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Home My WebLink AboutSW1220701_Design Calculations_20230329Storm water Pollution Prevention Plan Permit No. NCGO 10000 Comprehensive Storm Water Pollution Prevention Plan (C- "VVPPP) For C®rr><st><°auetfl®n Activities: Project/Site Name: All About Plumbing Building Addition Project Address/Location: 5521 Old Haywood Road Suite 1 Mills River, NC 28759 SWPPP Preparer: McCutchen Engineering Associates, PC J. David McCutchen 898 West Saint John Street Spartanburg, SC 29301 Phone: 864-582-0585 Fax: 864-582-0581 Primary Permittee: All About Plumbing Permittee/Owner Contact: Contact: Caleb Wilson 5521 Old Haywood Road Mills River, NC 28759 828-778-2425 office@allaboutplumbingnc.com Day -to -Day Operator: C-SWPPP Preparation Date: 05-25-22 Revised 07-20-22 Revised 11-28-22 Revised 02-28-23 :I GIN@••''��: M C G ..'on�\ rg' -Z 1 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Perm itNo. NCG010000 Table of Contents Section 1 PROJECT OVERVIEW 1.1 Narrative.............................................................................................................. 3-4 1.2 Storm water Management and Sediment Control ................................................ 5-8 1.3 Sequence of Construction........................................................................................8 1.4 Non -Numeric Effluent Limits............................................................................ 8-11 1.5 Buffer Zone Management......................................................................................I I Section 2 SITE FEATURES AND SENSITIVE AREAS 2.1 Sources of Pollution...............................................................................................12 2.2 Ground Stabilization..............................................................................................13 2.3 Materials Handling........................................................................................... 14-15 2.4 Operations & Maintenance.............................................................................. 15-17 Section 3 COMPLIANCE REQUIREMENTS 3.1 SWPPP Availability.............................................................................................18 3.2 Pre -Construction Conferences...............................................................................18 3.3 Inspection Requirements........................................................................................18 3.4 Maintenance Policies............................................................................................19 3.5 Record Keeping....................................................................................................19 3.6 Final Stabilization..................................................................................................20 Appendices REFERENCE MATERIAL Appendix A - Site Maps Appendix B - Drainage Maps Appendix C - Additional Approvals/Certifications Appendix D - Engineering Report (C-SWPPP* Only) Appendix E - Inspection Log and Reports (OS-SWPPP** Only) Appendix F - Rainfall Records (OS-SWPPP** Only) Appendix G - Additional Site Logs and Records (OS-SWPPP** Only) Appendix H - Misc. Design Information/Cut Sheets Appendix I - Pond Maintenance Agreement *C-SWPPP is acronym for Comprehensive Storm Water Pollution Prevention Plan **OS-SWPPP is acronym for On -Site Storm Water Pollution Prevention Plan 2 RIMMMMM All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 Section I PROJECTOVERVIEW 1.1 Narrative (CGP Section 3.2.1) Construction Activities and BNO Summary ect The proposed consist of developing the following: • Proposed 6,400 SF Building • Proposed gravel parking area • Proposed vegetated conveyance — grass swale Parcel #: 9632-57-0722 Total Site Acreage: 3.15 Acres Disturbed acreage for the improvements = 1.30 Acres Soil Type = Bradson (Type B) The NCDEQ Stormwater Design Manual was used in the development and analysis of this project. This project was determined to fall under the low -density stormwater requirements per the calculation below. Project Density Calculation: Per 15A NCAC 2H .1003(1)(b) of the NCDEQ Stormwater Design Manual, the project density is 15.35%. The proposed development is located within the French Broad River Watershed. The proposed BUA increase is 0.33 acres. Per the NCDEQ Stormwater Design Manual, low density projects are not required to be equipped with Stormwater Control Measures (SCMs) in exchange for limiting their built - upon area, maximizing dispersed flow and ensuring that stormwater conveyances are vegetated. These strategies protect the hydrology of the receiving stream, prevent erosion, and remove pollutants through infiltration. Onsite proposed storm water drainage conveyance has been designed using the 10-year storm event (rational method). Vegetated conveyance calculations are included in this report. Perimeter control BMP's (Best Management Practices) shall be installed prior to the initiation of clearing/grubbing, grading and demolition. These structures will be the 3 All About Plumbing - Building Addition Storm water Pollution Prevention Pla❑ Permit No. NCG010000 primary sediment control BMP used during the lifespan of the construction activities until final stabilization is achieved. Construction of this site should occur in THREE (3) distinct Erosion and Prevention and Sediment Control Phases. Phase I consists of the installation of the perimeter controls (i.e. silt fence, tree protection, etc.). Remove trees and vegetation as required to construct the vegetated conveyance. During Phase I diversion ditches/berms, etc. are required to direct sediment laden runoff into appropriate designed measures. Phase II consists of the new construction (building, storm drainage, etc.), grading and storm drainage. During phase II, diversion ditches/berms, etc. are required to direct sediment laden runoff into appropriate designed measures Phase III consists of final stabilization (for all disturbed areas), installation of curb /gutter and landscaping. During Phase III, finalize building construction, remove all BMP's, and finalize landscaping. Onsite Storm Drainage: Onsite storm drainage features (i.e. grass swales) have been designed for the 10-year storm event (rational method) Rainfall intensity = 7.09 in/hr (5 min duration) Rainfall Events (inches) — SCS/TR-55 Method Mills River 2 year: 3.58 inches 10 year: 5.06 inches 25 year: 5.96 inches 50 year: 6.69 inches 100 year: 7.45 inches Flooding Issues To the best of our knowledge and belief, no downstream flooding problems are present at the time this design was done. 4 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 1.2 Storm water Management and Sediment Control (CGP Section 3.2.2) Erosion Prevention BMPs As the existing site is cleared, grubbed and graded to the proposed contours shown on the construction site plans, erosion prevention BMPs shall be placed throughout the construction site to aid in the prevention of sediment -laden storm water runoff. These BMPs shall be focused in areas with high potential of erosion, areas preceding infiltration practices, and shall be applied to all steep slopes. That is slopes equal to or greater than 3H:1V. Each erosion prevention measure shall be selected on a site -specific basis and details have been provided on the construction site plans. The plans identify all proposed Erosion Prevention BMPs and the recommended installation, maintenance, and inspection procedures. Examples of Erosion Prevention BMPs are, but are not limited to, surface roughening, temporary seeding, erosion control blankets, turf reinforcement mats, sodding, riprap, outlet protection, dust control, and polyaciylamide (PAM). Sediment Control BMPs Sediment Control BMPs are designed to remove some of the sediment accumulated within storm water runoff, to the best extent practicable. These BMPs help prevent sediment impacts to adjacent properties and water bodies from storm water discharges originating from construction sites. Typically these BMPs are placed near each of the site's outfalls and are installed prior to clearing and grubbing of the site (before large areas of soil are exposed). However, these BMPs can also be located throughout the construction site and, in these circumstances, are installed after mass grading has occurred. Placement, sizing and modifications of Sediment Control BMPs should be left to the SWPPP preparer and/or the Site Engineer. Contractors must consult the SWPPP Preparer as listed at the front of this SWPPP before malting any significant changes to these BMPs. Each sediment control BMP shall be selected on a site -specific basis. Examples of Sediment Control BMPs are, but are not limited to sediment traps, sediment basins, silt fence, rock check dams, rock sediment dikes, sediment tubes, and inlet protection. Structural Control BMPs and Floodplain Placement This site -specific SWPPP utilizes the following structural control BMPs: storm water management pond, storm sewer systems, inlet protection and silt fence. These practices have been designed to either divert flows from exposed soils, to retain/detain flows, and to otherwise limit the runoff and the discharge of pollutants from disturbed areas of the construction site. 5 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 Throughout the lifespan of the construction project these BMPs will be installed and maintained, as required by the SWPPP and the construction site plans, until final stabilization has been achieved for the areas draining to each BMP. Upon final stabilization, each structural control BMP must be modified to the post -construction conditions shown within the approved construction site plans or removed, if the structural BMP was a temporary structure Construction Entrances and Dust Control All access areas into and out of the limits of disturbance, as shown on the construction site plans are required to be equipped with a construction entrance. The use of this BMP will limit the amount of sediment being transported by construction vehicles onto existing roadways or other impervious areas. Any tracked sediment, along with any attached pollutants, deposited on impervious areas could be washed downstream during the next rain event. Each construction entrance must be installed as shown in the details section of the construction site plans. If a new entrance or exit is required, that is not shown on the plans, install the construction entrance as noted by the construction entrance detail, marls the location on the plans and make a record of this minor modification in the SWPPP's modification log, which is located within one of the appendices of the On -site SWPPP. Each stabilized construction entrance should be used in conjunction with Street Sweeping measures if it becomes apparent that sediment is still being tracked onto adjacent impervious areas, even with the use of the construction entrance. During extremely dry conditions, drought, and/or excessive winds, the construction site should be treated for dust control to prevent the suspension of fine sediment particles into the air, being carried offsite, and deposited on adjacent properties or surface waters. This practice may not be directly called out for on the construction site plans. A water tanker used to spray the soil down may be an effective way to prevent excessive dust at a construction site. Water Quality BMPs During Construction Site -specific water quality BMPs (e.g., storm water management pond, inlet protection, silt fence, and outlet protection) must be installed prior to the mass clearing, grubbing and grading of the site, and must be kept in functioning order throughout the lifespan of all construction activities. Each of these BMPs must be maintained and inspected until all areas draining to these BMPs have reached final stabilization, approved by the construction site inspector or the SWPPP Preparer, and recorded within the stabilization log located as an appendix of the On -site SWPPP. The location, installation procedures, and maintenance procedures for each water quality BMP can be found within the approved construction site plans. 6 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO10000 Sediment and Erosion Control Trapping Efficiency Sediment Trapping will be achieved via silt fence. The sediment trapping calculations for the proposed site via silt fence are shown below. Sediment Trapping Efficiency During Construction (Perimeter Silt Fence) Storm Event Trapping Efficiency (SEDCAD Calcs) 2 year 96.1 % 10 year 95.1 % Drainage area = 0.57 acres SCS CN = 86.0 Length: Double row of 125' of silt fence (250' Total) Height: 2.5' Post -Construction Water Quality Upon final stabilization, each construction site will have to make the transition from temporary BMPs to permanent BMPs. This transition includes the conversion of the temporary diversion swales to permanent grass swales. Swales remove pollutants from stormwater by biofiltration, settling and infiltration. Grassed swales filter pollutants as stormwater runoff moves through the leaves and roots of the grass. Other Storm Water Management Procedures Based on the nature, conditions, and/or procedures associated with this construction site, the following items must be followed and adopted by all those conducting land disturbing activities at this site: • All construction debris must be stockpiled in designated areas, which have been provided with the proper BMPs to prevent the discharge of pollutants through storm water runoff from building or other similar materials off -site or into surface waters. • Any additional waste material or stockpile material (i.e., soil and mulch) must also be stored in the designated areas as shown on the Construction Site Plans or as the contractor, responsible for day -day activities at this site, deems appropriate. Silt fence or an approved equal shall surround all stockpiled materials. • All parties conducting work at this construction site must be informed of and make note of pollutant sources, both industrial and construction, at this site, and be informed of all controls and measures the will be implemented to prevent the discharge of these pollutants in storm water runoff. • Any additional non -storm water discharges, as referenced in the CGP, should be 7 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 eliminated or reduced to the maximum extent feasible. All unpreventable non -storm water discharges shall be treated through the approved storm water management system before release off -site. Following is a list of allowable non -storm water discharges: ■ Fire hydrant flushing ■ Wash water without detergents ■ Water used for dust control ■ Potable water ® Building wash down water without detergents Uncontaminated pavement wash water TJ Uncontaminated condensation from mechanical equipment ❑ Uncontaminated ground or spring water Water from foundation of footing drains ■ Uncontaminated excavation dewatering ■ Landscape irrigation. 1.-1 OCL/UC11CC UI 1_IUJL5Ll UC%L1U11 The construction sequence for this project has been provided on Drawings EP series plans of the construction site plans. Each item/step of that construction sequence has been listed is the sequence that they should be implemented. The estimated construction start date is January 2023. The estimated construction completion date is May 2023. For additional information or questions on the sequencing please contact the SWPPP Preparer or the Permittee referenced on the cover of this SWPPP. 