformance with the authorized proposal. We caution that we never have full knowledge of the subsurface conditions. Our opinions and recommendations are based on conditions encountered at the test locations described. Variations in the reported conditions are probable. This site evaluation was based upon visual reconnaissance, observations of existing conditions, a limited field exploration, evaluation of the general suitability of the site for the proposed development, a review of readily available information, and our experience with similar sites and conditions. The general subsurface conditions utilized in our evaluation were based on interpolation of subsurface data between the test locations. If the project information is incorrect or if the structure location (horizontal or vertical) and/or dimensions are changed, please contact us so that our recommendations can be reviewed. The discovery of site or subsurface conditions during construction which deviate from the data outlined in this exploration should be reported to us for our evaluation. The description of the proposed project is based on information provided to ECS. If any of this information is inaccurate, either due to our interpretation of the documents provided or site or design changes that may occur later, ECS should be contacted immediately in order that we can review the report in light of the changes and provide additional or alternate recommendations as may be required to reflect the proposed construction. We recommend that ECS be allowed to review the project's plans and specifications pertaining to our work so that we may ascertain consistency of those plans/specifications with the intent of the geotechnical report. Field observations, monitoring, and quality assurance testing during earthwork and foundation installation are an extension of and integral to the geotechnical design recommendation. We recommend that the owner retain these quality assurance services and that ECS be allowed to continue our involvement throughout these critical phases of construction to provide general consultation as issues arise. ECS is not responsible for the conclusions, opinions, or recommendations of others based on the data in this report. Site Location Diagram Boring Location Diagrams EqS ol 111 v (T tv cz cz CC •R, i Cl) � T 0 .O � co 0 11- O m V (n 0 0 > a- Z,aL_w Mrf 1 k O i O a I n I � S O (p gip' (D O m 0 N F nF .. 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LU m z a� @ p ma 2 j (m CLIENT Job #: BORING # SHEET — Samet Corporation 31:3861 1 B-1 1 OF 1 PROJECT NAME ARCHITECT -ENGINEER Pro'ect AV - Broad ointe Site SITE LOCATION CALIBRATED PENETROMETER TONS/FT' 350 Fannina Fields Road Mills River Henderson County, NC ROCK QUALITY DESIGNATION & RECOVERY NORTHING EASTING STATION ROD% - — - REC% PLASTIC WATER LIQUID z DESCRIPTION OF MATERIAL ENGLISH UNITS " z U LL LIMIT% CONTENT% LIMIT% w IL BOTTOM OF CASING LOSS OF CIRCULATION !D w u n LL o J O o SURFACE ELEVATION 2093 = IL J IL J IL J IL LU > OU CC ¢ > - � ® STANDARD PENETRATION o U) U) � ¢ w m BLOWS/FT D To soil Thickness 3" (ML) Residuum, SANDY SILT, contains slight 1 S-1 SS 18 10 mica, light brown, moist, stiff 4 9 5 2090 (SM) Residuum, SILTY FINE TO MEDIUM S 2 SS 18 7 SAND, contains slight mica, light brown and tan, 5 14 moist, medium dense 8 5 5 S-3 SS 18 10 7 :16 9 2085 4 S-4 SS 18 9 7 15 10 $ 2080 7 S-5 SS 18 18 9 20 15 11 END OF BORING @ 15' 2075 20 2070 25 2065 30 THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES BETWEEN SOIL TYPES. IN -SITU THE TRANSITION MAY BE GRADUAL. WL DRY WS❑ WDO BORING STARTED 07/16/19 CAVE IN DEPTH 13 WL(SHW) t WL(ACR) BORING COMPLETED 07/16/19 HAMMER TYPE Auto WL Jesse RIG CME550X FOREMAN DRILLING METHOD ASTM D1586 - Chambless CLIENT Job#: BORING# SHEET Samet Corporation 31:3861 B-2 1 OF 1 EE PROJECT NAME ARCHITECT -ENGINEER Promect AV - Broad ointe Site SITE LOCATION CALIBRATED PENETROMETER TONS/FT2 350 Fanninq Fields Road Mills River Henderson County,NC ROCK QUALITY DESIGNATION & RECOVERY NORTHING EASTING STATION RQD% - — - REC% PLASTIC WATER LIQUID z DESCRIPTION OF MATERIAL ENGLISH UNITS — z c2 F LIMIT% CONTENT% LIMIT% �i n O a o _- BOTTOM OF CASING LOSS OF CIRCULATION �� w J Z Z w O _ SURFACE ELEVATION 2139 a W 0- W 0- W 0- 00 ~ w w O ® STANDARD PENETRATION o co co co O w IQBLOWS/FT To soil Thickness 2" 2 (ML) Residuum, SANDY SILT, light brown and S-1 SS 18 18 orangish brown, moist, stiff a 11 2135 � a 9 S-2 SS 18 18 5 5 3 S-3 SS 18 18 (SM) Residuum, SILTY FINE TO MEDIUM 6 12. SAND, contains slight mica, reddish brown to 6 light brown, moist, medium dense to loose S-4 SS 18 18 2130 5 13 10 $ 2125 z a 11 S-5 SS 18 18 15 2120 3 a 8 S-6 SS 18 18 20 a END OF BORING @ 20' 2115 25 2110 30 THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES BETWEEN SOIL TYPES. IN -SITU THE TRANSITION MAY BE GRADUAL. ❑ WL DRY wS ❑ WD E BORING STARTED 07/16/19 CAVE IN DEPTH 17 WL(SHW) WL(ACR) BORING COMPLETED 07/16/19 HAMMER TYPE Auto WL Jesse RIG CME550X FOREMAN DRILLING METHOD ASTM D1586 - Chambless CLIENT Job #: BORING # SHEET - Samet Cor oration 31:3861 1 B-3 1 OF 1 PROJECT NAME ARCHITECT -ENGINEER Pro'ect AV - Broad ointe Site SITE LOCATION CALIBRATED PENETROMETER TONS/FT' 350 Fannina Fields Road Mills River Henderson County, NC ROCK QUALITY DESIGNATION & RECOVERY NORTHING EASTING STATION ROD% - — - REC% PLASTIC WATER LIQUID z DESCRIPTION OF MATERIAL ENGLISH UNITS " z U LL LIMIT% CONTENT% LIMIT% w IL BOTTOM OF CASING LOSS OF CIRCULATION ! a w u n LL o J O o SURFACE ELEVATION 2128 = IL J IL J IL J IL LU > OU CC ¢ > - � ® STANDARD PENETRATION o U) U) � ¢ w m BLOWS/FT D To soil Thickness 1" (ML) Residuum, SANDY SILT, light brown, 2 S 1 SS 18 16 moist, firm 2 5 26.5-0 E36-X- !�43 E 3 2125 2 S-2 SS 18 18 2 6 5 4 1 S-3 SS 18 18 2 7 5 2120 (ML) Residuum, SANDY SILT, contains slight S-4 SS 18 18 mica, pinkish brown and light brown, moist, stiff a 11 10 (SM) Residuum, SILTY FINE TO MEDIUM SAND, contains mica, light brown and light 2115 gray, moist, loose to medium dense 1 S-5 SS 18 18 2 7 15 — 5 2110 2 S-6 SS 18 18 6 14 20 $ 2105 5 S-7 SS 18 18 4 13 25 ITITITI9 END OF BORING @ 25' 2100 30 THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES BETWEEN SOIL TYPES. IN -SITU THE TRANSITION MAY BE GRADUAL. WL 15 WS❑ WDO BORING STARTED 07/16/19 CAVE IN DEPTH 22 WL(SHW) t WL(ACR) BORING COMPLETED 07/16/19 HAMMER TYPE Auto WL Jesse RIG CME550X FOREMAN DRILLING METHOD ASTM D1586 - Chambless CLIENT Job #: BORING # SHEET - Samet Corporation 31:3861 1 B-4 1 OF 1 PROJECT NAME ARCHITECT -ENGINEER Pro'ect AV - Broad ointe Site SITE LOCATION CALIBRATED PENETROMETER TONS/FT' 350 Fannina Fields Road Mills River Henderson County, NC ROCK QUALITY DESIGNATION & RECOVERY NORTHING EASTING STATION ROD% - — - REC% PLASTIC WATER LIQUID z DESCRIPTION OF MATERIAL ENGLISH UNITS " z U LL LIMIT% CONTENT% LIMIT% w IL BOTTOM OF CASING LOSS OF CIRCULATION ! a w u n LL o J O o SURFACE ELEVATION 2148 = IL J IL J IL J IL LU > OU CC ¢ > - � ® STANDARD PENETRATION o U) U) � ¢ w m BLOWS/FT D To soil Thickness 1" (ML) Residuum, SANDY SILT, contains slight 2 S-1 SS 18 12 mica, light brown, moist, firm 3 6 3 2145 1 S-2 SS 18 10 3 6 5 3 (SM) Residuum, SILTY FINE TO MEDIUM S-3 SS 18 14 SAND, contains slight mica, light brown and 2 3 7 white, moist, loose to medium dense 4 2140 3 S-4 SS 18 12 5 13 10 $ 2135 4 S-5 SS 18 10 5 12; 15 (SM) Residuum, SILTY FINE TO MEDIUM SAND, contains slight mica, light brown, moist, 2130 loose 3 S-6 SS 18 14 5 10 20 5 END OF