1.4 Non -Numeric Effluent Limits Storm water Volume and Velocity Control During the implementation of construction activities, all parties performing work at this construction site whose work may affect the implementation of the SWPPP must be informed of and directed on how to comply with this Non -Numeric Effluent Limit, which requires the management of storm water runoff within the construction site and at each outfall. The purpose of this requirement is to control the storm water volume and velocity at these locations to minimize erosion. Specifically, each responsible party should be made aware of the practices that have been or should be implemented at the construction site to accomplish these particular stormwater management practices. Below is a list of practices that may be utilized within the disturbed area and at each outfall at construction sites to control storm water volume and velocity: 8 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 Volume Control • Limiting the amount of disturbed area and exposed soils • Staging and/or Phasing of the Construction Sequence; • Sediment Basins and Sediment Traps • Diverting off -site flow around the construction site; • Controlling the Drainage Patterns within the Construction Site; Temporary Stabilization of Disturbed Areas. Velocity Control • Surface Roughening and/or other Slope Stabilization Practices; • Level Spreaders, Riprap Plunge Pools and/or other Velocity Dissipation BMPS located at the Construction Site's and Sediment Basin Outfalls. • Use of Rock Checks, Sediment Tubes, Etc. in Temporary Diversions Swales and Ditches. • Use of Erosion Control Blankets, Turf Reinforcement Mats, and other Non - Vegetative BMPs that can be used to Quickly Stabilize Disturbed Areas. The SWPPP Preparer/Engineer should approve any modifications (Additional BMPs or Changes to Existing BMPs) to address the management of storm water volume and velocity prior to implementation. All approved SWPPPs that were issued coverage under the CGP should include ample BMPs and other control measures to address this specific Non -Numeric Effluent Limit. Soil Exposure, Compaction and Preservation Throughout construction activities, the amount of soil exposed during construction should be kept to a minimum. This may be accomplished by minimizing the amount the disturbed area within the permitted Limits of Disturbance (shown on the approved construction site plans) to only that which is necessary to complete the proposed work. For areas that have already been disturbed and where construction activities will not begin for a period of 14 days or more, temporary stabilization techniques must be implemented. Prior to implementation of any major grading activities, topsoil is to be preserved by placing it in areas designated for stockpiling until final grades are reached. Each stockpile must be equipped with proper sediment and erosion controls to preserve the topsoil and protect adjacent areas from impacts. Once final grades have been reached, the preserved topsoil should be utilized to apply to areas identified for stabilization. Topsoil contains nutrients and organisms that aid in the growth of vegetation. The compaction of soil should also be minimized to the degree practicable during grading activities. This is especially important during the replacement of topsoil to aid in a quick establishment of vegetative cover. Compaction of soil may also reduce rainfall's ability to infiltrate into the soil, increasing the amount of storm water runoff. Soil Stabilization Throughout construction activities, soil stabilization techniques are to be initiated as soon as practicable whenever any clearing, grading, excavating, or other land- 9 - All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 disturbing activities have permanently or temporarily ceased on any portion of the construction site and will not resume for a period exceeding 14 calendar days. For areas where initiating stabilization measures is infeasible, (e.g., where snow cover, frozen ground, or drought conditions preclude stabilization), initiate vegetative or non - vegetative stabilization measures as soon as practicable. Steep Slopes (Slopes of 30% grade or greater) All disturbed steep slopes (30% grade, —3H:1V, or greater), and steep slopes to be created through grading activities must be managed in a fashion that limits the potential of erosion along the slopes. All parties whose work is/was responsible for the creation/disturbance of steep slopes must comply with the following items: • Minimize the Disturbance of all steep slopes, when possible. • Divert Concentrated or Channelized Flows of storm water away from and around steep slope disturbances. • Use Specialized BMP Controls including temporary and permanent seeding with soil binders, erosion control blankets, surface roughening, reducing continuous slope length with terracing or diversions, gradient terraces, interceptor dikes and swales, grass -lined channels, pipe slope drains, subsurface drains, level spreaders, check dams, seep berms, and triangular silt dikes to minimize erosion. • Initiate Stabilization Measures as soon as practicable on any disturbed steep slope areas where construction activities have permanently or temporarily ceased, and will not resume for a period exceeding 7 calendar days. • A Vegetative and/or Non -Vegetative Cover must be established within 3 working days from the time that stabilization measures were initiated. Stabilization of steep slopes should be a priority for those performing work at the construction site. At the very least, runoff control BMPs should be implemented to transport storm water runoff from the top of the slope to the toe of the slope. An example of this is to install diversion swales along the top of slope and direct the runoff towards pipe slopes drains to transports the runoff to the toe of the slope. All pipe slope drain outlets are to be equipped proper outlet protection. Sediment Discharge Minimization Permittees, Contractors, and all other parties responsible for conducting land - disturbing activities are required to install and maintain all erosion and sediment BMPs that are identified on the approved construction site plans. These BMPs have been designed and approved to address such factors as the amount, frequency, intensity and duration of precipitation, the nature of resulting storm water runoff, and soil characteristics, including the range of soils particle sizes expected to be present on the construction site. Proper installation, inspection, and maintenance will allow these BMPs to operate at maximum efficiencies in order to minimize sediment discharges to the maximum extent practical. 10 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCG010000 Pollutant Discharge Minimization Permittees, Contractors, and all other parties responsible for conducting land - disturbing activities are required to install, implement, and maintain effective pollution prevention measures to minimize the discharge of pollutants. At a minimum, the following items must be implemented: • Minimize the discharge of pollutants from dewatering trenches and excavations by managing runoff with the appropriate controls. Otherwise these discharges are prohibited; • Minimize the discharge of pollutants from equipment and vehicle washing, wheel wash water, and other wash waters. Wash waters must be treated in a sediment basin or alternative control that provides equivalent or better treatment prior to discharge; • Minimize the exposure of building materials, building products, construction wastes, trash, landscape materials, fertilizers, pesticides, herbicides, detergents, sanitary waste and other materials present on the site to precipitation and to storm water; and • Minimize the discharge of pollutants from spills and leaks and implement chemical spill and leak prevention and response procedures. Prohibited Discharges Permittees, Contractors, and all other responsible parties for conducting land - disturbing activities are prohibited to discharges, from the construction site, the following items: • Wastewater from washout of concrete, unless managed by an appropriate control; • Wastewater from washout and cleanout of stucco, paint, form release oils, curing compounds and other construction materials; • Fuels, oils, or other pollutants used in vehicle and equipment operation and maintenance; and • Soaps or solvents used in vehicle and equipment washing. 1.5 Buffer Zone Management Not applicable 11 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 section G SITE FEATURESANDSENSITIVE AREAS 2.1 Sources ofPollution Throughout construction activities, each permittee, contractor, and person responsible for conducting work will need to ensure that sources of pollution are managed to prevent their discharge from the construction site. Expected pollution sources during construction have been identified in Table 2.1-A, but due to the nature of construction activities, it is often tough to predict all pollution sources that may appear throughout the life of a construction project. For that reason, the following table has also been provided to help all those performing work at this construction site identify possible sources of pollution Storm water runoff subjected to the identified pollution sources must be treated by the appropriate BMPs as directed by this SWPPP. In the event that any additional sources of pollution are identified during construction, the person(s) with day-to-day operational control at the site is to add the new source(s) to Table 2.1-A and consult with the SWPPP Preparer to properly address this source and to prevent the discharge of its pollutant through storm water runoff. Table 2.1-A: Potential Sources of Pollution Source Material or Location* Appropriate Control Measures Chemical Loose soil exposed/disturbed All areas within As directed by the construction Plans. This during clearing, Sediment the Limits of includes Silt Fence, sediment tubes, grubbing and grading Disturbance sediment basins, and sediment traps. activities Areas where Located adjacent construction Heavy Metals to each Concrete Washout Basin as shown on equipment are & pH construction sheet C-8 of the plans. cleaned, a.k.a. entrance concrete washout Water encountered Nutrients & In and around Direct water into impoundments such as during trenching Sediment any trenching basins or traps to allow for the activities. sedimentation of the listed pollutants. Sediment & All areas to be Paving Operations Trash paved. Inlet protection. Nutrients, pH, Material Delivery and Sediment, All areas used as Silt fence and/or sediment dikes Storage Areas Heavy Metals, storage areas oils & grease Metals, Areas Provide secondary containments, locate in Equipment fueling and hydrocarbons, surrounding fuel upland areas. Repair leaking and broken maintenance areas oils and tanks hoses. greases Metal oxides, stoddard Throughout site, solvent, talc, primarily in areas Washwater should be contained and is Paints calcium- of building prohibited from being discharged carbonate, construction arsenic *Area where material/chemical is used on site. 12 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 2.2 Ground Stabilization 1. Ground Stabilzation Timelines Ground stabilization shall be achieved on any area of a site where land disturbing activities have ceased within the timeframes listed in Table 3 below. It is recommended to stabilize the ground more quickly if practicable. Extensions of time may be approved by the E&SC plan authority based on weather or other site -specific conditions that make compliance impracticable. Portions of a site that are lower in elevation and not expected to discharge during construction may be exempt from the temporary ground cover requirements if identified on the E&SC plan and approved by the E&SC plan authority. Table 3: Required Ground Stabilization Timeframes Stabilize within this many Site Area Description calendar days after ceasing Timeframe Variations land disturbance_ (a) Perimeter dikes, swales, ditches, and 7 None perimeter slopes (b) High Quailty Water 7 None HQ Zones (c) Slopes Steeper than If slopes are 10' or less in length 3:1 7 and are not steeper than 2:1, 14 days are allowed 7 days for slopes greater than 50' in length and with slopes steeper than 4:1 (d) Slopes 3:1 to 4:1 14 • 7 days for perimeter dikes, swales, ditches, perimeter slopes and HQW Zones 10 days for the Falls Lake Watershed • 7 days for perimeter dikes, swales, ditches, perimeter (e) Areas with slopes 14 slopes, and HQW Zones flatter than 4:1 • 10 days for the Falls Lake Watershed unless there is zero slope. 2. Permanent Ground Stabilzation Timeline After the permanent cessation of construction activities, any areas with temporary ground stabilization shall be converted to permanent ground stabilization as soon as practicable but in no case longer than 90 calendar days after the last land disturbing activity. Temporary ground stabilization shall be maintained in a manner to render the surface stable against accelerated erosion until permanent ground stabilization is achieved. 13 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 2.3 Materials Han Any structural controls installed to manage construction materials stored or used on site shall be included in the field copy of the E&SC plan. Requirements for handling materials on construction sites shall be as follows: 1. Polyacrylamides (PAMS) and Flocculants Polyacrylamides (PAMS) and flocculants shall be: a.) Stored in leak -proof containers that are kept under storm -resistant cover or surrounded by secondary containment structures designed to protect adjacent surface waters; b.) Selected from the NC DWR List of Approved PAMS/Flocculants list, available at: https:Hfiles nc gov/ncdeq/Water%20Ouailiy/Environmental%2OSciences/ATU/ AnprovedPAMS4_I _2017.pdf, c.) Used at the concentrations specified in the NC DWR List of Approved PAMS/Flocculants and in accordance with the manufacturer's instructions. 2. Equipment Fluids a.) Fuels, lubricants, coolants, and hydraulic fluids, and other petroleum products shall be handled and disposed of in a manner so as not to enter surface or ground waters and in accordance with applicable state and federal regulations. Equipment used on the site must be operated and maintained properly to prevent discharge of fluids. b.) Equipment, vehicle, and other wash waters shall not be treated in a sediment basin or sediment trap. Alternative controls should be provided such that there is no discharge of soaps, solvents, or detergents. 3. Waste Materials a.) Building material and land clearing waste shall be disposed of in accordance with North Carolina General Statutes, Chapter 130A, Article 9 — Solid Waste Management, and rules governing the disposal of solid waste (15A NCAC 13B). Areas dedicated for managing building material and land clearing waste shall be at least 50 feet away from storm drain inlets and surface waters unless it can be shown that no other alternatives are reasonably available. b.) Paint and other liquid building material waste shall not be dumped into storm drains. It is recommended to locate paint washouts at least 50 away from storm drain inlets unless there is no alternative. Other options are to install lined washouts to use portable, removable bags or bins. c.) Hazardous or toxic waste shall be managed in accordance with the federal Resource Conservation and Recovery Act (RCRA) and NC Hazardous Waste Rules at 15A NCAC, Subchapter 13A. 14 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCG010000 d.) Litter and sanitary waste shall be managed in a manner to prevent it from entering waters and shall be disposed of offsite. 4. Herbicide, Pesticide, and Rodenticides Herbicide, pesticide, and rodenticides shall be stored and applied in accordance with the Federal Insecticide, Fungicide, and Rodenticide Act and label restrictions. 5. Concrete Materials Concrete materials onsite, including excess concrete, shall be controlled and managed toa void contact with surface waters, wetlands or buffers. No concrete or cement slurry shall be discharged from the site. (Note that discharges from onsite concrete plants require coverage under a separate NPDES permit — NCG140000.) Any hardened concrete residue will be disposed of, or recycled on site, in accordance with local and state solid waste regulations. 6. Earthen Material Stock Piles Earthen materials stock piles shall be located at least 50 feet away from storm drain inlets and surface waters unless no other alternatives are reasonably available. 2.4 Operation and Maintenance 1. Modifications to the E&SC Plan Modifications to the approved E&SC plan that require changes to the E&SC measure designs, the drainage areas, or the disturbed areas draining to the E&SC measures shall be approved by the E&SC plan authority. Deviations from the approved E&SC plan, or approved revised E&SC plan shall consititute a violation of this permit unless the deviation is to correct an emergency situation where sediment is being discharged off the site. The E&SC plan authority may allow deviations from the E&SC plan on a case -by -case basis if the deviations are minor adjustments to address minor deficiencies. A minor adjustment shall be the addition of E&SC measures (e.g., silt fence, inlet protection, check dams, rolled erosion control practices, etc.), or the relocation of E&SC measures that would improve the overall stormwater management and sediment control onsite. Minor adjustments shall be noted on the approved E&SC plan and maintained at the job site. 2. Operation and Maintenance The permittee shall install and maintain all temporary and permanent E&SC measures as required by this permit and the approved E&SC plan. 3. Corrective Actions If self -inspections required by this permit identify a need for maintenance of control measures, modifications or additions to control measures, or corrective actions to control sediment or other pollutants, these actions shall be performed as soon as possible considering adverse weather and site conditions. 15 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 4. Draw Down of Sediment Basins for Maintenance or Close out Sediment basins and traps that receive runoff from drainage areas of one acre or more shall use outlet structures that withdraw water from the surface when these devices need to be drawn down for maintenance or close out unless this is infeasible. The circumstances in which it is not feasible to withdraw water from the surface shall be rare (for example, times with extended cold weather). Non -surface withdrawals from sediment basins shall be allowed only when all of the following criteria have been met: a.) The E&SC Plan authority has been provided with documentation for the non - surface withdrawal and the specific time periods or conditions in which it will occur. The non -surface withdrawal shall not commence until the E&SC plan authority has approved these items, b.) The non -surface withdrawal has been reported as an anticipated bypass in accordance with Part III, Section C, Item (2)(c) and (d) of this permit, c.) Dewatering discharges are treated with controls to minimize discharges of pollutants from stormwater that is removed from the sediment basin. Examples of appropriate controls include properly sited, designed and maintained dewatering tanks, weir tanks and filtration systems, d.) Vegetated, upland areas of the sites or a property designed stone pad is used to the extent feasible at the outlet of the dewatering treatment devices described in Item (c) above, e.) Velocity dissipation devices such as check dams, sediment traps, and riprap are provided at the discharge points of all dewatering devices, and £) Sediment removed from dewatering treatment devices described in Item (c) above is disposed of in a mariner that does not cause deposition of sediment into waters of the United States. 5. Bypass of E&SC Measures Diversions of stormwater from E&SC measures when the design storm has not been exceeded are not allowed. Bypass of E&SC measures shall be reported in accordance with Part III, Section C, Item (2)(c) and (d) of this permit. 6. Unavoidable Bypass for Public Safety A bypass may be allowed by the Director if the Director determines that all of the following conditions were met: a.) The bypass is unavoidable to prevent loss of life, personal injury or severe property damage, b.) There were no feasible alternatives to the bypass, such as the use of auxillary control facilities, retention of stormwater or maintenance during normal periods of equipment downtime or dry weather. This condition is not satisfied if adequate back up controls should have been installed in the exercise of reasonable engineering judgement to prevent a bypass which occurred during normal periods of equipment downtime or preventative maintenance, and 16 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 c.) The permittee submitted a notice of the bypass per the record keeping requirements in Part I1I, Section C, Item (2) (c) and (d) of this permit. 7. Upset of E&SC Measures Diversions of stormwater from E&SC measures may be considered as an upset if the permittee can demonstrate that all of the following conditions have been met. In any enforcement proceeding, the permittee seeking to establish the occurrence of an upset has the burden of proof. a.) The permittee submitted notice of the upset as required in this general permit and identifies the cause(s) of the upset. b.) The permittee demonstrates that the upset was not caused by operational error, improperly designed treatment or control facilities, lack of preventative maintenance, or careless or improper operation. c.) The permittee agrees to take remedial measures if necessary. 17 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 Section 3 Compliance Requirements 3.1 SWPPP A vaila bility A copy of the On -Site SWPPP (OS-SWPPP) shall be provided by kept onsite until the project is closed out 3.2 Pre -Construction Conferences Prior to beginning construction, City of High Point shall be notified (minimum of 48 hours) and a pre -construction meeting must take place onsite. The following must be in attendance: ® Permittee or representative (having signature authority) ® SWPPP preparer (Civil Engineer) • 3rd Party inspector ® Contractor and necessary sub -contractors. Attendance must be recorded per the form provided in appendix G and maintained within the on -site SWPPP. 3.3 Inspection Requirements Construction site inspections are to be conducted on a routine basis and must include all areas disturbed by construction activity, including perimeter BMP's and areas used for storage of materials that are exposed to precipitation. Due to the size of this project, site inspections are required to be conducted at a minimum of a least once every calendar week and must be conducted until final stabilization is reached on all areas for the construction site. An inspection is recommended within 24 hours of end of a storm event of 0.5 inches or greater. Inspections must be performed by qualified personnel per City of High Point requirements. Copies of the inspection must be distributed to the permittee, engineering, construction administrator, contractor(s) and a copy must be provided in the on -site SWPPP. Rainfall log (indicated in appendix F) shall be completed on a daily basis by the onsite contractor. This log shall be maintained in the on -site SWPPP. A record of each inspection and of any action items taken must be retained as part of the On -Site SWPPP for at least three years from the date that permit coverage expires or is terminated. 18 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO10000 3.4 Maintenance Requirements A. Construction Maintenance: All BMP's and other protective measures identified in the OS-SWPPP must be maintained in effective operating condition. If site inspections identify BMP's are not operating effectively, maintenance must be performed within seven (7) calendar days, before the next inspection, or as reasonably possible, and before the next storm event. If periodic inspections indicate that a BMP has been used inappropriately, or incorrectly, the permittee must address the necessary replacement or modification required to correct the BMP within a time frame of 48 hours of identification. If existing BMP's need to be modified or if additional BMP's are necessary to comply with the requirements of this permit, implementation must be completed prior to the next storm event. If the contractor is unable to implement the BMP prior to the next storm event, the contractor shall provide documentation in the On -Site SWPPP. Sediment from sediment traps/basins shall be removed once sediment accumulates `/2 of the height of the clean -out stake. Sediment shall be disposed of onsite (within the limits of disturbance) or off site on an existing approved site (currently under permit coverage). Sediment collected by Silt Fence, or another sediment control measure, must be removed when the deposited sediment reaches 1 /3 of the height of the above ground portion of these BMP's or before it reaches a lower height based on the manufacturer's specifications. B. Permanent Maintenance: Permanent Storm Water management structures must be routinely maintained to operate per design. A copy of the permanent maintenance agreement is included in this SWPPP. 3.5 Record Keeping The On -Site SWPPP (OS-SWPPP) is a derivative of the Comprehensive SWPPP (C- SWPPP). The OS-SWPPP shall be provided to the contractor at the pre -construction meeting to remain onsite. The pertinent information regarding Self -Inspection, Recordkeeping and Reporting can be found on Sheet C500 of the construction documents. Contents of the OS-SWPPP: Coverage Approval letter/ local Approvals/Contractor Certifications/Recording Keeping/Logs 19 All About Plumbing - Building Addition Storm water Pollution Prevention Plan Permit No. NCGO 10000 3.6 Final Stabilization Project is not deemed complete until stabilization is achieved. Refer to plans for further information. Pond as-builts shall be furnished by the owner to the engineer for evaluation. The as- builts shall be prepared by a North Carolina Licensed Land Surveyor. It must include the following information: ® Grades/Contours/depths of pond(s) ® Elevations and dimension of all outlet structures, including o Pipe and orifice inverts and diameters o Weir elevations and dimensions o Riser dimensions and elevations o Emergency spillway dimensions and elevations (top of rock if applicable) o Locations and inverts for all pipes discharging into pond ® Upon receipt and approval of as-builts, the engineer shall prepare necessary documentation and submit close-out documentation to City of High Point for review and approval. 20 All About Plumbing - Building Addition Stormwaler Pollution Prevention Plan Permit No. NCGO 10000 Appendix A Site Maps L,ocatimis Map Site Maps Topographic Map Soils Maps rloodway Map All About Plumbing- Building Addition :nderson County, NC Tax Parcel Report Wednesday, April 27, 202: REID: Listed to: Mailing Address: Mailing City, State, Zip: Physical Address: Deed: Date Recorded: Revenue Stamps: County Zoning: Property Description Map Sheet: Assessed Acreage: Building Value: Land Value: Value To Be Billed: North Carolina Senate District VVHRwavU: IRIO W lvVI MUURV"I Parcel Information 10001068 ALL ABOUT PLUMBING INC. P.O. BOX 1041 HENDERSONVILLE, NC 28793 5521 OLD HAYWOOD RD 003058/00553 2017-05-26 16:19:00.0 300 Clues MINOR SUBDIVISION 3.0 AC L01 9632.00 3.00000000 $227,900.00 $147,600.00 $375,500.00 48 Pin: Neighborhood: Township: Municipality: Tax District: Plat: Elementary School District: Middle School District: High School District: Soll: Voting Precinct: Commissioner District Agricultural District North Carolina House District U.S. House District Flood Zone: 9632570722 TOWN OF MILLS RIVER (D) Mills River MILLS RIVER MILLS RIVER TOWN SLD 10634 MARLOW RUGBY MIDDLE WEST HIGH Hayesville loam, 7 to 15 percent slopes Mills River North 3 None Found 117 11 Zone X, Not Shaded (Areas outside of the floodplaln) THIS IS NOT A SURVEY. Henderson County Geographic Information Systems (GIS) All Infomtatlon or data provided, whether subscribed, purchased or othanvlse distributed, whether In hard copy or digital 200 North Grove Street media, shall be at the userAC"'s own risk. Henderson County makes no warranties or guaranloos, Including Ilia warranties of Hendersonville, NC 20702 merchantability or of fitness for a padlcular purpose. Map doln Is not appropriate for, and Is not to be used os, In geodollo, P: (020) 666.5124 legal, or onginoering base system. The dole Is not Intended as o substitute for surveyed locations such as can be determined F: (020) 690.5122 by a registered Publlo Land Surveyor, and dons not meet Ilia minimum accuracy standards of o Land Information SyslomlGoographlc Information System Survey In North Caroline (21 NCAC 66.1600). mderson County, NC I ax Parcel Keport vvednesday, April xt, zuc, REID: Listed to: Mailing Address: Mailing City, State, Zip: Physical Address: Deed: Date Recorded: Revenue Stamps: County Zoning: Property Description: Map Sheet: Assessed Acreage: Building Value: Land Value: Value To Be Billed: North Carolina Senate District Parcel Information 10001068 ALL ABOUT PLUMBING INC. P.O. BOX 1041 HENDERSONVILLE. NC 28793 5521 OLD HAYWOOD RD 003058/00553 2017-05-26 16:19:00.0 300 Cities MINOR SUBDIVISION 3.0 AC L01 9632.00 3.00000000 $227,900.00 $147,600.00 $375,500.00 48 Pin: Neighborhood: Township: Municipality: Tax District: Plat: Elementary School District: Middle School District. High School District: Soil: Voting Precinct: Commissioner District Agricultural District North Carolina House District U.S. House District Flood zone: 9632570722 TOWN OF MILLS RIVER (D) Mills River MILLS RIVER MILLS RIVER TOWN SLID 10634 MARLOW RUGBY MIDDLE WEST HIGH Hayesville loarn, 7 to 15 percent slopes Mills River Nortlt 3 None Found 117 11 Zone X, Not Shaded (Areas outside of the floodplaln) THIS IS NOT A SURVEY. Henderson County Geographic Information Systems (GIB) All Information or (late provided, whalhor subscribed, purchased or otherwise distributed, wllotlter In hord copy or digital 200 With Grove Street Hendersonville, NC 20792 media, shall be at the userAC"'s own risk, Henderson County makes no warranties or guarantees, Including the warranties of merchantability or of fitness for a particular purpose. Map data Is not appropfinto for, and Is not to be used as, a geodetic, P: (020) 698.5124 legal, or engineering base system. The dais Is not Intended as a substitute for surveyed locations such as can be determined F: (020) 690.5122 by a registered Public Land Surveyor, and does not meet tho minimum accuracy standards of a Land Information System/Geographic Information System Survey In North Carolina (21 NCAC 66.1600). • , / �\ ' '� �� sir. d,, i I t . �1 q� 1�i `11 ',il �, '1, ., ' f;' , �•1t `• .. 1 ,y,� BI; �`'` `I! 1 ', •� •, it 1,, ,, 'a�,.'t l.'; 1•';�1�i .' ,1'.i,•j.rVw � L:�• r t•; •.: k'r. i t `.�' , � 1 �., '. J.., � 1 r I 1 , � J� Aj 1 . V t"G-fir I ,.! ... 1, �j� 1%' � ' �•!. ,.1 .. �`- ,. •�i Q. , •� ''fit ,�j 1; ' , 1, r 1� . 1,• �� ',1' , AL :�, , ,,,• ' ,(/I1p_11`` '/b•� !y�7 1A .,iFi 'r 1,r . '; , I 1 , , ,I 11�117/7•y'!11{'!�I'%�IY• 1 1 ,r,. '1, I',1', ,' , � it f'1,''�tr��'i'':i"'i'�i �: i�ifal'1ij..''fi�l•j' ',rnr,l ,. � ., � l 7� Vet �.,, ;;il , • I. ., i,'i' 11 ..till.,.' •,',i�f; `n,a,�.„,.(,: ,. „ r i.•ij,J.'fl:`'. .j,:'�' , i:.•.:�,'. r'�; Lil;;l,,,',`.iC'�tiri5{,ttii 'ijr-G•,�;.'r.• , ,' ''/i 'rl �j,� '' :.:�.'�.. �.',j,�J:�I, i'.,`,If.,• �, 1.,, .t,i/ r jL; ..f` 1'�I,i�,• , O. .� i ,a',,i' ' f( !ir �r , f t!!, fjta dF � t,t ! C)'d Ctf4. 1 ' ' ' 1;•; �'•!'I C `' 7''!• r, /Ir,� , / �`! 1 I i }it, �, Jl I!{11 4 1 % c•i,4�''., 1. ,1z. , .l`tfl, �, u..hti`''.1;'rjr, +\iflw '4iil'•'((.:.f, .ti�; i. .'r.,u 1� �:' , 41:111 LUC, II t.%,4 I Al b� i �rrlf llrr I � �f;,it, �f , II� Fnr,rrinu uRtunl• gn leIt i ►c � i rj I� 1, y ��i U q I i !L ■ S t r I Stream Information: Lt�:uoNdBu Itn ' ej 3, Stream Index- 6.58 IiisTrw t.N Stream Nome: McDowell CreeY. Description: From source to French Broad River t ' Classification: C Date of Class.: March 3'1,1996 What does this Class. More into mean? �y River Basin: French Broad II 11 r Zoom to too v" :J jOCE R"A YDA LN oy 0,41 I'a ce- J, C: o 5.- I o>� ON a -a o b"MXV, H - (I 10,.,\� � . - - � boo � , � �� ISV 1 1 0 " I q *Lq im all", c , Nvrv) c; �� q ( - , f z Mlime M c 0 cu U 0 z c C) 0 U c 0 `m 'O C N 0 C7 0 U O O 'D T Z M.U.K <70 z n p� bS WOM o00ime 0101Z0e OLMC Ocr= 2 h 000= M.a,K DZ0 N T Z U) 'o g Z ) > 0 �0 N 0 920 3 c o dl r9 z N o OI 00 X O. p a �S 83 u r d) m U, nn O� 0 Gj O O C a ��p777 z z"0 z p� b5 ro c 0 ro U .c 0 0 z c 0 0 U c 0 P, d) d) v c a) _ 0 C7 0 U 0 0 T O Q O a C� z W W J a, 4� N� t = Z o .-o E v F ro � o c °.E E I °� � � T' o= � C 5 '� a ro N z= °' m _ U N 0 N A N p=• 'ra N 7 N E T ro (N .ro0 O N N N co M D. C ro N c.rc ++ ^ a N 0 -0adibro c N Z � ZON z o O E�> N W ro w o a N .; N 3 'k L u! �- .O C f'Lq + C C n. c ,No o aroi u ro°� o w 3 U� a O N° ORE a� ��vc on oa a U! v o a T aEiroEa�c N o .ro a s v ) O 'y 0 A N n o ai v CL J� 0 NroN o c o v roj Z °o N v�i °�v o O N � A Z T E V m cd N O N N (V N d)ro N N o m N C N E. Z U N N 7 d) SO E' �o O a T= d) �=m ,�U� s 3 cNU Ecroo� ve >,Q m ..` =o m a� 0ca)E mE w N o= ro Euv o o a) W t r f a) ad>) Z Q 0. o Eo ro v 0 a o 70 a QCl N ro N N =A O O N O 0.M ro N ro 0 'ii1 A UIw aTi _ O= —� 'O LO NN (0 v E m'¢g_' n. E (n � U U 2 R '6 Q N ,c a- IE O (4 (Q (n .