BORING @ 20' 2125 25 2120 30 THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES BETWEEN SOIL TYPES. IN -SITU THE TRANSITION MAY BE GRADUAL. WL DRY WS❑ WDO BORING STARTED 07/16/19 CAVE IN DEPTH 17 WL(SHW) t WL(ACR) BORING COMPLETED 07/16/19 HAMMER TYPE Auto WL Jesse RIG CME550X FOREMAN DRILLING METHOD ASTM D1586 - Chambless CLIENT Job #: BORING # SHEET — Samet Corporation 31:3861 1 B-5 1 OF 1 PROJECT NAME ARCHITECT -ENGINEER Pro'ect AV - Broad ointe Site SITE LOCATION CALIBRATED PENETROMETER TONS/FT' 350 Fannina Fields Road Mills River Henderson County, NC ROCK QUALITY DESIGNATION & RECOVERY NORTHING EASTING STATION ROD% — — — REC% PLASTIC WATER LIQUID z DESCRIPTION OF MATERIAL ENGLISH UNITS " z U LL LIMIT% CONTENT% LIMIT% w IL BOTTOM OF CASING LOSS OF CIRCULATION !D w u n LL o J O o SURFACE ELEVATION 2130 = IL J IL J IL J IL LU > OU CC ¢ > - � ® STANDARD PENETRATION o U) U) � ¢ � w m BLOWS/FT D To soil Thickness 11 "1 2130 (ML) Residuum, SANDY SILT, contains slight 2 S-1 SS 18 3 mica, gray and light brown, moist, soft to stiff 1 3 2 1 1 3 �4—�j --;�,-31 S-2 SS 18 18 5 2125 2 i 25.8 i 1 S-3 SS 18 18 1 5 4 1 S-4 SS 18 18 4 10 10 2120 6 (SM) Residuum, SILTY FINE TO MEDIUM SAND, contains mica, light brown, moist, medium dense to loose 2 S 5 SS 18 18 — 4 11 15 2115 2 S-6 SS 18 18 3 9 20 2110 6 END OF BORING @ 20' 25 2105 30 2100 i THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES BETWEEN SOIL TYPES. IN -SITU THE TRANSITION MAY BE GRADUAL. WL 14 WS❑ WDO BORING STARTED 07/16/19 CAVE IN DEPTH 16 WL(SHW) t WL(ACR) BORING COMPLETED 07/16/19 HAMMER TYPE Auto WL Jesse RIG CME550X FOREMAN DRILLING METHOD ASTM D1586 - Chambless CLIENT Job #: BORING # SHEET — Samet Corporation 31:3861 1 B-6 1 OF 1 PROJECT NAME ARCHITECT -ENGINEER Pro'ect AV - Broad ointe Site SITE LOCATION CALIBRATED PENETROMETER TONS/FT' 350 Fannina Fields Road Mills River Henderson County, NC ROCK QUALITY DESIGNATION & RECOVERY NORTHING EASTING STATION ROD% - — - REC% PLASTIC WATER LIQUID z DESCRIPTION OF MATERIAL ENGLISH UNITS " z U LL LIMIT% CONTENT% LIMIT% w IL BOTTOM OF CASING LOSS OF CIRCULATION !D w u n LL o J O o SURFACE ELEVATION 2171 = IL J IL J IL J IL LU i OU CC ¢ H > - ® STANDARD PENETRATION o U) U) � ¢ w m BLOWS/FT D To soil Thickness 1" (SC) Residuum, CLAYEY FINE SAND, contains I 2170 2 S-1 SS 18 10 slight mica, orangish brown, moist, loose 2 5 3 3 S-2 SS 18 8 4 8 5 4 2165 (SM) Residuum, SILTY FINE TO MEDIUM S-3 SS 18 10 SAND, contains slight mica, light brown and tan, 4 9 moist, loose to medium dense 5 3 S-4 SS 18 10 5 11 10 6 2160 3 S 5 SS 18 18 5 17 15 12 2155 4 S-6 SS 18 18 7 17 20 10 END OF BORING @ 20' 2150 25 2145 30 THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES BETWEEN SOIL TYPES. IN -SITU THE TRANSITION MAY BE GRADUAL. WL DRY WS❑ WDO BORING STARTED 07/16/19 CAVE IN DEPTH 16 WL(SHW) t WL(ACR) BORING COMPLETED 07/16/19 HAMMER TYPE Auto WL Jesse RIG CME550X FOREMAN DRILLING METHOD ASTM D1586 - Chambless EN REFERENCE NOTES FOR BORING LOGS MATERIAL1,2 ASPHALT CONCRETE a zy GRAVEL y TOPSOIL VOID BRICK r AGGREGATE BASE COURSE " 77 FILLS MAN -PLACED SOILS .:Lj. 0-,V_ GW WELL -GRADED GRAVEL gravel -sand mixtures, little or no fines GP POORLY -GRADED GRAVEL gravel -sand mixtures, little or no fines i GM SILTY GRAVEL gravel -sand -silt mixtures a GC CLAYEY GRAVEL gravel -sand -clay mixtures ...... ; SW WELL -GRADED SAND gravelly sand, little or no fines SP POORLY -GRADED SAND ® gravelly sand, little or no fines SM SILTY SAND sand-silt mixtures " SC CLAYEY SAND sand -clay mixtures ML SILT RN non -plastic to medium plasticity MH ELASTIC SILT A 11 high plasticity f CL LEAN CLAY low to medium plasticity CH FAT CLAY high plasticity OL ORGANIC SILT or CLAY non-plastic to low plasticity OH ORGANIC SILT or CLAY high plasticity PT PEAT highly organic soils DRILLING SAMPLING SYMBOLS & ABBREVIATIONS SS Split Spoon Sampler PM Pressuremeter Test ST Shelby Tube Sampler RD Rock Bit Drilling WS Wash Sample RC Rock Core, NX, BX, AX BS Bulk Sample of Cuttings REC Rock Sample Recovery % PA Power Auger (no sample) RQD Rock Quality Designation % HSA Hollow Stem Auger PARTICLE SIZE IDENTIFICATION DESIGNATION PARTICLE SIZES Boulders 12 inches (300 mm) or larger Cobbles 3 inches to 12 inches (75 mm to 300 mm) Gravel: Coarse 3/4 inch to 3 inches (19 mm to 75 mm) Fine 4.75 mm to 19 mm (No. 4 sieve to 3/4 inch) Sand: Coarse 2.00 mm to 4.75 mm (No. 10 to No. 4 sieve) Medium 0.425 mm to 2.00 mm (No. 40 to No. 10 sieve) Fine 0.074 mm to 0.425 mm (No. 200 to No. 40 sieve) Silt & Clay ("Fines") <0.074 mm (smaller than a No. 200 sieve) COHESIVE SILTS & CLAYS UNCONFINED COMPRESSIVE SPT5 CONSISTENCY STRENGTH, Qp4 (BPF) (COHESIVE) <0.25 <3 Very Soft 0.25 - <0.50 3-4 Soft 0.50 - <1.00 5-8 Medium Stiff 1.00 - <2.00 9 - 15 Stiff 2.00 - <4.00 16 - 30 Very Stiff 4.00 - 8.00 31 - 50 Hard >8.00 >50 Very Hard GRAVELS, SANDS & NON -COHESIVE SILTS SPT5 DENSITY <5 Very Loose 5-10 Loose 11 - 30 Medium Dense 31 - 50 Dense >50 Very Dense RELATIVE AMOUNT COARSE GRAINED (%)$ FINE GRAINED (%)$ Trace <5 <5 Dual Symbol 10 10 (ex: SW-SM) With 15-20 15-25 Adjective >25 >30 (ex: "Silty') WATER LEVELS WL Water Level (WS)(WD) (WS) While Sampling (WD) While Drilling V SHW Seasonal High WT ♦ ACR After Casing Removal V SWT Stabilized Water Table DCI Dry Cave -In WCI Wet Cave -In Classifications and symbols per ASTM D 2488-09 (Visual -Manual Procedure) unless noted otherwise. 2To be consistent with general practice, "POORLY GRADED" has been removed from GP, GP -GM, GP -GC, SP, SP-SM, SP-SC soil types on the boring logs. 3Non-ASTM designations are included in soil descriptions and symbols along with ASTM symbol [Ex: (SM-FILL)]. 4Typically estimated via pocket penetrometer or Torvane shear test and expressed in tons per square foot (tsf). 5Standard Penetration Test (SPT) refers to the number of hammer blows (blow count) of a 140 lb. hammer falling 30 inches on a 2 inch OD split spoon sampler required to drive the sampler 12 inches (ASTM D 1586). 'N-value"is another term for `blow count" and is expressed in blows per foot (bpf). 6The water levels are those levels actually measured in the borehole at the times indicated by the symbol. The measurements are relatively reliable when augering, without adding fluids, in granular soils. In clay and cohesive silts, the determination of water levels may require several days for the water level to stabilize. In such cases, additional methods of measurement are generally employed. Minor deviation from ASTM D 2488-09 Note 16. BPercentages are estimated to the nearest 5% per ASTM D 2488-09. Reference Notes for Boring Logs (FINAL 10-13-2016) 02016 ECS Corporate Services, LLC. All Rights Reserved Laboratory Testing Summary C 2 3 �2 j � 2 < \± £ L�co- --Qa � E f �Bmco§ > \ 0 CO # 4T co 1 CA m ±' ; a E ■ — �� / w§�) k E o ± �. - � 02 � f LCIM, 3 E , . �� \ 7; �2 fID / S � > to\ e - Om 6' d k g a a 2 0 \ � / n a � � f \ - { 5 2 g C04 \ / - 0 ® Li O U) \ Lf? q \ J \\ fir^ LO E cn )Fn Cl)} / \ \ � � = 2 Lq o LU 2 C*4 LO / \ a) a) % § a / = K co 2 L6 % a R ® / ƒ § E ■ ■ C-1) / 0 E © 2 2 a \ \ \ \ « _ cm R k f 7 k k \ 0 in • IL k co \ § 0 k 0m d co Cl)§ / 6 2 z k a a Geolechnical Engineeping Report — , Geotechnical Services Are Performed for Specific Purposes, Persons, and Projects GeolechniCal engineers structure their services to meet the specific needs of their clients. A geatechnical engineering study conducted for acivil engi- neer may not fulfill tha needs of a construction contraotor or even