- p Q N m N c U r R 12 � a ro w o m N r y a a `o m () e o z p a = s c © 0 ® © v ) C �I• � l � �l m ro \ � F- 00 a� m a .'o E ro }Q u3 c oc c CZ,c Q a 2 w C m U a Z G ro U Z rn m Q Qdi d a0l j o i {' a©o r_ v �o❑❑❑❑❑❑❑❑ J a "IFY No �N m "' a ro z ��r I iydrologic Soil Group --Henderson County, Notih Carolina Hydrologic Soil Group Map unit symbol Map unit name Rating Ames In AOI Percent of AOI BaB BaC - - Bradson gravelly loam, 2 to 7 percent slopes Bradson gravelly loam, 7 to 15 percent slopes B B 7.2 2.2 40,5% 12.4% DeB Delanco (dillard) loam, 2 to 7 percent slopes C -- 2.7 HYC Hayesville loam, 7 to 15 percent slopes C I l 5.6 31.7% Totals for Area of Interest 17.8 I 100.0% Description Hydrologic soil groups are based on estimates of runoff potential. Soils are assigned to one of four groups according to the rate of water infiltration when the soils are not protected by vegetation, are thoroughly wet, and receive precipitation from long -duration storms, The soils in the United States are assigned to four groups (A, B, C, and D) and three dual classes (A/D, B/D, and CID), The groups are defined as follows; Group A. Soils having a high infiltration rate (low runoff potential) when thoroughly wet, These consist mainly of deep, well drained to excessively drained sands or gravelly sands, These soils have a high rate of water transmission, Group B. Soils having a moderate infiltration rate when thoroughly wet. These consist chiefly of moderately deep or deep, moderately well drained or well drained soils that have moderately fine texture to moderately coarse texture. These soils have a moderate rate of water transmission. Group C. Soils having a slow infiltration rate when thoroughly wet. These consist chiefly of soils having a layer that impedes the downward movement of water or soils of moderately fine texture or fine texture. These soils have a slow rate of water transmission. Group D. Soils having a very slow infiltration rate (high runoff potential) when thoroughly wet, These consist chiefly of clays that have a high shrink -swell potential, soils that have a high water table, soils that have a claypan or clay layer at or near the surface, and soils that are shallow over nearly impervious material. These soils have a very slow rate of water transmission, If a soil is assigned to a dual hydrologic group (AID, B/D, or C/D), the first letter is for drained areas and the second Is for undrained areas. Only the soils that in their natural condition are in group D are assigned to dual classes, USDA! Natural Resources Web Soil Survey 5/18/2022 Conservation Servico National Cooperative Soil Survey Page 3 of 4 Hydrologic Soil Group —Henderson Counly, North Carolina Rating Options Aggregation Method: Dominant Condition Component Percent Cutoff- None Specified Tie -break Rule: Higher uS�U Natural Resources Web Soil Survey 5/18/2022 Conservation Service National Cooperative Soil Survey page 4 of 4 nA v bn N c N u N 4 n>L° m m E C �_ E v a v N✓ o �{ (� Iyrat E v C>� Ei'v GN N ,_ .t' Y J 2 N I-L YY N C wO G/ y� dj 0 0 �3>+N < o v u) r m S' oNm ; c N° � d a0 ccv a� N °o _ v w ncioc! �3N E�cvOrn oEv r v u °� � m n s :,l' o > i= .a I!y v a y v E ,°k o -.9 -5 �� m '� rc c> m°c o2 I°y c v v N ri,a a1 v a nc na °00��a o°❑ � 0 8 v p a '� roo o n >.c ro w' ❑ Q cLNi c o � € e 3 G7 Yi �° n � v �i Q ° nN ❑NyEa oZE u a 4) u a y a v v ❑ c E v v E ❑ �$ aoo $Z o E `a3 : ° o u 2� am u Q �n o N o�� .a'a o��oc oS �`o � c 0.� c o c v $ v o o vm•>m�Ni z Y� fi .9 do o t� o t`s u) +� ? o v C] v i j ~ o m ,1i F P 0 19 Q. n v O ro .' � A Ln 100 o `o 'a N 0 m ❑ °um a o\°\° N v i 3 0 0 gy m�// Y p o 4) o ryry tin N N.o,a> o-0 3 v ��I N N 41 N N �j N N N 0 Vr 4= K 4 ° .AJ 0 h MG C ,N° ° N O S '0 ❑ ng v N w v u v> v v ° t o o N 0 E 'r o o nA 0 c y ,c a i a oovN u.0Q°�Q Q Q c) c�?iUm 7 Uax O z o °—yy° on .0.�NE' ra° �+ 0 r N N EEp N N C N C = 1. �'0 y R C N �_ �, U N\ ,o v Q (Gp I1::11A �a°o 3=3�v c,3j`IcEuvv >aEyEW CO ❑ tdn - aN�v zoo �L^ nACna�v zi 0W 0� p� Ja Wa 0�ETn O;iCIzN E�my a. � (D0 0°°° a N c v a rx a aS� QO W c7a 0. CN� v� (Oq: y v n, � n w ix w o F E)N N 3 a �a ❑ N Ny u°iz of z 9, D D D ' D 0 01 0 (V 0 0 0 0 C 0 0 LO 0 LO N 0 StormWater Pollution Prevention Plan Permit No, NCG010000 Appendix B Drainage Maps Crass Swale Basin Map Sediment 'Trapping Basin Map All About Plumbing - Building Addition I elf I CARRIE LOU VIILSON PIN 9632-46-6321 DB 349 PG 4 i1 REMNANT ACREAGE: ±23.6 ACRES LL n�Mo P®M/CM �i µhp 6tEY. 1003.24 � CC C MAR/Cm/C7 ELM.A 1010.61 L / GRASS SWALE #1 ° U) ir DRAINAGE BASIN a Q / 0.82 ACRES � m WEIG TED C: 0.77 x 04' W / 1 1 �� Mm o w J CY) � Q 3: CIO "ULM iC04.62 I I I I / ��.�� \ U) ro GRASS SWALE o DRAINAGE BASIN (OWMAUM TO\ 11 \ I \ I 1 \ \ \ \ I I I( z 0.27 ACRES \ \ \ I \ \ \ \ 1 I \IREII / INVESWENTS LC PIN 632 57-5740M of , VVEIGHTED C: 0.77 \ I I I I I I \ I \ / / I I DB 1290 PG 52 W • M. \I I� \ \ I \ I // / // // / / / r\ AARON k MEGAN BLACKAIOR caulm PIN 9632-47-4356- DS 1455 PG 353 m I • 30.48' RITEWAY EXPRESS INC PIN 9632-47-9133 MANIC R R DB 912 PG 467 PIN 9632-57-457-4257 J IDB 862 PG 462 J I I I 0' 60' 120' 180' GRAPHIC SCALE: 1" = 60'-0" I elf I CARRIE LOU V'ALSON PIN 9632-40-0321 2-7DD 349 PG 4 REMNANT ACREAGE: ±23.6 ACRES nrna (' n nevAn/cAr MI�01w `.' � E EY. 1009.24 ccr�r+ RMA MENt 1 -� JI- CAP F1EY. 010.61 l / �a _z 1125 LF OF SILT FENCE o° CL DOUBLE ROW SEDIMENT / �� TRAPPING BASIN / / I �""PAKM o SILT FENCE I \ / I I I / (DISTURBED) 0.57 ACRES SCS CN = 86.00 I I Lu // \ \ i 1 W / I RBI INVESTMENTS LLC Z PIN 9632-57-5740 03 1290 PG 52 M 1 1 1 1 2E • / � f I I I I / / / / AARON & MEGAN DLACI<AIOR con++rn / PIN 9632-47-4356 OD 1455 PG 353 I • 30.40' RITEWAY EXPRESS INC PIN 9632-47-9133 PIN 9 R -57-4LAFEVER DD 912 PG 467 PIN 9632-57-4257 DD 062 PG 402 I � I 0' 60' 120' 160' GRAPHIC SCALE: 1" = 60'-0" Stormvaater Pollution Prevention Plan Permit No. NCG010000 Appendix C Additional Approvals/Certifications USACF's Jurisdictional Detertniciations (blot applicable) Jurisdictional Floodplaiti Management Certifications (Not applicable) Other Local Ordinance Certifications and Approvals (to be provided upon receipt) All About Plumbing - Building Addition Storm%vater Pollution Prevention Plan Permit No. NCG010000 Appendix D Engineering Reports Sediment Trapping Calculations Grass Swale Calculations Time of Concentration Calculations All About Plumbing - Building Addition NOAA Atlas 14, Volume 2, Version 3 µ Location (tame: Mills River, North Carolina, USAA &� �)� Latitude: 35.42220, Longitude:-82,5761mw- t l ,, Elevation: 2185.19 ftAA ' source: ESRI Maps Mp " source: USGS POINT PRECIPITATION FREQUENCY ESTIMATES G.M, Bonnln, D. Marlin, 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 PpS-based point precipitation frequency estimates with 90% confidence intervals (in inches), Average recurrence interval (years) Duration ��f-- ��-i�� 1 l 2 5 10 25 50_I 100 200 500 1000 5•mlll 0.331.040II 0.39 -0486 0,473-0 582 0,631--0 653 0,603.0.748 (0.650.0620 0.713-0694 0.766 0 970 0, 311107 0.88 -1.16 10-min 0.520652) (0.633.07 77) 0.75 -0 932 0. 401a05 0.96 08.19 (1,0511 931) (1.13 1142) 1.21 1.54 1.31 1.70 1.39 1.02 0 734 0.879 1.06 1,20 1.37 1.50 1.62 1.75 1.91 2,03 15-min (0,662.0.016) (0.795-0.976) (0.957-1.10) 11 (1.07-1.32) 1,22-1.51) (133.1,65) (1.43.1.80) 1 (1,53A.94) (1.65-2.13) (1.74-2.28) 30-mirt 101 1,22 1.51 1.73 2.02 2.25 2.48 1 2.72 3.04 3.29 (0.907-1.12) 1.10-1.35) 1 (1.36-1.60) (1.56-1.92) (1.81-2.24) 1 (2.00-2.49) 2.19-2.75) 2.38-3.02 2.63-3.40) 2.82-3.70) 3.81 60-min 1,131.39 1.301269 1.74 2315 2, 3 2549 2. 0 2. 8 2. 1 3537) 3.02-3.79 3.34 424) 3.70 4687 4.12 5.40) 1.47 1.79 2,25 2.63 3,15 3,57 4.02 4.50 5,16 5.70 2-ftr (1.32-1.63 (1.61-1.90) (2.02-2.49) (2.35-2.90) (2.00-3.49) 1 (3.16-3.96) 1 (3.53.4.46) 1 (3,91-4.99) (4.43-5.76) (4.05.6.40) 3-ht 1,5fl 1.90 2.38 2.78 3.36 3.84 4.35 4,90 5.70 6,36 (1.43.1.76) (1.72-2.12) JI (2.15.2.65) (2.49.3,09) 2.98.3.73) (3.394.26) (3.80.4.84) 4.24-5.46) 4.85.6.40 (5.35-7.17 6-itr 1.98 2.37 2.92 1 3.39 1 4.07 4.65 5.28 5.96 1 6.96 1 7.79 1.II1-2.19 (2.16-2.60) [ (2.66.3.20) 11 (3.073.72) 1 (3.66.4.47) (4.15-5.11) 4,67-5,81) (5.21.6.58) (5.98-7.72) 6.61.8.70) 12-hY 2 50 2,98 3,66 4.20 4.95 5.57 6,20 6.87 7.79 8.52 (2.30.2.73)1 (2.74-3.26) 1 (3.36.3.99) 1 (3.05.4.60) 1 (4.62-5.41) (5.06.6.09) 1 (6,60.6.79) 1 (6.15-7.64) (6.90.8.62) (7.47.9.49) 24-hY 2 99 3,58 4.40 1 5.06 5.96 6.69 11 7.45 1 8.24 1 9.34 10.2 2.77.3.23) (3.32-3.88) 1 (4,07-4.77) 1 (4.67-5.47) 1 (5.49-6.44) 1 (6.14-7,23) 6.80.0.04 (7,40-8.09) l(0.40.10.1) (9.12-11.1) 2•day 3.32 3682 4 3.95 67 4, 1-5.55 5.A 96 34 6,40 7,42 7.17-8.30 7,89.9.22 8,64 10.2 9.66-11.5 10 5. 2.6 3-day 3,80 4.- 5.46 6.21 7.22 0,02 8.85 9.69 10.8 11.8 (3.65.4.07 4.23.4.05) (5.10.5.85) 5.70.6.64) (6.70-7.72) 1 (7.43.8.69) 8,16.9.49 (8.89-10.4) (9.80-11.7) 10.7-12.7) 4-day 4,04 4.111 5,76 6.51 7.52 8.32 9,13 9.94 11.0 11.9 (3.70.4.31) (4.50.5.13) (5.38.6.15) (6.00.6.95) (7.00-0.03) (7.72 0.00) (8.43.9.76) (9.15-10.6) (10.1-11.9) (10.9.12.9) P•day7-4772 5.61 6.72 7,61 8.fl1 9.77 10.7 11.7 13.1 14.2 4.43.5.05) 5.26.6.00) 6,30-7.19 7.12-0.13 8.21-9.41 9.08-10.4 9.95.11.5 10.8-12.6 12.0-14,11(12.9-16.31. 2.9 10-day 5.2 5275 (6,05.6.81 7.18-8.07 8.06-9.07 (9.2410,4 10 2-1.5 11 11 2.6 12,10-13.7 13,12-15,3 14 1516.5 20-day 10,1 11.1 12.5 13.6 14,6 15,7 17.0 17,9 [;MU%1j(9.53.10.6) (10.5-11.8) (11.9-13.2) (12.8-14.4) (13.8.15.5) (14.7-16.6) (15.9.18.0) (16.7-19.1) 30-day 9 03 10.6 12.1 13.3 14.7 15.8 16.fl 17.619,0 19.fl 8.50.9.51 10.1-11,2 11.5-12.8) (12.6-14.0) (13.9-15.5) (15.0-16.6 (16.9-17.7 16.7-18.7 17.8-20.1 (18.6-21.0) 45-day 11.02.1 12.i8-14.1 (14.415,9 (156617,2) (17.3.4 1.410-10.0 (18,10-19.9 (10.9.0.9) 1 (19.7021,9) 20.71 3,0 (213223.0) 60-day (131113 4.6) (1513-16.9 171II 0,9 10.4� 0.3 199�22.0 21A23.2 2193243 (22.7� 5.2) 23.7526,4 24.4527.2 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 (lie lower bound) is 6%, Estimates at upper bounds are not checked against probable maximum precipitation (PIMP) estimates and may be higher than currently valid PMP values, Please refer to NOAA Atlas 14 document for more Information. Ddun LU rvH PF graphical NOAA Atlas 14, Volume 2, Version 3 „ Location name: Mills Rivet', North Carolina, USA" &" �)4 j Latitude: 35.42221, Longitude: •82,5751° Elevation: 2185,19 ft"" t'=� P ' source: ESRI Maps " source: USGS POINT PRECIPITATION FREQUENCY ESTIMATES G,M, Bonnin, D. Marlin, B. Lin, T. Parzybok, M.Yekla, 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/hour)1 Average recurrence Interval (years) Duration 1 2 5 10 25 50 100 200 �� 500 1000 5 tnln 6,370904 (7.2-18.98) 7. 0 9004 8.5G10.7 9.19-11.6) 9.97- 2.9 10.6-13.9 3.97.4090) (4.74?83 5, 0 G990 066 11 8.33 10.9 10•tnin 3,17-3.91 3. 0 45. 4.6405.69 5. 9G6.27 5.7 7?16 6. 97�83 (6.8078.63) 7.99022 7.80 0.2 15-min 2 94 3,52 (2.G5-3.2G) (3.18.3.90) 2 01 2.43 4..2 4.7fl 5.4G 5,98 6,49 6.99 (3.03.4,72) (4.29-5.29) (4.87 6.04) (G.30.6.G1) (5.73-7.18) (6.12-7.76) 3.02 3.46 4.05 4.50 4.97 5,44 7.G4 8.13 (6.62-8.fi3) (6.97 9.14) 6.08 6.5fl 30•min (1.81-2.24) 2.20-2.70) 1.25 1.52 (2.72-3.35) 11 (3.11-3.83) 11 (3.61-4.40) 1 (4.00.4.98 (4,39-5.50) 11 (4.77-6.04) 1.93 2.25 2.09 3.05 3.42 3.81 5.26.6.79) 6.64-7.40 4.36 4,80 60-min 1.13.1.39 1.30.1.G9) 1.74.2.15 2.03 2.49) 2,40-2.90 2.71-3.37 3.02-3.79 3.34-4.24 3.78.4.87 4.12-5.40 2ltr 0.736 O.fl93 1.13 1.31 1.57 1.79 2.01 2.25 (1.404.74) 1.58-1.90) (1.76.2.23) 1.96-2.60 2.58 2.85 (2.21-2.88 2.42-3.20 (0.662-0.815) (0.804.0,980 (1.01-1.25) (1.18-105) 3-hl' 0,4750687 0.57 .0.705) 0.715.0082) 0, 301..03) 0.994-1.24 (1.131.42 (1.271561 (1.416.82) (1.6292.13) (1.70-12.39) 0,331 0.395 0.487 0.566 0,680 11 0,777 0.802 0.996 1.16 1.30 1 (1,10-1.45 6•hr (0.303.0,3G5) (0.360.0.434) 0.444-0.535) (0.513.0.621) (0.612-0.747) 0.694.0.853) (0.779-0.971) (0.870-1.10) (0.990.1.29) EF1 0 208 (0.191-0.227) 0125 0,24fl (0.228.0,270) 0.149 0.304 (0.279.0.331) 0,183 0.349 0,411 (0.320.0.380) (0.375-0.449) 0,211 0,248 0.463 (0.420.0.605) 0.279 0.515 0.570 (0.465.0.664) (0.611-O.G26) 0.310 0.343 0.646 0.707 (0.573.0.715) (0.620.0.788) 0.309 0.426 24-hr (0,1 .12535 0.1 .149G2) 0.170.0.199) (0.195-0.228) (0.229.0.260 (0.256-0.301) 0.283-0.335) (0.312.0.371) (0.350.0.421) 0.380-0,461 0.144 0.161 0.179. 0.197 0.222 0.242 2-day 0.074 0.088 0.108 0.100.0.11G) 0.123 0.114-0.132 0.133-0.155 14 0.9-0.173 0.164-0.192) 0.180.0.212 (0.201.0.239 0.218-0.262 (0.069.0.080)I[0.082-0.095 3•day 057 0059.0 067) (0.07 -0 081 (0080 0 092 0093.0.0107) (0.103.0119 (0.1/3.0132 (0.124 0144) (0.137.0162) 0.140-0176 (0049.0 0.164 0.115 0.1 4-day 0.042 0.050 O.OGO 0.0G8 0.078 O.Ofl7 0,095 24 (0.095-0.111) (0.105.0.124) (0.113-0.134) (0.039.0.045) (0.047-0.053) (0.056.O.OG4) (0.063-0.072) (0.073-0.084) (0.000-0.093) (0.088-0.102) 7-day 0026.0 030 (00310 036 0033 37.0 043 0042-0 048 0049.0 056 0054-0 062) 0059.0 060 0084.0 075 (007 -0 084 007 70 091 10•day 002 -0 024 0.025.0 020 0,030.0 034 003 -0 038 0038.0 043 0.042.0 048 0046.0 053 0050.0 057 0055 0 064 0059.0 069 0,021 6.623 0.626 0.028 0.030 0.033 0.035 0.037 20•day 0.015 0.018 (0.01G•0.01G) (0.017.0.019)1(0.020.0.022) (0.022-0.025) (0.025.0.028) (0,027-0.030) 0.029.0.032) (0.031 0.035) (0.033.0.030) (0.035-0.040) 30•day 0 013 (0.014 0 015) 0.016.0 018 0017-0 019 0.019.0 022 (00210 023) 0022.0 025) 0023.0 026) (0.02G 0 028) 0026.0 029 (0012 0.014 0.015 0.017 0.018 0.018 0.019 0,020 0.021 0.011 0.012 45•day (0.010.0.011) 0.012-0,013 0.013.0.015) 0.014-0.016) (0.016-0.017) (0.017-0.018) 0.010.0.019) (0.018.0.020) 0,019.0.021 0,020.0.022) 7013 16 0717 18 70 GO•day (0009 0 010 0015 11 0 012) 0012.0 013 0013-0 014) L -0 016 0015.0 018 00-615 15 0 017) 001G-0 018) 001G•0 010 0:1 019 t 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 recurrence will be then upper less than the lower lues. Is Estimates at upper bounds are not y )reater cliecked against probable maximum precipitatie on (PMPestimates antd be higher than currently valid PMP vaor Please refer to NOAA Atlas 14 document for more Information. pack to top- PF graphical SEDCAD 4 for Windows rn int,f 1 aaR _9nn7 D-IA I Cr 11-11 All About Plumbing Sediment Traq Calculation, McCutchen Engineering Filename: Silt Fence Calculations.sM Printed 11-28-2022 SEDCAD 4 for Windows rnnv.•inht 9aan _Onn7 D—.1, I C,N—h Storm Type: NRCS Type II Design Storm: 2 yr - 24 hr Rainfall Depth: 3.580 inches Size (mm) Bradson 1.4000 100.000% 1.0000 89.700% 0.0630 66.000% 0.0440 38,100% 0.0380 36.600% 0.0040 4.200% 0.0030 2.600% 0,0010 0.000% Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SE®CA 4 for Windows �`nn"rinhl loon -,)nn7 D—Io I Crh—h Type Yp Stru (flows Stru # into) # Musk. K Musk. X (hrs) Description Silt Fence #2 ==> End 0.000 0.000 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows !`nnurinhl IaaR _onn7 P-1c I Slhl—h Z Structure Summary: Immediate Total Peak Total Peak Peak Contributing Contributing Discharge Runoff Sediment Sediment Settleable 24VW Area Area Volume (tons) Conc. Conc, ml (ac) (ac) (cfs) (ac-ft) (mg/1) (MI/1) In 1.24 0.10 3.4 44,320 28.99 15.91 #2 0,570 Out 0.570 1.21 0.101 0.1 2,437 0,00 0.00 Filename: Silt Fence CaICUlations.sO Printed 11-28-2022 SE®CAD 4 for Windows rn iv w loon _gnn7 P.,,.[a i clh—h Structure #2 Size (mm) In Out 1.4000 100,000% 100.000% 1.0000 89,700% 100.000% 0.0630 66.000% 100.000% 0.0440 38,100% 100.000% 0.0380 36,600% 100.000% 0.0040 4,200% 100.000% 0.0030 2.600% 66.013% 0.0010 0.000% 0.000% Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDC.AD 4 for Windows (`nnvrirhl idon _9n07 Po 10 I Crhuio L� 6 Structure #2 (Silt Fence) Silt Fence Inputs: Fence Flow Width along Land Slope Tie -back Rate (gpm/sq contour (ft) Height (ft) (0/o) distance (ft) ft) 10.0 250.0 2.5 4.00 62.5 Silt Fence Results: *Sediment Storage: 0.00 ac-ft *No sediment capacity defined Peak Fence Stage: 0.21 ft Peak Water Stage: 0.21 ft Dewater Time: 0.50 days Trap Efficiency: 96.06 Dewatering time is calculated from peak stage to lowest spillway Stage -Capacity -Discharge Table Fence Stage (ft) Water Stage (ft) Area (ac) Capacity (ac-ft) Discharge (cfs) Dewater Time (hrs) 0.00 0.00 0.000 0.000 0.000 Top of Sediment 0.10 0.10 0,014 0.001 0.563 11.95 0.20 0.20 0.029 0.003 1.136 0.21 0.21 0.030 0.003 1.206 0.00 Peak Stage 0.30 0,30 0.043 0.006 1.721 0.40 0.40 0.057 0.011 2.317 0.50 0.50 0.072 0.018 2.921 0.60 0.60 0.086 0.026 3.543 0.70 0.70 0.100 0.035 4,172 0.80 0.80 0.115 0.046 4.813 0.90 0.90 0.129 0.058 5.465 1.00 1.00 0.143 0.071 6.127 1.10 1.10 0.158 0.086 6.801 1.20 1.20 0.172 0.103 7.187 1.30 1.30 0.187 0.121 8.183 1.40 1.40 0.201 0.140 8.890 1.50 1.50 0.215 0.161 9.609 1.60 1.60 0.230 0.183 10.339 1.70 1.70 0.214 0.207 11.080 Filenarne: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows r t„hi 1QQR -')on7 I Qi ,1—h Fence Stage (ft) Water Stage (ft) Area (ac) Capacity (ac-ft) Discharge Dewater Time (cfs) (hrs) 1.80 1.80 0.258 0.232 11.832 1.90 1.90 0.273 0.259 12,595 2,00 2.00 0.287 0,287 13.369 2.10 2.10 0,301 0,316 14.154 2.20 2.20 0.316 0.347 14.951 2.30 2.30 0.330 0.379 15.759 2.40 2.40 0.344 0.413 16.578 2.50 2.50 0,359 0.448 17,408 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows f nnv.W,l 100A _9nn7 P--[l I ¢rhunh I Time of Peak Runoff Stru SWS SWS Area Musk K Curve Conc Musk X UHS Discharge Volume # # (ac) (hrs) (hrs) Number cfs ( ) ac-ft ( ) #2 1 0.570 0,060 0.000 0.000 86.000 TR55 1.24 0.102 0.570 1.24 0,102 /' • r / d„ / I'/Detail: Peak - Peak Sediment Sediment Settleable 24VW Stru SWS K L (ft) S (%) C P PS # Conc. Conc # #Soil (tons) (mg/I) #2 1 0.170 225,00 4.00 1.0000 1.0000 1 3.4 44,320 28.99 15.91 3.4 44,320 28.99 15.91 Filenarne: Silt Fence Calculations.sc4 Printed 11-28-2022 SE®CAD 4 for Windows r—...inhi inna _7nn7 P—,.Io I Q11,11 -h m McCutchen Engineering Filename: Silt Fence Cahllations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows (`nnvrinhl 1QQR.9nn7 P-10 I C�h�niah Storm .Information. Storm Type: NRCS Type II Design Storm: 10 yr - 24 hr Rainfall Depth: 5,060 inches Size (mm) Bradson 1.4000 100.000% 1,0000 89.700% 0.0630 66,000% 0.0440 38.100% 0.0380 36.600% 0.0040 4.200% 0.0030 2.600% 0.0010 0,000% Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCA® 4 for Windows (-n rinhl 9 ann _9nn7 P—Io I Q1111—h Type Yp Stru (flows Stru # into) # Musk. K Musk. X (hrs) Description Silt Fence #2 ==> End 0.000 0.000 Filename: Silt Fence Calculations,sc4 Printed 11-28-2022 SEDCAD 4 for Windows (`— in V,l 4QoA Ann? P—.Io I GGhl—h 4 Immediate Total Peak Total Peak Peak Contributing Contributing Discharge Runoff Sediment Sediment Settleable 24VW Area Area Volume (tons) Conc. Conc, (MI/1) (ac) (ac) (cfs) (ac-ft) (mg/1) (MI/1) In 1.93 0.17 5.7 45,086 29.50 16.38 #2 0.570 Out 0.570 1.87 0.17 1 0.3 3,411 0.21 0,01 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows (`nnvrint,l 1oQR _9nn7 Pmnnlo I C�h�aiah Structure #Z. Size (mm) In Out 1.4000 100.000% 100,000% 1.0000 89.700% 100,000% 0.0630 66.000% 100.000% 0.0440 38.100% 100,000% 0,0380 36.600% 100.000% 0.0040 4,200% 85.269% 0.0030 2,600% 52.786% 0.0010 0.000% 0.000% Filename: Silt Fence Cahllations.sc4 Printed 11-28-2022 SEDCAD 4 For Windows (`_... inhl 9aafl .9nn7 Pa 10 I QIh-h 11 StIvcture #2 (Silt Fence) Silt Fence Inputs: Fence Flow Width along Land Slope Tie -back Rate (gpm/sq contour (ft) Height (ft) N distance (ft) ft) 10.0 250.0 2.5 4.00 62.5 Silt Fence Results: *Sediment Storage: 0.00 ac-ft *No sediment capacity defined Peak Fence Stage: 0.32 ft Peak Water Stage: 0.32 ft Dewater Time: 0.50 days Trap Efficiency: 95.07 Dewatering time is calculated from peak stage to lowest spillway Stage -Capacity -Discharge Table Fence Stage (ft) Water Stage (ft) Area (ac) Capacity (ac-ft) Discharge (cfs) Dewater Time (hrs) 0.00 0.00 0,000 0.000 0.000 Top of Sediment 0.10 0.10 0.014 0.001 0.563 11.90 0.20 0.20 0.029 0.003 1.136 0.05 0.30 0.30 0,043 0.006 1.721 0.32 0.32 0,047 0.007 1.865 0.01 Peak Stage 0.40 0.40 0.057 0,011 2.317 0.50 0.50 0,072 0.018 2.924 0.60 0.60 0,086 0.026 3.543 0.70 0.70 0,100 0,035 4,172 0.80 0.80 0.115 0,046 1,813 0.90 0.90 0.129 0.058 5.165 1.00 1.00 0.143 0,071 6.127 1.10 1.10 0.158 0,086 6.801 1.20 1.20 0.172 0.103 7.187 1.30 1.30 0,187 0.121 8.183 1.40 1.40 0,201 0.140 8.890 1.50 1,50 0,215 0.161 9.609 1.60 1.60 0.230 0.183 10.339 1.70 1.70 0.244 0.207 11.080 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows !'nn,�rinhi 1aaA _Onn7 PomAlo I q,N—h Fence Stage (ft) Water Stage (ft) Area (ac) Capacity (ac-ft) Discharge Dewater Time (cfs) (hrs) 1.80 1.80 0.258 0,232 11.832 1.90 1.90 0.273 0.259 12.595 2.00 2.00 0.287 0.287 13.369 2.10 2.10 0.301 0.316 14.154 2.20 2.20 0.316 0.317 14.951 2.30 2.30 0.330 0.379 15.759 2.40 2.40 0,341 0.413 16,578 2.50 2.50 0.359 0.418 17.408 Filename: Silt Fence CaICUIations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows (`nnvrw,f 1aaR _onn7 P-,-JJ I gIIII—h 11 Subwatershed / !' I' ,I Detail: Time of Peak Runoff Stru SWS SWS Area Musk K Curve Conc Musk X UHS Discharge Volume # # (ac) (hrs) (hrs) Number (cfs) (ac-ft) #2 1 0.570 0,060 0.000 0,000 86.000 TR55 1.93 0.166 0.570 1.93 0.166 Subwatershed Sedimentology Detail Peak Peak Sediment Sediment Settleable 24VW Stu SWS Soil K L (ft) S (%) C P PS # (tons) Conc. Conc (MI/1) (mg/I) (MI/1) #2 1 0,170 225.00 1.00 1.0000 1,0000 1 5.7 45,086 29.50 16.38 5.7 45,086 29.50 16.38 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows r.,,-i� hi lawn _,)nn7 Pamoh I Q111 ah McCutchen Engineering Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SE®CA® 4 for Windows r— ... ;nw loop _9nn7 P—Ic I q,k—h 2 Storm Type: NRCS Type II Design Storm: 100 yr - 24 hr Rainfall Depth: 7.450 inches Size (mm) Bradson 1,4000 100,000% 1.0000 89.700% 0.0630 66.000% 0.0140 38.100% 0,0380 36.600% 0,0010 4,200% 0,0030 2,600% 0.0010 0.000% Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows rn —w,f i nap _9nn7 P—Io I crV,—h w Type Yp Stru (flows Stru # into) # Musk. K Musk, X (hrs) Description Silt Fence #2 ==> End 0.000 0,000 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCA® 4 for Windows !'nnvrinhf goon _9nn7 D-10 1 Crh...ah 4 Structure Summary: Immediate Total Peak Total Peak Peak Contributing Contributing discharge Runoff Sediment Sediment Settleable 24VW Area Area Volume (tons) Conc. Conc. (ac) (ac) (cfs) (ac-ft) (mg/1) (MI/1) In 3.02 0.27 9.8 46,275 30.27 16.85 #2 0.570 0,570 Out 2.91 0.27 1 0.5 4,337 0.45 0.19 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows r'—,,,W,1 IQOR _9nn7 P—,.II i Crh,nmh Size (mm) In Out 1,4000 100.000% 100.000% 1.0000 89.700% 100,000% 0.0630 66.000% 100.000% 0.0440 38.100% 100,000% 0.0380 36.600% 100.000% 0.0040 4.200% 76,103% 0.0030 2,600% 47.112% 0.0010 0.000% 0.000% Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows P-... i,,hl 4ciap _onn7 P.-.[a I Q1111-h 6 Structure #2 (Sllt Fence) Silt Fence Inputs: Fence Flow Width along Land Slope Tie -back Rate (gpm/sq contour (ft) Height (ft) (ON distance (ft) ft) 10.0 250.0 2.5 4.00 62.5 Silt Fence Results: *Sedlment Storage: 0.00 ac-ft *No sediment capacity defined Peak Fence Stage: 0.50 ft Peak Water Stage: 0.50 ft Dewater Time: 0.50 days Trap Efficiency: 94.48 % Dewatering time is calculated from peak stage to lowest spillway Stage -Capacity -Discharge Table Fence Stage (ft) Water Stage (ft) Area (ac) Capacity (ac-ft) Discharge (cfs) Dewater Time (hrs) 0.00 0.00 0.000 0,000 0.000 Top of Sediment 0.10 0.10 0.014 0.001 0.563 11.50 0.20 0.20 0.029 0.003 1.136 0.35 0.30 0.30 0.043 0.006 1.721 0.05 0.40 0.40 0.057 0.011 2.317 0.05 0.50 0.50 0.071 0.018 2.911 0.03 Peak Stage 0.50 0.50 0,072 0.018 2.924 0.60 0.60 0.086 0.026 3.543 0.70 0.70 0.100 0.035 4.172 0.80 0.80 0.115 0.046 4.813 0.90 0.90 0.129 0.058 5.465 1.00 1.00 0.143 0.071 6,127 1.10 1.10 0.158 0.086 6.801 1.20 1.20 0.172 0.103 7.487 1.30 1.30 0.187 0.121 8.183 1,10 1.40 0.201 0.140 8,890 1.50 1.50 0.215 0.161 9.609 1.60 1.60 0.230 0.183 10,339 1.70 1.70 0,214 0.207 11.080 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows r-... inhl 1o0A _ww D--I. i q,N—h Fence Stage (ft) Water Stage (ft) Area (ac) Capacity (ac-ft) Discharge Dewater Time (cfs) (hrs) 1.80 1.80 0.258 0.232 11.832 1.90 1.90 0.273 0.259 12.595 2.00 2.00 0.287 0.287 13.369 2.10 2.10 0.301 0.316 14.154 2.20 2.20 0.316 0.347 14.951 2.30 2.30 0.330 0.379 15.759 2.40 2.40 0.344 0.413 16.578 2.50 2.50 0.359 0.448 17.408 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 SEDCAD 4 for Windows (`nnvrinhl ic= _9nn7 Pa nI, I Q�h—h i Time of Peak Runoff Stru SWS SWS Area Musk K Curve Conc Musk X UHS Discharge Volume # # (ac) (hrs) Number (hrs) (cfs) (ac-ft) #2 1 0.570 0,060 0.000 0.000 86.000 TR55 3.02 0.275 E 0.570 3.02 0,275 Subwatershed SedimentologyDetail: Peak Peak Stru SWS Sediment Sediment Settleable 24VW Soil K L (ft) S (%) C P PS # Conc, Conc # # (tons) (MI/1) I (mg/1) (MI/1) #2 1 0.170 225.00 4.00 1.0000 1.0000 1 9.8 46,275 30.27 16.85 9.8 46,275 30.27 16.85 Filename: Silt Fence Calculations.sc4 Printed 11-28-2022 All About Plumbing — Grass Drainage Swale Calculations Vegetated Conveyance — Grass Swale #1 Available Capacity (per detail on drawing C400): 2 1 Q— 1.49 * A* R 3 * S z n Q = Flow Rate, (cfs) n = Manning's Roughness Coefficient (unitless) A = Flow Area, (so R = Hydraulic Radius, (ft) S = Slope of Energy Gradient, (ft/ft) Q = to be determined n = 0.035 A = 9.75 s.f. P = 11.50 R = 0.85 (A/P) S = 5.0% 1.49 2 1 Q =— xAx R3 xS2 n _ 1.49 x9.75x0.853x0.051 Q 0.035 Q = 8 3.2 8 cfs (Available Capacity) 10 Year Design Flow (From Grassed Area Drainage Basin: 0.82 acres Intensity: 7.09 in/hr Weighted C = (0.57 Ac)*(0.95)+ (0.25 Ac)*(0.35) 0.57 Ac+0.25 Ac Weighted C = 0.77 Q = CIA Q = 0.77 x 7.09 x 0.82 Q = 4.48 cfs All About Plumbing — Grass Drainage Swale Calculations Velocity Check Velocity = Q (cfs) /A (ft') For Q=4.48cfs; d=0.45ft For d=0.45ft;A=1.51ft2 V = 4.48 / 1.51 = 2.97 ft/s Conclusion: Capacity is available in the proposed design channel to handle 10-year design storm & velocity is equal to 2.97 ft/s which is lower than the maximum design velocity for grass swales of 4 ft/s. All About Plumbing — Grass Drainage Swale Calculations Vegetated Conveyance — Grass Swale #2 Available Capacity (per detail on drawing C400): 2 , Q _ 1.49 * A * R s * Sz n Q = Flow Rate, (cfs) n = Manning's Roughness Coefficient (unitless) A = Flow Area, (sf) R = Hydraulic Radius, (ft) S = Slope of Energy Gradient, (ft/ft) Q = to be determined n = 0.035 A = 9.75 s.f. P = 11.50 R = 0.85 (A/P) S = 2.0% 1.49 z 1 Q =— xAx R3 xS2 n _ 1.49 x9.75x0.853x0.022 Q 0.035 Q = 5 2.6 7 cfs (Available Capacity) 10 Year Design Flow (From Grassed Area Drainage Basin: 0.27 acres Intensity: 7.09 in/hr Weighted C = (0.15 Ac)*(0.95)+ (0.12 Ac)*(0.35) 0.15 Ac+0.12 Ac Weighted C = 0.68 Q = CIA Q = 0.68 x 7.09 x 0.27 Q = 1.30 cfs All About Plumbing — Grass Drainage Swale Calculations Velocity Check Velocity = Q (cfs) /A (ft2) For Q = 1.30 cfs ; d = 0.32 ft For d = 0.32 ft; A = 0.94 ft2 V = 1.30 / 0.94 = 1.38 ft/s Conclusion: Capacity is available in the proposed design channel to handle 10-year design storm & velocity is equal to 1.38 ft/s which is lower than the maximum design velocity for grass swales of 4 ft/s. Time of Concentration Sediment Trapping Area Project Dame: All About Plumbing Location: Mills River, NC Sheet Flow Surface Description Bare Soil ManninWs Roughness (n) Table 3-1 0.011 Flow Length (L) 100 Two Year 24 hour rainfall (P) 3.6" Average Land slope (s) 4.00% or 0,04 ft/ft 0.007(nL)0II T = (p) o.s x (S)IA T= 0.007(0.011 x 100)0.8 (3.6)0.s x (0.04)0.4 T = 0.01 hours Shallow Concentrated Flow Surface Description unpaved Flow Length (L) 100 Watercourse Slope (ft/ft) 4.0% or 0.04 ft/ft Average Velocity (figure 3-1) 3.2 L r 3600V 200 r 3600 x 3.2 T = 0.02 hmtrs Total Combined Time of Concentration Time = 0.01 hours + 0.02 hours Time = 0.03 hours or 1.8 minutes Stormwater Pollution Prevention Plan Permit No. NCGO10000 Appendix E Inspection Log and Reports All About Plumbing - Building Addition Stol'mWatel' Pollution Prevention Plan Permit No. NCG010000 ...Inspection Log Name of Construction Site Location of Construction Site Date of Inspection Inspector Name Does Inspection Report require maintenance of installed BMPs? ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No All About Plumbing - Building Addition Storinwater Pollution Prevention Plan Permit No. NCGO 10000 SWPPP Inspection Log (Continued) Date of Inspection Inspector Name Does Inspection Report require maintenance of installed 13MPs . ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No ❑ Yes ❑ No All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No, NCG010000 App en dix F Rainfdl Log and Reports All About Plumbing - Building Addition ccS 4- C a, M d' m "D I� m D` e- c- r- t- T- IIl V- �D r- t� r- 00 e- ON T- O N •- N N N M N d' N 111 N �D N N 00 N N O M 70, c N M d II1 �9 I� 00 0� w oN O t- N M d' Ln "D 7 ro c L �- N M d Lf1 �D I� 00 Q` O P r- r N rM d r- 'D I� r- W r ON �- O N r- N N N M N d' N un N 'D N I" N 00 N 0` N O M Q c� C s �D t� 00 O� O �- r- N c- M d �- LO r- -,o �- I� r 00 r ON r- O N �- N N N M N d N M N I'D N I'- N 00 N ON N O M M id 4-- C � rcf • • lf1 �D I" 00 0N O�-NM d'tn"Ol�oOo�Or-NMd'►n�Dl�oOo� .II � �... � LL r�S • Md'Ln�D M d m %,o w Q` O M d in %Dr- M M C 4- C L a� N M d' Ln 10 I� 00 O' O r N M d' n 'D r r r r r r r r r r N N N N N N N N N N M M u N rtS C L O r N M d' Ln 'D M d 111 �D I� 00 O' O E r N M d Ln D 00 O, r r r r r r r r r r N N N N N N N N N N M O Z C al L a1 -� O r N M d Ln �D Il� 00 ON O r r r M r d �- Ln r -'D r �- 00 �- ON r O N r N N N M N d' N tf1 N "D N il, N W N ON N O M r M U C L a, -0 E O r- N M d Ln �D I� 00 CYS O M d Ln �D tl, 00 ON O O r N M .F.r a, • Ln i0 Ln O O r N M d n "D i- W ON O m "D 00 ON O r • a v- O r N M d tl 1 �D t� 00 M O �— N M d Ln �D I� 00 ON O r- r N M d' M 'D t� 00 Q` r r r r r r r r r r N N N N N N N N N N M M Storm%vater Pollution Prevention Plan Permit No. NCG010000 Appendix G Additional Site Logs and Records All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCG010000 Date Et Time I Description/Outline and Name of the Presenter of SWPPP and Site Requirements I Name I Companv I Siqnature I All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCG010000 ••• Pre -Construction ConferenceI/ I• Name Company Signature All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCGO 10000 ••• Contractor •Sub-ContractorI• Name of Construction Site Location of Construction Site Company/individualResponsibilities 1.) Start Date: Completion Date: 2.) Start Date: Completion Date: 3.) Start Date: Completion Date: 4.) Start Date: Completion Date: 5.) Start Date: Completion Date: 6.) Start Date: Completion Date: 7.) Start Date: Completion Date: 8.) Start Date: Completion Date: 9.) Start Date: Completion Date: 10.) Start Date: Completion Date: All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCGO 10000 SWPPP Contractor Et Sub -Contractor Log (Continued) 11.) Start Date: Completion Date: 12.) Start Date: Completion Date: 13.) Start Date: Completion Date: 14.) Start Date: Completion Date: 15.) Start Date: Completion Date: 16.) Start Date: Completion Date: 17.) Start Date: Completion Date: 18.) Start Date: Completion Date: 19.) Start Date: Completion Date: 20.) Start Date: Completion Date: 21.) Start Date: Completion Date: All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCGO 10000 SWPPP Modification • • Name of Construction Site Location of Construction Site . . .. . . . . .. . . . . kill ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approved/Implemented BY: -,-Type of Modification AL Description of Modification Location of Modification ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approved/implemented BY: ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approved/implemented BY: ..nff;M171) Description of Modification Location of Modification ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approved/Implemented BY: ModificationType of ..Modification ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approved/Implemented BY: All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCG010000 SWPPP Modification • • • I Name of Construction Site Location of Construction Site j&Type of Modification.. .d ification ❑ Major ❑ Minor Start Date: Completion Date: Reason for Approved/Implemented Modifications: BY: Type of Modification Description of Modification Location of Modification ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approvedllmplemented BY: Type of Modification.. .. ❑ Major ❑ Minor Start Date: Completion Date: Reason for Approved/implemented Modifications: BY: .:.Description of ModificationModification ❑ Major ❑ Minor Start Date: Completion Date: Reason for Approved/Implemented Modifications: BY: Type of Modification Description of Modification Location of Modificatlooll ❑ Major ❑ Minor Start Date: Completion Date: Reason for Modifications: Approved/implemented BY: All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCG010000 SWPPP Soil StabilizationI • Name of Construction Site Location of Construction Site .- of Stabilization Description of Stabilization Location of Stabilization— F Final ❑ Temporary Initiate Date: Completion Date: Additional Inspection Frequency for work proposed for Stabilized Area: area: --this of Stabilization Descriptioni3e of Stabilization Location of Stabilization ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional Inspection Frequency for work proposed for Stabilized Area: this area: -� Type . . ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional Inspection Frequency for work proposed for Stabilized Area: this area: of Stabilization DescriptionType ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional Inspection Frequency for work proposed for Stabilized Area: this area: .- of Stabilization Description ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional Inspection Frequency for work proposed for Stabilized Area: this area: All About Plumbing - Building Addition StOPmWatel- Pollution Prevention Plan Permit No. NCGO 10000 SWPPP Modification Log (Continued), Name of Construction Site Location of Construction Site StabilizationType of Description ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional work proposed for Inspection Frequency for this area: Stabilized Area: .......—Type of Stabilization_.. Description of Stabilization Location of Stabilization ❑ Final ❑ -Temporary Initiate Date: Completion Date: Additional work proposed for Inspection Frequency for this area: Stabilized Area: Type of Stabilization Description of . of • ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional work proposed for Inspection Frequency for this area: Stabilized Area: .• .Description of Stabilization Location of Stabilization' ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional work proposed for Inspection Frequency for this area: Stabilized Area: .