anottrer civil engineer. Because each gectechnicaf engineering study is unique, each geolechnical engineering report is unique, prepared solely foTthe client. No one exempt you should rely on your gemechnical engineering report wilhoul first conferring with the geotechnW engineer who prepared il. Audno aw —aol er+ nyov —should apply the report fuf any purpose or project except the one originally contemplated. RBad the Full Report Serious problems have occurred because those relying on a geolechnical engineering report did not read it all, av nut rely on an executive summary. Do not read selected alemantsanly. A Geotechnical Engineering Report Is Based on A Unique Set of Project -Specific Factors Seatecftnical engineers consider a number of unique, project -specific te- tflrs when establishing the scope of a study. Typical factors ir.r%de: the clienCs goats, objectives, and Fisk management preferences, the garlerral nature of the structure involved, its size, and Configuration; the location of :he structure on the site; and other planned ar existing site improvements, such as access roads, parking lots. and underground uliRiss. Unless the gactechtlical engineer who Conducted tfre study specifically indimtes oth- .rwise, do not rely an a geotechnical engineering report that was: * not prepared for you, not prepared for your project. • nol prepared for the specific site explored, or completed before important proieet changes were made. Typical changes that can erode the reliability of an existing geotschniral engineering Teport include those that affect • the function of the proposed struclure, as when it's changed from a parking garage to an office building, or from a light industrial plant to a refrigerated warehouse. • elevation, configuration, location, orientation, or weight of she praposei structure, • cornpasiliun of the design team, or • project ownership. As a general rule, a*Vs infarrn you r g eatech n i cal engineer of project changes --even minor ones ---and request an assessment of their impact. ta�o hrtrical tgrheers oarTn�t ecr res{uensrb+lrly pr trabih+ for problm that occur because [heir Worts do nV (raQrrsider develOprrafts of which they were ad lrrfomw. Stdtsurface Conditions Can Change A geoitectlniral engineering repan is based on conditions that existed at the ti me the study was performed_ Oo V rely on a grrotechrricar ongincer ft Moodwhose adequacy may have tmn affected by: the passage of lime; by man-rnade events, such as construction on or adjacent to the site, or by naluraI events, such as floods, carmcluakes, or groundwater fluctua- fians. Always contact the geatechnical angi1eer halom applying the report In determine if it is still reliable_ A minor amount of additional tesilng or analysis coud prevenl major problems, Most Gelfiefticd Findings Are Professional Opinions Site explorat an identifies subsurface conditions only al those points where subsurface tests are conducted or samples are taken. Geotechnical engi- neers review field and laboratory data and then apply their professional judgment to render an opinion about subsurface condilions. throughout the srle Actual subsAace conditions may differ----someNnnes signif icantiy— ftorn those indicaled in your report. Detaining the geotechnical engineer who developed your report to provide construction observation is the mosi effective method of managing the '63 associated with unanticipated conditions, A Report's Recommendations Are i Fing bo not ovwrely an the construclion recommendations included in your report_ Those womwcratkr?sare oat,fall, because geofechnical engi- neers develop them principally from judgment and opinion. Gec fechnical engineers ran finalize their recommendations only by observing actual subsurface conditions revealel during construction. Thegeolechnkal engrrreer rvho de velopear your r�rl carrrrot ass�frtie resporlsibilr`ty or liability tar fhe report's racarrrrrenod lions if that engx]eer does not perform conslrrictlor? cbserual+gn A Geetechnical Engineering Replan 19 SIAW to Misinterpretabon Other design ream members' misinterpretation of geotechnical engineering reports has resulted in costly pablerm, Lower thal risk by ha ing your gw- tachniral engineer confer with agpropriale rnembm of lhre design Nrn alter submitting 1he report Also retain your geotactlnical engineef to review perb- aent elements of tale design team 3 plans and specifications, Contractors can also mIsinlefpret a geowhniml engimering report. Reduce that risk by #raving your gectechni;al engineer paWcipale in prebid and preconsiruction corleiences, and by providing Min strucl1on observal1on. go Not Redraw the F.ngi's Lis GeotechnicaI engineers prepa'e final boring and testing logs based upon their intarpietal1on of field lags and laboratory data. To prevent errors or omissions, the logs included in a geotechnical engineering report should never he redrawn far inclusion in arch ileuA or other design drawings Only photographic or electronic reproduction is aoWlahle, bill recogrtlZa drat separating fogs f0m the pore ma i? Mte (J' k., Mve Centractors a Complete Report and G$ Some pwmrs and design professionals mistakenly believe they ran make contractors liable for unanticipated subsurface conditions by limiting whale they provide for bid preparation. To help prevent costly problems, give con- tractors the complete geolechniA argineed ng report, brrrpriMce it wilh a clearly written letter cf tradsnnittal. In that letter, advise contractors that the report was nut prepared for purposes of bid develupment arid that the report's accuracy is limited; encourage them to cmfer with the geotechnical engineer who prepared the report (a modest lee may be required) andlar to conducl addill anal study to olu in the specific types of infarmaEion their need or prefer. A prebid conference an also be valuable_ Be sz+re confrac- tafs have sfffbiif tirrr?to perform additional study. Only then might you be in a positiarr to give contractors the best infomtation available to you. while requiring them to at least share some of the linancial responsibilities stemming from unanticipated omnditions. MW Responsibility Ppeftions Closely Some clients, design professia na I s, and codraclors do not recognize that geotechnicaI engineering is far less exact Nan olher engineering disci- plines. This lack of understanding has created unrealistic expectations that have led to disappol0Txnts, claims, and disputes. To help reduce the risk otsuch oulmnim geobechnical engineers commonly includea variety of explarialory provisions in their reports. sometimes labeled "limitations' many of these provisions indicate where geotec` rileN engineers' responsi- bilities begin and end, to help others rem gnize Iheir own responsibilities and risks. Read Use provisions closely. Ask questions, Your geca achnical engineer should respond fully and frankly. Gaminiironmentel Concerns Are Not Covered The equipmml. techniques, and personnel used to periorrn a ge+amnidron- mentalstudy differ significantly from those usad to perform a oolehnia study. For Ihal reason, a geatechnical engineering report does not usually mlale any genenvirnnmental findings, conclusions, or wrnnnendations; e,g., about the likelihood of encountering underground storage tanks or regulated contaminants. Urranticroledet*anmentalproblems have led to gixrterorfs pvnjecf failam.. if yob have not yel obtained your own genen- vironmental infr}rmation, ask your gp,,DWhnical comuIWt for risk man - agernent guidance. Do not rely on an ertvirri mental report prepared for someone else. Obtain Prflfessinnal Assistance To Real with Maid Diverse siralegies can be applied during building design, construction, operation, and rimintenance to prevent signifiWlltMUMS of mold from growing on indoor surfaces. Tn he effective, all such strategies should be devised for die mpress purpose of mold prevention, inlegrated into a corn- prehensive plan, and executed with diligeir ovefsight by a prdmiond maid prevention consultant_ Becaum just a small amount of water or moisture can lead to the development of severe mold infestations, a num- ber of mold prevention strategies focus an keeping building surfaces dry. While ground►raier, water infiltration, and similar issues may have bean addressed as part of the geotechnkal engineering study whose findings are cunveyed in this report, the geotEchnical engineer in charge of this project Is nd a meld prevention Con5ullanl. nona at the services par - formed in connection wilts the geateahaical enpilreer's study were designed or conducted for the purpose of moltdpaewn- Nan. Propar implemenfafian nl the remmmendatinns conveyed in this repart will not al ifself be srrfticient to provenf mold from growing in or orr the slruelure involved. RelW on Your ASFE-Member GeutechnCial Engineer top Additional Assistance Mern bersNp ifs ASFN7HE Ns7 PEOPLE oN EmTH exposes geotechnical engineers loa w4a array of risk management techniques thAt can be of genuine benefit for averyone involved with a constructioa project. Confer with you -9FE-mernber geotechnical engheer far more 1Rformalion, ASFr= THE REST PEEPEE OK EJEitf esi i Caiasviiie noadlSuae Gi till, Silver Spring MD 2010 Tsl ephgne: 301 i565.2T33 1`43iralle: V (505-2011 e-mall. irdoadsfe.org www.asle.org CopyrfgtFf 7JW by AVt< trac &VkACzip. repr6durthm. nr WpprrV of r#S dvcomorrr, 6 who or rrr paR, byar�y fttMnS &Mftrt?Wr, rs strkfr prehl NMd, except WOMASfFS spwirer wrAwrr permissran_ Emirtrrm, gii0Pp, or aawnffhx extrarl y warding tram rha &xummw is permitted only with the express wauff. Perm&wn arASFF, and anrp far puWaaes of zv luWa Fv6wxh or Wok rBUtdW. On� m"urs of AM rrrdiy use ibis ducun4"t a a comprevnl fu or ss as element of a gvohetlrnrsat arrpa'nsofing report Airy alder firm, +ndrviduaf' or curer 60% Vat so frsas ibis dacsrrrent Wftut is ng an A5FF membermald tie comrt fVng nepbpNd ar rrrt6rR+onar paudriWo mfsrepmsesranorr, IIGROSM.4MRP . ' Architecture Engineering An Employee -Owned Company Environmental Stormwater Management Report b � Land Surveying Companies APPENDIX I SITE OPERATIONS AND MAINTENANCE PLAN 6135 Park South Drive • Charlotte, NC 28210 • (980) 999-1772 • www.blcompanies.com . Architecture Engineering An Employee -Owned Company Environmental . � Land Surveying Companies Site Operations and Maintenance Plan For the proposed development located at: Boylston Highway Mills River, North Carolina Prepared for Submission to: Town of Mills River, North Carolina December 5, 2019 Revised: January 30, 2020 Prepared for: Samet Corporation P.O. Box 8050 Greensboro, NC 27419 Prepared by: .�' Architecture Engineering Environmental .� Land Surveying Companies BL Companies 3420 Toringdon Way, Suite 210 Charlotte, NC 28277 (704) 565-7070 BL Project Number: 1901780 Contents GENERALOVERVIEW.............................................................................................................................................3 STORMWATER MANAGEMENT MAINTENANCE..............................................................................................8 SYSTEM COMPONENTS ......... PARKING LOTS ....................... LANDSCAPING ........................ TRASH COLLECTION .............. SNOW REMOVAL & STORAGE OUTDOOR STORAGE ............. 10 10 10 10 11 UTILITIES..................................................................................................................................................................11 INSPECTION LOG - FORM MAINTENANCE SCHEDULE FORM General Overview This report has been prepared in support of a Permit Application submission to the North Carolina Department of Environmental Quality (NCDEQ) by Samet Corporation for the proposed development at the intersection of Boylston Highway and Fanning Fields Road. The subject property is approximately 28.88 acres in size and is currently undeveloped, forested farmland areas. Several pockets of wetlands and streams, including a USGS "blue -line" stream, reside on the eastern and western portions of the property, leaving the developable land between them. The USGS "blue -line" stream, also known as "Stream 1", requires a 30-foot buffer. However, no proposed development will be impacting any streams, associated buffers, or wetlands on -site. The property is bordered to the north and west by Boylston Highway (Rte. 280), to the south by Miles View Drive, and to the east by undeveloped pasture and farmland. Several industrial and commercial uses, such as FedEx Ground, exist across Boylston Highway and Pepsi Bottling Group resides to the south of Miles View Drive. Generally, the property slopes toward Boylston Highway. Approximately half of the property slopes northwestward toward "Stream 3" and "Stream 4" (surrounded by "Wetland 3") which discharges to the northwest and underneath Boylston Highway. The other half of the property similarly slopes northeastward toward "Wetland 1" and "Stream 1" that also discharges to the north and underneath Boylston Highway. The proposed site development consists of a proposed 110,866 s.f. industrial warehouse building, associated impervious parking and drives, subsurface detention facilities, ADS BayFilter filtration structures, lawn with various landscape plantings, and proposed utilities. The development will not impact any wetlands or streams, nor will it impact the USGS "blue -line" stream, also known as "Stream 1", or its buffers. To mitigate the increase in peak runoff caused by the proposed development, several underground stormwater detention facilities have been designed and are proposed to be located onsite below the parking lots. The detention facility attenuates the peak runoff flows up to and including the 25-year design storm. The intent of the on -site stormwater management system is to mimic the pre -development drainage patterns to the maximum extent practical. The site stormwater system provides stormwater detention and water quality improvements through ADS BayFilter filtration structures, underground stormwater management systems (detention/infiltration ponds), deep sump catch basins, riprap energy dissipators, and a pavement sweeping program to treat the impervious surfaces. These measures have been designed in accordance with the 2013 NC Erosion and Sediment Control Planning and Design Manual and the NCDEP Stormwater Design Manual. The following Operations and Maintenance Plan, herby referred to as Plan, was prepared specifically for the development located in the Town of Mills River, North Carolina. The Plan was developed to satisfy the requirements of the North Carolina Division of Environmental Quality (NCDEQ) Stormwater Design Manual and the Erosion and Sediment Control Planning Design Manual. The Plan was developed to satisfy the Town of Mills River Zoning Permit and the North Carolina Department of Environmental Quality's requirements for the Stormwater Management Plan for the General Permit for the Discharge of Stormwater