• of .ilization Description of Stabilization Location of Stabilization ❑ Final ❑ Temporary Initiate Date: Completion Date: Additional work proposed for Inspection Frequency for this area; Stabilized Area: All About Plumbing - Building Addition Stormwater Pollution Prevention Plan Permit No. NCGO10000 Appendix H Misc. Design Information/Cut Sheets All About Plumbing - Building Addition A1INFAB 2098 is manufactured using sigh tenacity polypropylene yarns that are "MR1 Noven to form a dimensionally stable network, A/hich allows the yarns to maintain their relative position. WINFABfL" 2098 resists ultraviolet deterioration, rotting, and biological degradation and is inert to commonly encountered soil chemicals. It meets o1' exceeds the i requirements of AASFITO M288 for unsupported silt fence and ASTM D6461 table 2; MaXImum Average Noll VOlue PRODUCT DATA SHEET WINFAB'' 2098 0 I f f;.i I•„I f1i Dlsclnlmol; W114rAD assulnes Ila liability fol Tire coluplateness of nccurticy of Illls Infoltnntlott of the u111n1a1e use of tills 111fom1nllon, WIMMU dlsclofnls nny o11d all 111101ed, explessad, or slnluloly slauldauls, 01,1011100es, or 14nllnlllles, This Includes Without limitation filly balled v!aunnly, as to nlelchalllabllily of Illness lot n patllculal purpose of nrlslna float a cotuse of dealing of Imp of bade as (o equfpmenl, nlnlellnis, of hllorllu1,lioll futttished hetowIlil, Tills document should not ba WORM(] ns enJinee11119 a<IVIce, Always consult the ptolecl enclhlem fof poled specific letluhema111s, The and user mistlfllus sole Iesponslblllly lot thu use of this II1101111,111011 and ploducl. The plopally vnlues Ilsled nbove ate subject to chnnde without nollco, f' are Trade llaths al Wlllocoochee lildusldnl Fa )Iles. Inc. U2.021 V1111Moocilae IndtI51101 Fabllcs Inc, lulml Alt l !^,lvt'1,bVhlf,lhll'„1,, 11111 ,I Mnshvlllo M111s Rd. MnslW1110 GA 3.1636 Pill (s l?.) 6311-5767 - Fax: (912) 6311.6633 111111,119; or, 11 107 Dalgl 2010 HmAlon INS J{,zwSfON CONTROL AND I SI CTION 160S 2 I.'LMPORARY SIX_T .1 eNCE 3 1605.-1 DESCRIPTION 4 Furnish material, construct, maintain and rmiwve temporary silt fence in loca(iom shown in 5 the plans or in locations that require mrface drainage to be filtered, 6 16002 h4ATERIALS 7 Refer to Division 10, item Section Geotextile, Type 3 1056 8 (A) Posts 9 Provide steel posts with a( leas( 5 feet long, 1 3/8 inch wide measured parallel to the 10 fence and 1,25 Ibs, per foot in weight per length, Equip with an anchor plate with an area I I of at least 1,1,0 square inches. Ensure a means of retaining fencing material in the desired 12 position without displacement. 13 (11) ��Ioveu Wire Felice 14 Provide woven wire fence at least 32 inches high with 5 horizon(al wires, vertical wires 15 spaced 12 inches apart, 10 gauge lop and bottom wires and J2 1/2 gauge for all other 16 wires. 17 (C) Attachment Device 18 Provide plastic ties, wire fasteners or other ap woved allachvut device, 19 1605-3 CONSTRUCTION METHODS 20 Install in locations as shown in the plans or as directed, 21 lnslall wire and gomextile as shown in Roadway Stand(w(l Dra vings, 22 Geotextile may be used without (he woven 4vire 1elicc backing with a post spacing of not 23 more. than 6 fee(, 24 Well post inclined toward runousource, at an angle of not more than 20' From vertical, 25 AUnch gwwxMe to the post with acceptable methods, 26 Ovalap geotextile al leas( 18 inches at splice joints, 27 1NSA MAINTFNJ ANCE AND REMOVAL 28 Maini& the sill knee until the project is aceepted or until the fence, is removed, Remove and 29 replace deteriorated or ineffective gcolextile. Remove and dispose of silt aceunwlations in 3() accordance 4vith Section 1630 when necessary or as directed, 31 heave silt fence in place until site stabilization and remove at project comple(ion, Removed 32 silt fence becomes the properly of the Contractor, Dress and seed and unilch all areas where 33 silt fence is removed in accordance wilh Section 1660, NGD01' 2018 S(andard Specifications 16-1 2 3 �I 5 6 7 8 9 10 II 12 13 Snclion 1606 1600S NKASU12T!;I1IEN'1' AND PAVh NI' Temporruy Sill hence will he measured and paid in linear feet, accepted in place, along the Wound line of the fence. 'Temporary Silt fence; that requi.m removal and replacement clue to general deterioration or ineffective geotextile will he paid at con(ract unit prices. Repairs to Me Penoc clue to carelessness or neglect on the part of the COMM- "All be at no cost to the Del a menu. Sill Excavation will be measured and paid in accordance with Article 1630-3, Seeding and Mulching will be measured and paid in accordancc with Article 1660-8. !\'bete 104.5, pertaining to revised coMmel prices, will not apply to this item• NO'*V's&" in Me umitmet unk ph, will be allowed because of any overrun or underrun• Payment will be made, Under; Pay item Temporary Silt hence Pay Unit Lineal' fool SI+ MON 1606 SPRO L SEDIMENT CONTROL FENCE 14 1606--1 DESCRIPTION 15 FumNh materials, *onstrnet, maintain and remove special sediment control fence- Place 16 special sediment control fence as shown in the plans or as directed. 17 1606-2 NIATERIALS 18 Refer to Division 10, Item Section Sediment Control Slone, Standard Size No. 5 or 57 1005 19 (A) Posts 20 Provide steel posts in accordance with Subarticle 1605-2(A), 21 (B) 1/411 1lardwave Cloth 22 Provide hardware cloth with I/4 inch openings constructed from 24 gauge wire, 23 (C) Attachment Device 24 Provide plastic lies, wire fasteners or other approved attachment device, 25 IH60 CONSTRUCTION N1E`P1-10D,S 26 h,tall hardware cloth and sediment control stone in accordance with Roa(hwrcy S'lrt,trJard 27 Drmwings, Attach hardware cloth to post with acceptable methods, 28 N6aintain the special sedimen( control fence until the project is accepted or until the, fence is 29 removed, Remove, and dispose of Silt accumulations at the fence when so directed in 30 accordance \Pith Section 1630, 31 1606-4 N1l,AS'UREMEN1' AND PAS NgEN1' 32 .Sill I?mamlinrl Will be measured and paid in accordance wi(h Article 1630-3, 33 IN" l/cuchvrrrn, Clvdh will be nleilRl)red and paid in accordance with Atli*le 16315, 311 Sediittenl CocUrol Slone will be measured and paid in accordance \Pith Arlicic; 16111 1r,_2. NCDOT 2010 S(a)dard SpecificatiOns I r-A AN for ForSustomonre vefletarlolr Profile's 5 Fundamentals are the Foundation to Sustainable Vegetation Establishing sustainable vegetation and receiving the earliest possible Notice of Termination (NOT) are the goals of every project. Profile's 5 Fundamentals are the surest way to get you there. Picking the right erosion control material like Flexterram HP-FGM"' is just one of the 5 steps. 1. Assess and Create Optimal Soil Conditions Soil testing provides essential information to determine what soil amendments, if any, are required to assure a more favorable growing environment for faster, more complete vegetative growth and sustainable establishment. 2. Pick the Right Plant Species It is essential to select plant species that are adapted to the site conditions, to3. Select the Correct Erosion Control Material The right cover protects both seed and soil, and facilitates growth. Flexterra HP-FGM is unsurpassed in delivering outstanding performance. 4. Ensure Proper Installation Products must be Installed in accordance with manufacturer recommendations to maximize their performance. f 5, Follow-up Inspections and Maintenance Practices Continual monitoring ensures all site compliance Issues are being addressed. Maintenance may be required to mitigate unexpected challenges. Profile provides valuable assistance for each of these Fundamentals 2417-- beginning with FREE soil testing. Visit proflleps3.com- FLEX U ERR " U IlP-FGM"' Absolutely the Most Effective Erosion Control Medium Available Flexterra) HP-FGM"stands alone as the ultimate erosion control and revegetation product. Fine grading and extensive soil preparation are unnecessary, allowing you to apply the product for immediate protection and superior performance at reduced overall costs. Flexterra HP-FGM Delivers: o The highest germination and HARD ARMOR growth establishment of any °°^ •^•°^^° ••^°°°°^••^^^ rolled or other hydraulically REINFORCED VEGETATION applied erosion control product available „ ,,,.mM•.,.,,,............. ,MmM NATURAL VEGETATION a Greater than 99% erosion control effectiveness immediately upon application o 100% biodegradable o Non -toxic and safe for even the most sensitive environments ME Superior erosion control across Profile's spectrum of products ensures reliable, sustainable solutions for slopes, channels, shorelines, water management projects, pipeline restorations, waste and fly ash containment sites, fine turf areas and other environmentally sensitive sites. Patented Technologies and Greener Components Deliver Unmatched Performance Flexterra HP-FGM combines both chemical and mechanical bonding techniques to lock the engineered medium in place and promote accelerated germination with minimal soil loss. Greener from the inside out, here's what makes it work so well: Revolutionary patented Micro -Pore particles optimize water and nutrient retention 100% recycled, virgin Thermally Refined° wood fibers produce the highest yield and coverage per unit weight, and are phyto-sanitized, ellminating weed seeds and pathogens k ) 100% non -toxic blopolymers and water absorbents enhance erosion control resistance and growth establishment 100% biodegradable interlocking fibers Increase mechanical bonding of the matrix to provide Immediate performance upon Installation A Closer Look at Micro -Pore Particles and Thermally Refined' Wood Fibers Fibers magnified 45 tunes by Independent lab specializing In fiber analysis. ea Micro -Pore particles capture and hold moisture and nutrients, reduce soil surface evaporation and improve oxygen exchange, which all contribute to faster, more uniform vegetation establishment. a Micro -Pore particles also increase bond strength of the flexible growth medium, resulting In greater resistance to raindrop Impact and sheet flow. Inferior wood fibers magnified 45 tunes, Nothing Keeps More Soil On Site Flexterra® HP-FGM" has demonstrated nearly perfect erosion control performance — even on slopes as severe as 0.251-1;1 V. In addition to minimizing soil loss, the turbidity of runoff is greatly reduced, In large scale testing, Flexterra HP-FGM reduced effluent turbidity of sandy loam soils to less than 250 Nephelometric Turbidity Units (NTUs). Establishes Vegetation More Reliably Quicker and complete establishment is the key to long-term erosion control. Flexterra HP-FGM has recorded the highest growth establishment rating of any erosion control product in independent laboratory testing using standard test method ASTM D7322. The First Erosion Control Product to Offer Documented Functional Longevity ASTM D5338 testing protocol confirms Flexterra HP-FGM's observed functional longevity of Lip to 18 months. Flexterra HP-FGM is proven to last longer than other hydraulically applied erosion control products. Long-lasting Flexterra HP-FGM is designed to: c Provide protection on bare soil over periods of dormancy; assures that when more optimal growing conditions arrive, the seed and nutrients are still in place and in an environment conducive to rapid germination and emergence. Increase survivability of plants; exceptional water retention nurtures vegetation to better withstand environmental stress. Accommodate a broad range of vegetative species; safeguards and helps to cultivate even the slowest establishing species. 100% recycled, Thermally Refined® virgin wood chips create fine, long and highly absorbent fibers that deliver superior yield, coverage and water -holding capacity. Competitive refining technologies develop Inferior fibers that require more bales to achieve the coverage of Profile's Thermally Refined wood fiber matrices, Additionally, claims that competitive mulches save or use less water during application just don't hold water. EROSION CONTROL PERFORMANCE 100% go% i — 00% I 70% — G0% 50% SVavrlfot`` Doubledltt Proble'Bmded D�uGr�let lea a ra' ItTdravfidAu�Js SVawBlsn et h'Mr laVla D<e sbrB an el IP•I�iIA' Average Pemnl Effealveness Days TYPICAL FUNCTIONAL LONGEVITY 500 400 300 zoo -- 100 0 d Prolfle�lYoad Pror�errlilaid I i'vS�1 101114iAiu(ih Based on AStThM 05338 and Field Observallons Flexterra" HP-FGiVI"' Technical Data: PHYSICAL PROPERTIES* MasslllnilArea ASTM NS66' glrn' (ozlyd') x 390 (11.6) thickness ASTM D6525' rnm (In) x 5.6 (0.22) Ground Cover ASTM D6567' % x 99 Watet-Rolding Capadly ASTM D7367 % x 1,700 Material Color Observed nla Green ENVIRONMENTAL PROPERTIES* Biodegradability ASTM D5338 nla Yes Ecoloxicity EPA 2021.0 % 40•Iu LCO> 100% Effluent Turbidity large Scales NTU < 250 PERFORMANCE PROPERTIES* Cover Factor' Large Scales nla s 0.01 Percent Effectiveness' Large Scales % x 99 Functional Longevity' ASTM D5338 months s 10 CweTirne observed hours 0.2 Vegetation Establishment ASTM D7322' % x 800 PRODUCT COMPOSITION TYPICAL VALUE lheumally Processed' (within a pressurized vessel) 100% Recycled Virgin Woad Fibers 80% Wetting agents (Including high -viscosity colloidal polysac(haddes, cross -linked blopolymers, and wafer absorbents) 10% Gimped Biodegradable Interlocking Fibers 5% Micro•Pore Granules 5% * When uniformly applied at a rate of 3,5001blac (3,940 kgllha) under laboratory conditions, 1. ASTM test methods developed for Rolled Erosion Control Products that have been modified to accommodate Hydraulic Erosion Control Products. 2. Cover factor Is calculated as soil loss ratio of treated surface versus an untreated control surface. 3. Percent Effectiveness = One minus Cover Factor multiplled by 100%. 4. Functional Longevity Is the estimated time period, based upon field observations, that a material can be angdpated to provide erosion control and agronomic benefits as Influenced by composition, as well as site -specific conditions, Including; but not limited to —temperature, moisture and light conditions, soils, biological activity, vegetative establishment and other environmental factors. 5. Large Scale testing conducted at Utah Water Research Laboratory. For specific testing Information, please contact a Profile technical service representative at 800-508.8681 (US and Canada) or International - +1-847-215-1144. 6. Heated to a temperature greater than 380 degrees Fahrenheit (193 degrees Celslus) for 5 minutes at a pressure greater than 50 psi (345 kPa). P.�o�e• Solutions foryourfavironment' GREEN DESIGN ENGINEERING"' EArITII•FRIENDI, HOLUTIONH CROW FOn BUHTAINADLE IIEHULTH" Green Design Engineering"' Is a holistic approach, combining environmentally beneficial design and ecologically sound products with agronomic and erosion control expertise, to provide the most effective, customized and cost-efficlent solutions for erosion control and vegetative establishment. _ - 3 PSI, Profile's unique online PROFILE BOIL SOLUTIONS 8 o F T w A R E project design and management software, is the best place to start applying The 5 Fundamentals"' to your next project. The process begins with a FREE soil test, and walks you through every Fundamental. It's the only program of Its kind that Integrates and compares a variety of technologies to your specific project parameters, and provides complete documentation including product specifications, Installation guidelines, CAD details and other pertinent technical Information. Get started by visiting Prof! lePS1com. PROFILE Products LLC 750 W. Lake Cook Rd • Suite 440 Find us on 191 DuffaloGrove, ILG0009.000.500.8601 prollleproducts,com faoebook,com/proflloEVS 02010 PROFILE Products LLC, all rights reserved, Profile, Flexterra and Thennally Relined are registered trademarks of PROFILE Products I.I.C. IECA Solutions foryour Environment, RP-FGM, The 5 Fundamentals, GreenArmor System, ENGM, Flexible Growth Medium, ProMaldx, fPr9' Engineered FlberMatrix, Green Design Engineering and Earlh•Fllendly Solutions forsuslainable Results are trademarks of PROFILE Products LLC, IIP•02 02110 INSTALLED COST PER ACRE4 INCLUDING SEED, FERTILIZER, AND LABOR Flexterra'° dramatically reduces overall costs. The savings are even more dramatic when you consider the extensive soil preparation blankets require to minimize voids and hrldging over the soil surface, 'Bused on Installed rate of 3,500lb per ocro. Flexterra'° itas consistently outperformed any and all competitive vegetated slope protection technologies, including Bonded Fiber Matrices and Erosion Control Blankets. Flexible Slope Protection at the Lowest Overall Cost. New Flexterra"' is a revolutionary component of Profile Erosion Control Solutions (PECS"'), the Industry's most comprehensive ' t assortment of hydraulic mulch and erosion control blanket technology combined with on -site expertise and unfailing , support, Like all products within the PECS arsenal, Flexterra"' is specifically engineered to deliver optimum performance under demanding conditions, Nothing controls soil erosion and accelerates seed germination like Flexterra;" the ultimate hydraulically applied blanket, Patented technology creates a Flexible Growth Medium"' (FGM"') that offers better protection on slopes than rolled erosion control blankets (ECB) and bonded fiber matrix (BFM) products — with the speed and cost savings of hydraulic seeding, Plus, it can be combined with other erosion control technologies to accommodate a broad range of conditions, At lower application rates, it can significantly and economically Improve the performance of complementary technologies from straw blankets to turf reinforcement mats (TRM), Flexterra"' is effective upon application. It requires no cure time to develop Intimate soil contact. This engineered medium performs on slopes steeper than 2.5H:1V and remains effective even during sustained rainfall events. It can be applied using all types of mechanically agitated hydraulic seeding equipment over uneven terrain and rough seedbeds. It Doesn't Just Perform, It Outperforms, Nothing compares to the performance of Flexterra"' when evaluated by the most prestigious slope erosion testing laboratories in North America. Flexterra" performance has been proven, r Superior erosion control-0.0001 Cover (C) Factor from the Universal Soil Loss Equation translates to 99,9% effectiveness —or near perfection, r Effective immediately —no cure time required, r Fastest turf establishment-1500% water holding capacity delivers more moisture to the seedbed for better germination. 