Associated with Commercial Activity. Purpose & Goals The purpose of this Plan is to ensure that the stormwater management components are operated in accordance with all approvals and permits. The primary goal is to inform all property managers on how the system operates and what maintenance items are necessary to protect downstream wetlands and watercourses. The secondary goal is to provide a practical, efficient means of maintenance, planning, and record keeping, verifying permit compliance. Resaonsible Parties The Property Owner, and other parties as listed below, will be responsible for implementing the Plan for the subject property. Company: ALM Asheville, LLC Contact: Brian Hall Business Address: 9830 Colonnade Boulevard, Suite 600 San Antonio, TX 78230 Maintenance inspections shall be performed by a qualified professional. The property owner may retain a management company to oversee the maintenance of the site. A contact name and phone number for the Facility Manager responsible to follow and adhere to this plan will kept on file with this plan and provided to the Town of Mills River. Some utilities located on the site will be owned and maintained by various utility companies in accordance with their standards. The property owner may maintain the service connections and shall coordinate with the corresponding utility provider for additional information. List of Permits & Special Conditions The project will receive several permits, which may contain special conditions that require compliance by the property owner and maintenance contractors. This permit may include the following: • Town of Mills River Permits — o Town of Mills River Zoning Permit: Site Plan o Commercial Construction: Building Permit • State of North Carolina Permits — o NCDEQ General Permit for the Discharge of Stormwater Associated with Commercial Activity o NCDEQ Erosion Control Permit o NCDEQ Stormwater Permit o NCDOT Approvals and Curb Cut Approval Maintenance Logs and Checklists The property owner will keep a record of all maintenance procedures performed, date of inspection/cleanings, etc. Copies of inspection reports and maintenance records shall be kept on -site and be readily available if requested by local municipalities or state authorities. Forms The following forms will be developed for annual maintenance. Copies of the forms will be kept on -site as part of the Stormwater System Operation and Maintenance Plan. • Annual Checklist • Quarterly Checklist • Monthly Checklist Employee Training The property owner will have an employee -training program, with annual updates, to ensure that the qualified employees charged with maintaining the buildings and grounds do so in accordance with the approved permit conditions. All sub -contractors (Vactor, landscaping, snowplowing, etc.) will be informed of requirements and responsibilities. Spill Prevention, Response and Clean-up Procedures These procedures provide guidance for the prevention of spills of hazardous materials, and the notification, clean-up, and reporting of releases should they occur at the site. A formal plan shall be prepared and kept on site in the Facility Manager's office. Hazardous Materials Storage All hazardous materials shall be stored high and dry in secure locked areas. A list of hazardous materials on -site should be maintained and updated as required. All hazardous products, shall be transported, stored, and used in compliance with applicable labels, regulations, and permit conditions. No incompatible materials shall be mixed or stored together. Compliance with all applicable regulations, including those relating to proper labeling, retention of MSDS sheets, compatibility requirements, containers, and housekeeping shall be the responsibility of the contractor. Drums and containers will be clearly labeled and stored with all labels visible. All flammable products will be stored away from heat and/or ignition sources. All transportation of hazardous materials shall occur in compliance with all applicable federal, state, and local regulations and permit conditions. Equipment and Materials The Facility Manager shall keep on -hand appropriate equipment, supplies, and materials for containment and clean-up of chemicals, in the event of a spill. These materials may include but are not limited to: • Spill Kits for Equipment. • Sorbents for containment and quick pickup of spilled liquids. • Drums, barrels, temporary storage bags for containment and transportation. • Absorbent pads, oil booms, mats, or equivalent. • Washable, reusable rags for cleaning up small leaks. • Sheet plastic. • The above listed materials and dry powder and any other material for use in oil spill clean-up will be stored onsite in a secure area. All personnel will be notified of the location of materials used to contain spills. Site Management and Spill Prevention The following measures should be implemented to ensure the proper storage and disposal of wastes: • Designate waste collection areas. • Cover waste containers. • Schedule waste collection at appropriate intervals to prevent overfilling of containers; • Clean up any spills immediately and dispose of in accordance with applicable state and local laws. • Maintain adequate spill prevention materials (e.g., absorbent pads, booms) on -site. • No petroleum products other than those used for small equipment shall be stored on -site. Fuel trucks or fuel storage tanks to fuel equipment/trucks shall not be stored on site. • Storage areas and waste containers should be included in the regular inspection program of the site. Inspection and Leak Detection Facility Manager and/or designated staff shall conduct routine inspections of equipment and facilities, and any other potential sources of hazardous releases. Equipment and facilities will be inspected on a routine basis for leaks of potential hazardous materials and for integrity of containment should where applicable. Spill Event and Clean-up Procedures In the event of a spill occurrence, the following actions are to be taken: • Notify Mills River Fire Department, City of Asheville Water Department and NCDEQ. • Contain the release; • Contain the release using absorbent or absorbent socks or booms to minimize the extent of the spill; • Protect sensitive receptors such as drains, storm drains, surface water bodies, and minimize the amount of uncontrolled release; • Corner off the spill area with "CAUTION" tape. The area should consist of the entire spill area plus a buffer of at least three feet; • For spills less than 5 gallons on an impervious surface, attempt to confine and clean the spill; • For spills greater than 5 gallons, attempt to confine the spill and call a remediation contractor if assistance is required with product recovery and containment; 9 Corrosive spills should be neutralized using an appropriate neutralizing agent; • Clean up the spill from the perimeter inward using appropriate absorbent (clays, pads, pillows, etc.); • Collect all contaminated media in drums, if quantities permit; • Clean all reusable equipment using rags and cleaners as appropriate; • Dispose of all disposable equipment (e.g., PPE) in drums; • Document the spill and report to the proper authorities. • For spills greater than 5 gallons, report to DEEP, Mills River Water Division and Mills River Fire Department. • Provide written documentation of the spill. • An up-to-date list of qualified emergency response contractors with the capability of reaching the project site quickly shall be onsite. No disposal of waste materials on -site is permitted. Stormwater Washouts If any unanticipated stormwater washouts occur on site that are not covered under general maintenance of any of the Stormwater Management Facilities listed below, the facility manager shall contact the engineer of record for recommendations on corrective actions to be performed. A log of washouts and corrective actions taken, including dates, shall be included with the general maintenance logs. Stormwater Management Maintenance System Components The stormwater management system has several components that are shown on the Grading and Drainage Plan (GD-1 & GD-2) and perform various functions in capturing, routing, and treating stormwater runoff. A - Catch Basins. Yard Drains. and Manholes Catch Basins and yard drains are inlets which trap road sand and floatable debris prior to draining through the storm sewer system. The proposed catch basins and yard drains (CBs) are equipped with sumps with sump depths 4' below the outlet pipe. The property owner is responsible for cleaning the catch basins, yard drains and manholes on the site. A North Carolina Licensed hauler shall clean the sumps and dispose of removed sand legally. The road sand may be reused for winter sanding but may not be stored on -site. As part of the hauling contract, the hauler shall notify the property owner in writing where the material is being disposed. Each catch basin and yard drain shall be inspected every four months, with one inspection occurring during the month of April. Any debris occurring within one foot from the bottom of each sump shall be removed by Vacuum "Vactor" type of maintenance equipment. B — ADS BayFilter filtration structures (or approved equal) The BayFilter system requires periodic maintenance to continue operating at the design frequency. The maintenance process is comprised of removal and replacement of each BayFilter cartridge, vertical draw down module; and the cleaning of the vault por manhole with a vacuum truck. The ADS BayFilter filtration structures shall be maintained according to the manufacturer's recommendations. The maintenance procedures are attached to this document. A detailed maintenance logbook shall be kept for each filtration structure. Information is to include, but not be limited to, the date of inspection, record of grit depth, condition of filters, observation of any floatable, and date of cleaning performed. C - Underground Infiltration Systems and Piping The underground detention and infiltration systems are designed to collect flows from all paved parking areas and shall be inspected every six months in the months of April and October. Each of the inspection manholes provided shall be opened and visually checked from the surface. Observation of grit inside of the detention systems shall be noted and any deposits found to be 2 inches or more, as measured from the invert of pipe, shall be cleaned and removed. The underground infiltration systems qualify as a Confined Space under OSHA regulations, and any maintenance involving entry into the pipes should comply with OSHA Confined Space Entry Regulations. The perforated piping system will be visually inspected through the manholes. If deemed necessary, the perforated piping can be TV inspected. Site Maintenance Parking Lots Parking lots, driveways and sidewalks shall be swept regularly by the property owner to clean trash and other debris. The property owner will sweep parking lots on its property in the spring to remove winter accumulations of road sand. Landscaping The property owner will maintain landscaped areas. Normally the landscaping maintenance will consist of pruning, mulching, planting, mowing lawns, raking leaves, etc. It expected that all landscaping is to remain in healthy condition that is consistent with approved plans. Trees/landscaping that die must be replaced. Use of fertilizers and pesticides will be controlled and limited to minimal amounts necessary for healthy landscape maintenance. The lawn areas, once established, will be maintained at a typical height of 2'/"-3". High grass along the pond edge is not to be mowed. This will allow the grass to be maintained with minimal impact from weeds and/or pests. The low -maintenance slope areas will be maintained as a meadow or allowed to revert back to natural conditions. Pesticides will only be used as a control method when a problem has been clearly identified and other natural control methods are not successful. All pesticide applications shall be by licensed applicators, where necessary. Invasive vegetation is to be removed. Topsoil, brush, leaves, clippings, woodchips, mulch, and other material shall be stored off site. Trash Collection All trash will be contained in self-contained trash compactors on -site with access to an exterior door. The self-contained trash compactor will be enclosed. All trash will be collected on a regular basis and disposed of legally off -site. Snow Removal & Storage Snow shall be shoveled and plowed from sidewalks, driveways and parking areas as soon as practical during and after winter storms and stored in snow storage areas on site where practical. No sodium chloride shall be used for ice or snow control on the site. Snow removal deposition areas will be checked and maintained after the winter season by removal of any debris and sand and restored to original condition after seasonal winter conditions. Vegetation will be raked and if needed, pruned or reseeded. Outdoor Storage There will be no outdoor storage of hazardous chemicals, fertilizer, pesticides, or herbicides anywhere in the site. Clean wooden pallets and baled cardboard may be stored outside periodically. These items will be removed from the site on a regular schedule. Utilities Sanitary Sewer System All of the on -site sanitary sewer collection system will be owned and maintained by the property owner. On -Site Collection Sewer: The property owner will annually inspect the manholes within the on -site sewer system on the property and check for debris and blockages. Any low - flow lines with accumulations will be cleaned with water jetting. Water System The on -site mains and fire hydrants will be owned and maintained by the property owner. The off -site mains are owned and maintained by the City of Asheville Water Department. The property owner will be responsible for maintaining the domestic and fire service lines to the buildings and the on -site hydrants. Gas\Electric\Telecommunications System The gas system on site will be owned and maintained by the property owner and gas will be provided by Dominion Energy. The electric system will be owned and maintained up to the transformer by Duke Energy. The property owner will maintain the secondary electric lines from the transformers to the buildings. The telecommunications system will be owned and maintained by AT&T up to the buildings. Site Lighting The property owner is responsible for maintaining the parking lot, driveway and building - mounted lights on the property. BAYFILTERTm INSPECTION AND MAINTENANCE MANUAL The BayFilter system requires periodic maintenance to continue operating at the design efficiency. The maintenance process is comprised of the removal and replacement of each BayFilter cartridge, vertical drain down module; and the cleaning of the vault or manhole with a vacuum truck. The maintenance cycle of the BayFilter system will be driven mostly by