1/3 less expensive than blankets —less soil preparation is required, Product Corript Effective without special site preparation yes no ................ -........ -....... -... ------- ------------- ---- t . Can he applied without direct access to site yes no -- �L --------------------- ------- ------------------------ no Eliminates cos labor Intensive stoking yes i.---------------------------- --- ----- tly------------------------------ --- Y - _ 0 Bonds directly to the soil es no 4!w t..... --- ------------ �'�` ' Rids site of messy, leftover nett Ing yes no Flexterro- approached perfection (greater than 99% effectiveness) udder varying slope, soil, rainfall and testing coittlitions. Test Method Lab ProtocoP ASTM D64595 ECTC Test Method #20 Appllcaltorl Rate 3000 lb/oc - - 3500 lb/oc--_.---3500 Woo ---------------------------------------------- - ------ -------- Test Conditions: Slope Gradient 2,5H:IV 2H:IV 3HAV Soil Type snarly loam clay snnd silty snnd Test Duration I hr 3 successive —I hr 1/2 hr --------------------------- ------------------- ---------------------- Rainfall Event 5 In/hr 2 in/hr 6 in/hr -------------------------------------------------------------------- -------------------------- Cover or'C" TactoO 0,0003 010001 0.0066 ........... ----------------------- - ------- -------------------------- % Effecllvcltess2 99.97% 99.99% 99.34% I, UWRL— Utah Wolof Rosa arch laboratory 2. SDSU/SERL—Son Dlotio Stale Univofsiiy/Soil Erosion Research Laboratory 3. TRI—TnUEnvlronmonlal, Inc, 4. Lab pfaccduro developed over 20 yonrs of rainfall simulatlon toson0 6.'Standord Tosl Mothod for Determination of Erosion Control Dlankot (ECO) Peitormonco In Protecting Ildislopos from Rainfall Erosion' Tasting simulated throe succossNo %yoorstorm events In Los Angeles Basin 6. Proposed ASTM and E(oslan Conlrol Technology Councli IECTC) Approvad • Standard Indox Tast Method for Determination of Bolted Erosion Control Product (RECP) Abllity to Prolact Soll (ram nslnsplesh and Runoff under Danch•Scalo Conditions 7. Cove raf'C' Factor determined from cemparisen of treated slope vs. Lora stop condition, Do C Factor Is the componontollhoUnivorsal Sell Loss Equationth6trnonsurestho erosion control offactivanossof a product. one minus Cover Facto raqunit tho %Effectiveness. Blanket and BFM Comparisons Fall Flat, Flexterra"' is an effective alternative to erosion control blankets and BFMs, No straw or excelsior blanket alone can match Flexterra's°' slope protection, even on critical sites, The loft of the FGM" matrix captures moisture and creates more air space to enhance seedling emergence, Flexterra.. absorbs and holds 5 times its weight in water, while standard excelsior blankets retain only twice their weight, The beauty of Flexterra'', however, Is that it can be used a number of ways, For example, blankets and turf reinforcement mats (TRMs) will perform better when a protective layer of Flexterrad" is first applied at a reduced rate before installation, Independent testing proves that Flexterra" significantly out -performs excelsior and straw blankets as well as BFMs in preventing erosion. The results speak for themselves: NEARLY 100 TIMES LESS SOIL LOSS PER ACRE THAN BLAMICETS AND BFMS. FGM" BFM"" STRAW BLANKET EXCELSIOR BLANKET 'Faking Erosion Control to a whole New ]Level, Although BFM technology has its place, Flextert " FGM°' is engineered for much tougher site and environmental conditions. Select FGM'" if: Select BFM If: r The site requires stronger mechanical ' A chemical bond is strong enough and chemical bonds to withstand to meet slope severity and length greater surface flow and/or severe slopes " The required functional longevity of ' Soil needs erosion protection for LIP soil protection is G months or less to one year The site demands Immediate erosion protection and you need to eliminate risk from impending weather r You need the fastest vegetation establishment possible 1 You require a high factor of design safety The soil is dry and rain is not expected within 48 hours after application ' There Is a high degree of certainty heavy rains will not follow application r You require a moderate factor of design safety Flexterra'° EXC05101' Slaw FGM"' Blanket Blanket PROMOTES MORE COMPLETE SEED GERMINATION THAN BLANKETS Flexterra'" not only provldes better Immedinto erosion control, Independent testing also proves Flexterra'" provides better long-term control through more reliable and donser vegetation establishment. FGM" application rasa 3,000lb per acro. 5" par hr. rain avant on 2.511: IV stop a for I hr. on sandy loom soil. 'Extropolalod from Utah rosoarch. "Compolllive OFM product ---mo..wnw-w- Wood Fillers hiterlochiup Fihers Co-Polymor Gol Crosslinlcinp Hydro -colloid Tacl(ilier No CURE TIME REQUIRED Testing proves that Floxterram Is 98% elfOclive two liours niter application. FGM1"1 application to to 3,0001b por 0cro, lo•yoarslon avant 12.1 Inchas► Son Dlogo Stalo Univorsity Sall Erosion nosoarch Laboratory ISDSU/SELL) The Right Chemistry Works Every Time. Flexterra"' uses patented technology combining both chemical and mechanical bonding techniques to lock the engineered medium in place. Crimped synthetic fibers, organic fibers and performance -enhancing additives form a lofty, interlocking matrix that creates air space and water -absorbing cavities which improve germination; reduce the impact of raindrop energy and minimize soil loss. Superior chemistry means no cure time, which enables the matrix to handle higher rates of surface flow energy from heavy rains —upon application. Water-resistant tackifiers and flocculants chemically bond the matrix to the soil surface. OSS Soil Loss Two Hours After Application 10011) 0o ro 4 i BAN SOIL FLE ENV FO 601b 4011) 2016 olb - IElapsedThna 0 20 AO 60 00 100 A11 lutes 100% 9 i co a, 11 tA —— .s r 2% FGM"' Dare Soll Solves Problems on a Variety of Sites. FGM"' has been used on projects ranging from rough ground and steep, rocky slopes to moderate- or steep -graded fill slopes. It is also used in environmentally sensitive wetlands and other wildlife areas not compatible with nettings. It has proven itself in a broad array of applications: DOT & Highway Projects FGM"' can be applied gLIICIdy to small or large areas with no cutting, trimming or stapling Involved. It has received DOT approval on a growing list of states. Mine Reclamation FGM" exceeds the rigid environmental standards that come with abandoned mined land (AML) reclamation projects. Commercial and Residential Construction FGM'° doesn't require stakes that pose hazards and doesn't leave netting behind that can Interfere with mowing. Golf Course Construction FGM" locks the soil and seed In place, allowing grass to mature into a healthy, dense cover at a fraction of the cost of sod. Flexible Growth Medium"' Specification The Flexible Growth Medluni" (FGM") shall be a hydratlllcally-applied, flexible erosion control blanket composed of long strand, thermally processed wood fibers, crimped, Interlocking fibers and performance enhancing additives, The FGM" requires no curing period and upon application forms an intimate bond with the soil surface to create a continuous, porous, absorbent and erosion resistant blanket that allows for rapid germination and accelerated plant growth. The FGM` shall be Flexterra", as manufactured by Profile Products, LLC and shall conform to the property values listed below when applied at a rate of 3500 pounds per acre (3900 kilograms/hectare), PROPERTY TEST OD PIkysicill Mass Per Unit Area ASTM D-6566 11,5 oz/yd' 390 g/111' Thickness ASTM D-6525 0.19 In 4.8 nnn % Grotntd Cover ASTM D-6567 99e/a 99% Water Holding Capacity Proposed ASTM 1500% 1500% Flexural Rigidity (wet) ASTM D-6575 12 oz-yd 10,000 ntg-em Color (fugilive dye) Observed Green Green Endurance Funetionnl Longevity Observed Up to l yr Up l0 1 yr Perforinance Cover Factor (6 InAir event) % Effectiveness ECTC Test Method 112 ECTC'fest Melliod 112 0.0066 99.34% 0.0066 99•34% Sliem• Stress ECTC Test Method 113 1 Will' 48 Pa One minus Cover or "C" Factor equals the %effectiveness. INSTALLATION Strictly comply with manufacturer's Installation instructions and !recommendations. Use approved hydro -spraying machines with fan -type nozzle (50-degree tip). To achieve optimum soil surface coverage apply FGM" from opposing directions to soil surface. Erosion Control and Revegetatlon: Step One: Apply seed, fertilizer and other soil amendments with small amount of Flexterra" for visual metering. Step Two: Mix 50 lb of FGM" per 125 gallons (23 I(g/475 liters) of water; confirm loading rates with equipment manufacturer. SLOPE GRADIENT OH to IV 3000 Ib/ac 3400 kg/Itn >3H to IV and: 2M to IV 3500 ib/tic 3900 kg/hn >2H to IV and SI H to IV 4000 Ib/ac 4500 kgAin >IH to IV 4500 Mac 5100 kg/lta Below EC13 or TRM 1500 Ib/ae 1700 kg/ha As in611 for TRM 3500 Ib/ac 3900 kg/ita Consult comprehensive Csl formatted speenicauons for nuumonm PACKAGING Bags: Net Weight - 50 lb, UV resistant plastic film. Pallets: Weather-proof, stretch -wrapped with UV resistant pallet cover, 40 bags/pallet, I ton/pallet. Your Trusted Partner in Soil Solutions - Profile Products Is the world's largest producer of hydraulic mulch and hydraulic nulch additives, and a leader In erosion control and revegetation science. Many of today's Industry standnrds were Innovations Introduced by Profile. Our leadership continues through aggressive research and development, active support of trade associations, and education designed to advance the hulustrys effectiveness and professionalism. Profile" lour Trrrslcr! Purhmr• In Sul! Sulrrllons * F03 k e�A , For technical Inrormanon call 1.866.326.6202. For distributor location and customerservlce call 1.800.366.1180. 02004 PROFILE Products LI.C, oil rights reserved. Flexterroand Flexlble Growth Medluni ara trademarks of PROFILE Products LLC. U.S. Patent It's: 5,042,020; 5,770.782; 5,741,832 750 Lnko Cook Road - Suite 440 1 Buffalo Grove, IL 60089 www.proilleprotlucts.com Profile Solutions for your Environment Application / Loading Procedures A. Strictly comply with equipment Manufacturer's installation instructions and recommendations, Use approved hydro -spraying machines with fan -type nozzle (50-degree tip) whenever possible to achieve best soil coverage, Apply from opposing directions to assure 100% soil surface coverage. Slope interruption devices or water diversion techniques are recommended according to the slope interruption limits table on the back, B. To ensure proper application rates, measure and stake area. For maximum performance, apply in a two-step process*: 1. Apply specified prescriptive agronomic formulations along with 50% of seed with a small amount of HP-FGM"' or ET FGM"' for visual metering, 2, Mix balance of seed and apply HP-FGM or ET FGM at a rate of 50 pounds per 125 gallons (see mixing section on the back for details) of water over freshly seeded surfaces. See loading chart on the back and confirm loading mites with equipment manufacturer. Do not leave seeded surfaces unprotected, especially if precipitation is imminent, C. Fill 1/3 of mechanically agitated hydroseeder with water. Turn pump on for 15 seconds and purge and pre -wet lines. Turn pump off, D. Turn agitator on and load low density materials first (i.e. seed),** E. Continue slowly filling tank with water while loading fiber matrix into tank, F. Consult loading chart on the back to determine the number of bags to be added for desired area and application rate, G. HP-FGM or ET FGM should be completely loaded before water level reaches 75% of the top of tank, H, Top off with water and mix until all fiber is fully broken apart and hydrated (minimum of 10 minutes — increase mixing time when applying in cold conditions). This is very important to fully activate the bonding additives and to obtain proper viscosity, I, Add fertilizer, J. Shut off recirculation valve to minimize potential for air entrainment within the slurry, K. Slow clown agitator and start applying with a 50-degree fan tip nozzle, L. Spray in opposing directions for maximum soil coverage, *Depending on site conditions, HP-FGM or BT FGM may be applied In a ale -step process inhere all components may be mixed together hl single tank loads, Consult with Manufacturer for fin'ther details, ""Do not add tacklfiers or pol),mels. Tank Size II of 50-II) (001) halos (II)) 250 2 100 600 4 200 760 6 300 1,000 0 400 1,600 12 600 2,000 16 coo 2,600 20 1,000 3,000 24 1,200 3,600 20 1,400 4,000 32 1,600 01s, 111E lr'M'�uaPlil GaM 0001h/ncro 3,600lb/ncro 4,000 1h/ncro 4,600lb/acro dncon)ont 2,60017Across(i (0aQ Sq it t Was S(I it Acres Sq it Acres Sq it Acres 200 1.742 2 0.033 1,246 0.020 1,009 0.026 900 0.022 560 3,405 4 0.007 2,409 0.057 2,170 0.050 1,936 0.044 040 6,227 0 0.100 3,734 01000 3,207 0,076 2,904 0.007 1,120 6,970 0.100 6,000 0.133 4,970 0.114 4,356 0,100 3,072 0.009 1,000 10,464 0.240 0,712 0.200 7,407 0.171 6,634 0.160 6;000 0.133 2,240 13,039 0.320 11,616 0,267 9,057 0.229 0,712 0.200 7,744 0.170 2,000 17,424 0.400 14,620 0,333 12,440 0.200 10,090 0,260 9,600 0,222 3,360 20,909 0.400 17,424 0.400 14,935 0.343 13,060 0.300 11,610 0.267 3,920 24,394 0.660 20,320 0,407 17,424 0,400 16,240 0.360 13.652 0.311 4,400 27,070 0.640 23,232 0.633 19,913 0.457__t 17,424 1 0.400 15,400 1 0.350 Additional Notes; a For Hose applications, 35 lb/100 gal Is recommended. o Rough surfaces (rocky terrain, cat tracks, ripped solls, etc.) may require additional product to achieve 100% coverage, o Be sure to allow for residual material In tank on subsequent applications, q'hnlloatloll� i kites slope Condition Engllsh SI S 4H to 1V 2600 Wears 2000 kgnioclaro > 411 to 1V and S 311 to 1V 3000lb/acro 3400 kgnieclare > 311 to 1V and 52H to 1V 3600 Macro 3900 kgnloclaro > 211 to 1V and 5111 to 1V 4000lb/acro 4500 kgnloclaro > iH to 1v' 45001b/acro 5100 kgnloclare Below ECB orTRM 1500 Macro 1700 k9theclefe As Inllll forTRM' 3500lb/acre 3900 kgnloclaro 'HP-FGM or ET-FGM recommended for slopes greater Ilion 1HJV. 'Use only approved and IosledTRMs to create Ilia Graon/umor System. Visual Key for Proper Application (Flexterra HP-FGM shown below) Proper Application Improper Application Product Category Length (11) La igth (nl) HP-FGM 100 30 ET-FGM 125 30 'Listed slope Inlorfuptlon limits are for product applications on a 3H;1V slope. For applicallon on sleeper slopes, slope Inlorfupllon longlhs may need to be decreased. 