the actual solids load on the filter. The system should be periodically monitored to be certain it is operating correctly. Since stormwater solids loads can be variable, it is possible that the maintenance cycle could be more or less than the projected duration. BayFilter systems in volume -based applications are designed to treat the WQv in 24 to 48 hours initially. Late in the operational cycle of the BayFilter, the flow rate will diminish as a result of occlusion. When the drain down exceeds the regulated standard, maintenance should be performed. When a BayFilter system is first installed, it is recommended that it be inspected every six (6) months. When the filter system exhibits flows below design levels the system should be maintained. Filter cartridge replacement should also be considered when sediment levels are at or above the level of the manifold system. Please contact the BaySaver Technologies Engineering Department for maintenance cycle estimations or assistance at 1.800.229.7283. BayFilter System Cleanout Vactor Truck Maintenance Jet Vactoring Through Access Hatch Maintenance Procedures 1. Contact BaySaver Technologies for replacement filter cartridge pricing and availability at 1-800-229-7283. 2. Remove the manhole covers and open all access hatches. 3. Before entering the system make sure the air is safe per OSHA Standards or use a breathing apparatus. Use low 02, high CO, or other applicable warning devices per regulatory requirements. 4. Using a vacuum truck remove any liquid and sediments that can be removed prior to entry. 5. Remove the hold down bars. Using a small lift or the boom of the vacuum truck, remove used cartridges by lifting them out. 6. Any cartridges that cannot be readily lifted can be easily slid along the floor to a location they can be lifted via a boom lift. 7. When all the cartridges have been removed, it is now practical to remove the balance of the solids and water. Loosen the stainless clamps on the Fernco couplings for the manifold and remove the drain pipes as well. Carefully cap the manifold and the Ferncos and rinse the floor, washing away the balance of any remaining collected solids. 8. Clean the manifold pipes, inspect, and reinstall. 9. Install the exchange cartridges, reinstall the hold down bars and close all covers. 10. The used cartridges may be sent back to BaySaver Technologies for recycling. For more information please see the BaySaver website at www.baysaver.com or contact 1-800-229-7283. ,,,,,,,2 wtb% Manifold Tee View of a Cleaned System Cartridge Hoist Point MAINTENANCE SCHEDULE During the First Year of Operation: Task: Completion Date: Manager's Initials: JANUARY: Employee Training Program with Spill Program *Stormwater Management Basins (Underground) FEBRUARY: * Stormwater Management Basins (Underground) MARCH: * Stormwater Management Basins (Underground) APRIL: *Catch Basin/Yard Drain * Stormwater Management Basins (Underground) ADS BayFilter *Sanitary Inspection Shrub Fertilization AUGUST: *Catch Basin/Yard Drain * Stormwater Management Basins (Underground) OCTOBER: * Stormwater Management Basins (Underground) ADS BayFilter Tree and Lawn Fertilization DECEMBER: *Catch Basin/Yard Drain * Stormwater Management Basins (Underground) *NOTE: Use appropriate worksheet found in this plan to conduct the inspection. After the First Year of Operation: FOR YEAR Task: Completion Date: Manager's Initials: JANUARY: Employee Training Program with Spill Program APRIL: *Catch Basin/Yard Drain * Stormwater Management Basins (Above Ground) ADS BayFilter *Sanitary Inspection Shrub Fertilization AUGUST: *Catch Basin/Yard Drain OCTOBER: * Stormwater Management Basins (Above Ground) Tree and Lawn Fertilization DECEMBER: *Catch Basin/Yard Drain *NOTE: Use appropriate worksheet found in this plan to conduct the inspection. O U ^ U •� 0 U .14 �^ aacl z z z z z z cl U to 0 Cb QU 0 �•14 z z z z z z cl U U U U � U � Q � U O O O O O O ° U w w w w w w U •� Q U = Operation & Maintenance Agreement Project Name: Proposed Development - Boylston Highyway, Mills River, NC Project Location: 5Fanning Fields Road Cover Page Maintenance records shall be kept on the following SCM(s). This maintenance record shall be kept in a log in a known set location. Any deficient SCM elements noted in the inspection will be corrected, repaired, or replaced immediately. These deficiencies can affect the integrity of structures, safety of the public, and the pollutant removal efficiency of the SCM(s). The SCM(s) on this project include (check all that apply & corresponding O&M sheets will Infiltration Basin Quantity: Infiltration Trench Quantity: Bioretention Cell Quantity: Wet Pond Quantity: Stormwater Wetland Quantity: Permeable Pavement Quantity: Sand Filter Quantity: Rainwater Harvesting Quantity: Green Roof Quantity: Level Spreader - Filter Strip Quantity: Proprietary System Quantity: Treatment Swale Quantity: Dry Pond Quantity: Disconnected Impervious Surface Present: User Defined SCM Present: Low Density Present: 8 Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Type: 7 No No No �Z3"LCI�RYI1lU] Iifa\t I acknowledge and agree by my signature below that I am responsible for the performance of the maintenance procedures listed for each SCM above, and attached O&M tables. I agree to notify NCDEQ of any problems with the system or prior to any changes to the system or responsible party. Responsible Party: David Buck Title & Organization: Executive Managing Director, ALM Asheville Street address: 9830 Colonnade Blvd, Suite 600 City, state, zip: San Antonio, TX 78255 Phone number(s): (210) 641-8484 Email:l david.buck@usrealco.com Signature: Date: 154 — \ - "I \ 1, Aga n �A,n+t 0►AO —,a Notary Public for the State of j �'�Ca-S County of Re KQt- , do hereby certify that 3 mi d Yt1CV- personally appeared before me this Ll th— day of Pe'_h rU6L r1A a, Oak and acknowledge the due execution of the Operations and Maintenance Agreement. Witness my hand and official seal, f` 1 Qatri_ •--- Seal Ir 1 ar • 1=i My commission expires it�'�,p�y STORM-EZ 2/9/2021 Version 1.5 O&M Agreement Page 1 of 1 Infiltration Basin Maintenance Requirements Important operation and maintenance procedures: - The drainage area will be carefully managed to reduce the sediment load to the infiltration basin. No portion of the infiltration basin will be fertilized after the initial fertilization that is required to - establish the vegetation. Lime may be allowed if vegetation is planted on the surface of the infiltration basin and a soil test shows that it is needed. - The vegetation in and around the basin will be maintained at a height of four to six inches. After the infiltration basin is established, it will be inspected quarterly and within 24 hours after every storm event greater than 1.0 inches (or 1.5 inches if in a Coastal County). Records of operation and maintenance shall be kept in a known set location and shall be available upon request. Inspection activities shall be performed as follows. Any problems that are found shall be repaired immediately. SCM element: Potential problem: How to remediate the problem: The entire infiltration Trash/debris is present. Remove the trash/debris. basin Areas of bare soil and/or Regrade the soil if necessary to remove the gully, plant ground erosive gullies have cover and water until it is established. Provide lime and a one - The grass filter strip or formed. time fertilizer application. other pretreatment area Sediment has Search for the source of the sediment and remedy the problem accumulated to a depth of if possible. Remove the sediment and dispose of it in a location greater than three inches. where it will not cause impacts to streams or the SCM. The structure is clogged. Unclog the conveyance and dispose of any sediment in a The flow diversion location where it will not cause impacts to streams or the SCM. structure (if applicable) Make any necessary repairs or replace if damage is too much The structure is damaged. for repair. The inlet pipe is clogged (if Unclog the pipe and dispose of any sediment in a location applicable). where it will not cause impacts to streams or the SCM. The inlet pipe is cracked or otherwise damaged (if Repair or replace the pipe. applicable). Erosion is occurring in the Regrade the swale if necessary and provide erosion control The inlet device swale (if applicable). devices such as reinforced turf matting or riprap to avoid future erosion problems. Stone verge is clogged or Remove sediment and clogged stone and replace with clean covered in sediment (if stone. applicable). More than four inches of Search for the source of the sediment and remedy the problem sediment has if possible. Remove the sediment and dispose of it in a location accumulated. where it will not cause impacts to streams or the SCM. The basin Erosion of the basin surface has occurred or Provide additional erosion protection such as reinforced turf riprap is displaced. matting or riprap if needed to prevent future erosion problems. Water is standing more Replace the top few inches of soil to see if this corrects the than three days after a standing water problem. If not, consult an appropriate storm event. 1professional for a more extensive repair. Infiltration Basin Maintenance Requirements (continued) SCM element: Potential problem: How to remediate the problem: Shrubs or trees are growing on the Remove shrubs and trees immediately. embankment. The embankment n annual inspection by an appropriate professional shows that Make needed repairs immediately. the embankment needs repair. Clogging has occurred. gg g Clean out the outlet device and dispose of sediment in a location where it will not cause impacts to streams or the SCM. The outlet device The outlet device is Repair or replace the outlet device. damaged Erosion or other signs of damage have occurred at Repair the damage and improve the flow dissipation structure. the outlet. The receiving water Discharges from the infiltration basin are causing erosion or Contact the local NCDEQ Regional Office. sedimentation in the receiving water. Proprietary System Maintenance Requirements How many devices are 0 Contech StormFilters? Important operation and maintenance procedures: - The drainage area will be carefully managed to reduce the sediment load to the StormFilter. - The sedimentation chamber or forebay will be cleaned out whenever sediment depth exceeds six inches. The StormFilter system will be inspected quarterly. Records of operation and maintenance will be kept in a known set location and will be available upon request. Inspection activities shall be performed as follows. Any problems that are found shall be repaired immediately. BMP element: Potential problem: How to remediate the problem: Adjacent pavement (if Trash/debris is present. Remove the trash/debris. applicable) Flow diversion structure Sediment is present on the Sweep or vacuum the sediment as soon as possible. pavement surface. StormFilter Cartridges The structure is clogged. Unclog the conveyance and dispose of any sediment offsite. The structure is damaged. Make any necessary repairs or replace if damage is too large for repair. Outlet device Clogging has occurred. Clean out the outlet device. Dispose of the sediment offsite. The outlet device is Repair or replace the outlet device. damaged Erosion or other signs of damage have occurred at Repair the damage and improve the flow dissipation structure. the outlet. The receiving water Discharges from the StormFilter are causing erosion or sedimentation in Contact the local NCDEQ Regional Office. the receiving water. All other operation and maintenance activities should be in accordance with Contech's StormFilter Inspection and Maintenance Procedures document. Any problems that are found shall be repaired immediately. The responsible party shall have received and understand Contech's StormFilter Inspection and Maintenance Procedures document. ATTACH MANUFACTURER'S MAINTENANCE MANUAL FOR ALL PROPRIETARY DEVICES BAYFILTERTm INSPECTION AND MAINTENANCE MANUAL The BayFilter system requires periodic maintenance to continue operating at the design efficiency. The maintenance process is comprised of the removal and replacement of each BayFilter cartridge, vertical drain down module; and the cleaning of the vault or manhole with a vacuum truck. The maintenance cycle of the BayFilter system will be driven mostly by the actual solids load on the filter. The system should be periodically monitored to be certain it is operating correctly. Since stormwater solids loads can be variable, it is possible that the maintenance cycle could be more or less than the projected duration. BayFilter systems in volume -based applications are designed to treat the WQv in 24 to 48 hours initially. Late in the operational cycle of the BayFilter, the flow rate will diminish as a result of occlusion. When the drain down exceeds the regulated standard, maintenance should be performed. When a BayFilter system is first installed, it is recommended that it be inspected every six (6) months. When the filter system exhibits flows below design levels the system should be maintained. Filter cartridge replacement should also be considered when sediment levels are at or above the level of the manifold system. Please contact the BaySaver Technologies Engineering Department for maintenance cycle estimations or assistance at 1.800.229.7283. BayFilter System Cleanout Vactor Truck Maintenance Jet Vectoring Through Access Hatch Maintenance Procedures 1. Contact BaySaver Technologies for replacement filter cartridge pricing and availability at 1800-229-7283. 2. Remove the manhole covers and open all access hatches. 3. Before entering the system make sure the air is safe per OSHA Standards or use a breathing apparatus. Use low 02, high CO, or other applicable warning devices per regulatory requirements. 4. Using a vacuum truck remove any liquid and sediments that can be removed prior to entry. 5. Remove the hold down bars. Using a small lift or the boom of the vacuum truck, remove used cartridges by lifting them out. 6. Any cartridges that cannot be readily lifted can be easily slid along the floor to a location they can be lifted via a boom lift. 7. When all the cartridges have been removed, it is now practical to remove the balance of the solids and water. Loosen the stainless clamps on the Fernco couplings for the manifold and remove the drain pipes as well. Carefully cap the manifold and the Ferncos and rinse the floor, washing away the balance of any remaining collected solids. 8. Clean the manifold pipes, inspect, and reinstall. 9. Install the exchange cartridges, reinstall the hold down bars and close all covers. 10. The used cartridges may be sent back to BaySaver Technologies for recycling. For more information please see the BaySaver website at www.baysaver.com or contact 1-800-229-7283. Manifold Tee View of a Cleaned System Cartridge Hoist Point