3,000 Wacre 3,5001b/acre .4,000 lb/acre Idnolok®UckcI I)� lilnoss }inss Profrle� Sorultont foryour Adrommtin- PROFILE Products LLC 760 Lake Cook Road, Suite 440 Buffalo Grove, IL 60089 ,�+ Flextem,a' IIP•FGM' (goo) 608-6601 CocoReXET FGM www.proflleproduots.com U.S. Mont 11's; 6,042,020; 6,770,702; 6,741.032; 0,300.47017,762,004 ESI'-01 W13 LAN D LO K® Product Data LANDLOKO 450 LANDLOKO 450 turf reinforcernent mat (TRM) features X30 technology that consists of a dense web of interlocking, multi -lobed polypropylene fibers positioned between two biaxially oriented nets and mechanically bound together by parallel stitching with polypropylene thread. The TRM is designed to accelerate seedling emergence, exhibit high resiliency, and possess strength and elongation properties to limit stretching in a saturated condition. Every component of LANDLOKO 450 is stabilized against chemical and ultraviolet degradation which are normally found in a natural soil environment. Furthermore, the TRM contains no biodegradable components. LANDLOKO 450 conforms to the property values listed below' and is manufactured at a Propex facility having achieved ISO 9001:2008 certification. Propex performs internal Manufacturing Quality Control (MQC) tests that hn%ln hoon arrrcarlitsarl by the C"Pr1C\ynthPtir-. Annrefiitation InGtituta - I Ahnratnry Accrpditatinn Program (GAI-LAP). PROPERTY TEST METHOD T ENGLISH METRIC ORIGIN OF MATERIALS % U.S. Manufactured 100% 100% PHYSICAL Mass Unit Area 2 ASTM D-6566 10.0 oz/yd2 339 g/m2 Thickness 2 ASTM D-6525 0.50 in 12.7 ram Light Penetration % Passing)2 ASTM D-6567 20% 20% Color Visual Green or Tan MECHANICAL Tensile Strength 2 ASTM D-6818 425 x 350 Ibs/ft 6.2 x 5.1 kN/m Elongation 2 ASTM D-6818 50% 50% Resiliency2 ASTM D-6524 90% 90% Flexibilit 2 ASTM D-6575 0.026 in -lb 30,000 mg -cm ENDURANCE UV Resistance % Retained at 1000 hrs 2 ASTM D-4355 80% 80% PERFORMANCE Velocity (Vegetated )2,3 Large Scale 18 ft/sec 5.5 In/sec Shear Stress (Vegetated)2,3 Large Scale 10 Ib/ft2 479 Pa Mannin 's n Unve etated 2,4 Calculated 0.025 0.025 Seedling Emergence 2 ASTM D-7322 409% 409% ROLL SIZES 8ftx140ft 16 ft x 140 ft 16 ft x 348.75 ft 2.45mx42.7m 4.88 In x 42.7 m 4.88mx106.3m NOTES: 1. The property values listed above are effective 01/22/2020 and are subject to change without notice. 2. Values represent testing at little of manufacture and are shown as typical values. 3. Maxhnuin permissible velocity and shear stress has been obtained through vegetated testing programs featuring specific sell types, vegetation classes, flow conditions, and (allure criteria. These conditions may not be relevant to every project nor are they replicated by other manufacturers. Please contact Propex for further Information. 4. Calculated as typical values from largescale Jlexible channel lining test programs with a flow depth of 6 to 12 Inches. ENGINEERED EARTH SOLUTIONSTM GEOSOLUTIONS www.propexglobal.com Propex Operating Company, LLC • 4019 Industry Drive • Chattanooga, TN 37416 • ph 800 6211273 • ph 423 8551466 ARMORMAXo, PYRAMAT', LANOLOKa, W, PYRAWALLt, SCOURLOK', GEOTEX', PETROMAT', PETROTAC', REFLECTEX', and GRIOPROt'u are registered trademarks of Propex Operating Company, I.I.C. iids publication should not be construed as engineming addco. W ille Infonnatlon contained In this publication Is accurate to the best of our knowledge, Propex does not warrant Its accuracy or conipleteness. The ultimale customer and user of the products should assume sole resPonslbility tar the final determination of the suitability of the Information and the products (or the contemplated and actual use. ilia only warranty made by Propex for its products Is set forth In our product data shoals farina product, or such other mitten warranty as maybe agreed by Propex and Indhiduai cuslomers. Piano. specifically disclaims all otter warranties. oxpross or Implied, Including without limitation, warranties of merchantability, or fitness for a particular purpose, or arising lions provision of samples, a course of dealing or usage of trade. 0 2020 Propex Operating Company, LLC LANDLOKO 450 turf reinforcement mat (TRM) features X30 technology that consists of a dense web of crimped, interlocking, multi -lobed polypropylene fibers positioned between two biaxially oriented nets and mechanically bound together by parallel stitching with polypropylene thread. The TRM is designed to accelerate seedling emergence, exhibit high resiliency, and possess strength and elongation properties to limit stretching in a saturated condition. Every component of LANDLOK 450 is stabilized against chemical and ultraviolet degradation which are normally found in a natural soil environment. Furthermore, the TRM contains no biodegradable components. LANDLOK 450 conforms to the property values listed below and is manufactured at a Propex facility having achieved ISO 9001:2000 certification. Propex performs internal Manufacturing Quality Control (MQC) tests that have been accredited by the Geosynthetic Accreditation Institute — Laboratory Accreditation Program (GAI-LAP). This product NTPEP approved for AASHTO standards. MARV2 PROPERTY TEST METHOD ENGLISH METRIC ORIGIN OF MATERIALS % U.S. Manufactured Inputs 100% 100% % U.S. Manufactured 100% 100% PHYSICAI Mass/Unit Area ASTM D-6566 10.0 oz/yd2 340 g/m Thickness ASTM D-6525 0.40 in 10.1 mm Light Penetration % Passing ASTM D-6567 20% 20% Color Visual Green or Tan MECHANICAI Tensile Strength (Grab) ASTM D-6818 400 x 300 lb/ft 5.8 x 4.3 kN/m Elongation ASTM D-6818 50% max 50% (max) Resiliency ASTM D-6524 90% 90% Flexibility ASTM D-6575 0.026 in -lb avg 30,000 mg -cm avg ENDURANCE UV Resistance ASTM D-4355 80% 80% % Retained 1000 hrs PERFORMANCE Velocit (Vegetated) Large Scale 18 ft/s 5.5 m/s Shear Stress Vegetated Large Scale 10 lb/ff 479 Pa Manning's "n"' (Unvegetated) Calculated 0.025 0.025 Seedling Emergence ECTC Draft Method #4 409% 409% ROLL SIZES 1 6.5 ft x 138.5 ft 1 2.0 m x 42.2 m NOTES: 1. The property values listed are effective 0412011 and are subject to change without notice. 2. MARV indicates minimum average roll value calculated as the typical minus two standard deviations. Statistically, it yields a 97.7% degree of confidence that any sample taken during quality assurance testing will exceed the value reported, 3. Maximum permissible velocity and shear stress has been obtained through vegetated testing programs featuring specific soil types, vegetation classes, flow conditions, and failure criteria. These conditions may not be relevant to every project nor are they replicated by other manufacturers. Please contact Propex for further information, 4. Calculated as typical values from large-scale flexible channel lining test programs with a flow depth of 6 to 12 inches. epropex-Geotextile Systems TESTED.PROVEN.TRUSTED. www.geotextile.com Propex Operating Company, LLC - 6025 Lee Highway, Suite 425 • PO Box 22788 • Chattanooga, TN 37422 ph 423 899 0444 • ph 800 621 1273 • fax 423 899 7619 Geotexd', Landloko, Pyramato, X3', SuporGro", Petromal" and Petrotac" are registered trademarks of Propex Operating Company, LLC. nis pub,"ton shouli rut be crosbud as engneedrg aNce, t',hla Inrormarm contared in Ws pcblwron is —rate to she best of o" knos:ed,e, Propex dons M warrant its accuracy or cargQlaness The Wmate customer and user of the prods ss "d assume sda respans�bdty fa Iha Anal deterrrfnation of ore ssflabllty of the In!ormdten and the products W the coolemoatd and aWual uso. The my warranty made tr/Popex fa Its poduds Is set forth h our product dsta sheets ("the product, ot such We written warranty as may be egred by Propex ad Indsidual cust"ners. Propex speefualy dscla'ms al other vanautias, eapress or Impld. IncWag stidhad rvueatim, warranties of merchantaWy or Alness for a particular purpose, or a6ing from prwh cn of same'es, a cause of dearng or usage of trade. © 2011 Propex Operating Company, LLC LANDLOK' LANDLOK TURF REINFORCEMNET MAT PERPENDICULAR CHANNEL INSTALLATION AND MAINTENANCE GUIDELINES Thank you for purchasing the LANDLOK® Turf Reinforcement Mat (TRM) by Propex Operating Company, LLC (Propex). This document provides installation and maintenance guidelines for LANDLOK used as channel armoring to increase channel resiliency towards forces created by high velocities and shear stresses. LANDLOK provides permanent erosion protection on the side slopes and/or bed of a channel. Temporary securing pins (pins) are used during installation to hold LANDLOK in place. Pins also promote vegetation establishment keeping LANDLOK in intimate contact with the soil. LANDLOK is an engineered solution with a unique design for each specific project. While Propex has made every effort to ensure general validity, this information should not be used for a specific application without independent professional examination and verification of its suitability, applicability, and accuracy. The documentation provided herein is for general information only, and is intended to present installation guidance only. Project specific contract documents take precedence when pin placements are different than what is represented in this document. Depending upon the critical nature of the structure to be armored, work restrictions may be in place such as limiting installation based on growing seasons, weather patterns, etc. Work should be performed under the provisions set forth for the specific project. Propex Engineering Services is available for support during installation to consult for solving constructability issues encountered in specific applications. Please feel flee to call our techincal support hotline at (423) 553-2450. BEFORE INSTALLATION BEGINS • Coordinate with a Propex Representative: A pre -construction meeting with the construction team and a representative from Propex is recommended prior to installation. This meeting should be scheduled by the contractor with at least a two week notice prior to construction. • Gather the Tools Needed: Tools that you will need to install LANDLOK include a pair of industrial shears to cut LANDLOK, tape measure, and mallet or hammer. • Determine Vegetation Establishment Strategy: The method of vegetation establishment should be determined prior to the start of installation. Different vegetation establishment methods require different orders of installation. Refer to Establish Vegetation for further guidance. INSTALLATION OF LANDLOK FOR CHANNELS PREPARE THE SITE It is recommended during all stages of site preparation that disturbed soils remain unprotected for not more than a single day. Depending on project size this may require progressive site preparation during installation. 1. Grade and compact the area in the channel where LANDLOK will be installed. The channel surface should be uniform and smooth, having all rocks, clods, vegetation or other objects removed so that during LANDLOK Laydown, LANDLOK comes in direct, intimate contact with the channel surface. 2. Prepare the area to be armored with LANDLOK by loosening the topsoil to promote better vegetation establishment. This may be accomplished with a rotary tiller on slopes 3:1 or flatter. For slopes greater than 3:1, prepare topsoil in a safe manner. 3. Excavate an Initial Channel (IC) trench a minimum of 12 in x 12 in (300 mm x 300 mm) across the channel at the downstream end of the project (Figure 1). Deeper IC trench and/or hard armoring may be required for channels that have the potential for scour. LANDLOK' TRM Page 2 of 13 Figure 1: Initial Channel (IC) Trench 4. Excavate a Crest of Slope (COS) trench a minimum of 12 in x 12 in (300 mm x 300 mm) along both sides of the installation. Each COS trench must be a minimum of 3 ft (900mm) over the crest of the bank, preferably on a relatively flat surface (Figure 2). COMPACTED BACKFILL i T MIN j 1. (900 mm) (300mm) LANDLOK TRM I_j 1 i-I I I -III-III-I I I =I I I -I I I -I I I- - (300mm) I I'I-I I 11 F I 1=1 I =1 I I -I 11=1 I I^I 11= 11=1 11A -1 I -,'PIN ON 1 2" (300I i m) CENTERS NOTE: SEED OR SOD ALL -1 I I I I 1 (III 1I1 I i 111 i 1 DISTURBED AREAS Figure 2: Crest of Slope (COS) Trench 5. Excavate a Terminal Channel (TC) trench a minimum of 12 in x 12 in (300 mm x 300 mm) across the channel at the upstream end of the project (Figure 3). Deeper TC trench and/or hard armoring may be required for channels that have the potential for scour. Propex Operating Company, LLC - 4019 Industry Drive, Chattanooga, TN 37416 - p 800 6211273 - www.propexglobal.com LANDLOK® i A1111111- —� FLOW OF WATER OR COMPACTED BACKFILL DIRECTION OF PREVAILING WIND LANDLOKTRM 711�T11Ti -_—(300 mm)= (300 mm>=1 I - _I- = I- I - I I -I 1 I I=1 _�11= I II I_� PIN ON 12" (300 Prim) CENTERS- -I I1 11 � Ll tI1 =1 11 I I I --I i I -III -I i 1 -I -I =1 I I -I W11 �, �_ I1IIII�IL��-11I I Figure 3: Terminal Channel (TC) Trench 6. If seeding, refer to Vegetation Establishment for additional considerations during site preparation. LANDLOK LAYDOWN Page 3 of 13 1. Starting with the downstream end of the site select one of the COS trenches to begin the LANDLOK Laydown process. To ensure proper anchoring of the overlapped areas the proceeding roll width must be laid out before the current roll width can be anchored with exception to the final roll width at the TIC trench. For straight sections of a channel, LANDLOK panel lengths should be long enough to construct both COS trenches while also covering the surface of the channel being armored. (Figure 17) Panel edges should rest perpendicular to the channel center line. For best results, panels of LANDLOK should be continuous and free frorn seams or roll end overlaps that are parallel to the centerline of the channel. Panel edge overlapping should follow a pattern of placing each proceeding panel's edge overtop the previous panel edge, shingling the panels in the direction of the water flow. FLOW OF WATER OR DIRECTION OF PREVAILING WIND IC TRENCH LANDLOKTRM ' l l III III III -=I ICI I I III=111-III-III - -1 11=III-I I F III-1 I I ;IIFIII(irill Figure 4: Initial Channel (IC) Trench Alignment FLOW OF WATER OR DIRECTION OF PREVAILING WIND IC TRENCH LANDLOKTRM I I I I —III Ili-1Y1_I -I I I=_III1-1 I I -I I I-1 11=111=,111 PIN, 11=1I I=1 11=1 I I I" (- Figure 5: Initial Channel (IC) Trench Placement 2. Lay the LANDLOK panel on the downstream side of the IC trench (Figure 4). Place the panel edge in the IC trench, ensuring full coverage along the bottorn of the entire IC trench with the LANDLOK (Figure 5). 3. Secure LANDLOK with pins in the IC trench (Figure 5). Pins should be rnade of steel with a 0.20 in (5 mm) minimum diameter, having a 1.5 in (38mrn) diameter washer at the head, and a length between 12 and 24 in (300-600 mm) with sufficient ground penetration to resist pullout (Figure 6). Longer pins may be required for looser soils. Heaver metal stakes may be required in rocky soils. Suggested placement of pins for the IC trench is along the bottom of the trench with pins on 12 in (300 mm). Propex Operating Company, LLC - 4019 Industry Drive, Chattanooga, TN 37416 - p 800 621 1273 - Www.propexglobal.com LANDLOK' 1.5" (38 mm) DIAMETER STEEL WASHER 0.20" (5 mm) DIAMETER STEEL 12 - 24" Figure 6: Securing Pin 4. Backfill and compact the IC trench (Figure 5). Page 4 of 13 5. Fold the LANDLOK panel over the top of the compacted IC trench (Figure 7) and place each panel end into the respective COS trenches. 6. Place the next LANDLOK panel by laying the LANDLOK roll so that the roll end points towards the COS trench (Figure 9), with a 3 inch (75 mm) overlap created at adjacent panel edge locations. Ensure that adjacent panel edges maintain a minimum 3 inch (75 mm) overlap during LANDLOK Laydown. (Figure 13) FLOW OF WATER OR DIRECTION OF PREVAILING WIND LANDLOKTRM IC TRENCH =11=I I I=111-111- = =1 I 11 I -I I I 111=1I I I �' 11=1 I -III -I 11=1 1 1=1T- 111=PIN=III-i "-11111iilll-, Figure 7: Initial Channel (IC) Trench Complete FLOW OF WATER OR �~ DIRECTION OF PREVAILING WIND IANDLI TRM ROLL EDGE IC TRENCIi OVERLAP -f17--- M611 _! I I=III-III I LA I Ed 11=1 11=1 I I=' I l i P'_"_I=f i I -III -III I -I!I-gill„„Ili= Figure 8: Initial Channel (IC) Trench Complete and Overlapped 4. Secure LANDLOK with pins in the COS trench (Figure 10). Suggested placement of pins for the COS trench is along the bottom of the trench on 12 in (300 mm) centers. Pins should also be installed on panel edge overlaps in the COS trench. Figure 9: Crest of Slope (COS) Trench Alignment LANDLOK' Figure 10: Crest of Slope (COS) Trench Placement Figure 11: Perpendicular Placement of LANDLOK across Channel 5. Backfill and compact the COS trench in the location of the first LANDLOK panel only (Figure 10). Page 5 of 13 6. Unroll the LANDLOK roll on the channel surface in the area to be armored. (Figure 11) Ensure that LANDLOK has intimate contact with the ground and all irregular surfaces beneath LANDLOK are removed. 7. Secure LANDLOK panels in place using pins across the channel surface according to the project's engineered design. Pin placement should reflect a staggered checkerboard pattern across the channel surface for best results (Figure 12 and Figure 13). • Roll edges shall be overlapped a minimum of 3 in (75 mm) with pins placed on 12 in (300 rnm) centers (Figure 13). 1.25' i 1 1 1 1 1 I 1 (375 mm) ---�----I ---i- ------ --- I 1 I LANDLOKTRM i i 1 2.5' --- i-----.� ----- i --- (750 mm) OFFSET PINS TOCREATE A ---------I------�--- CHECKERBOARD I 1 1 PATTERN 1 I I 2' 4' (60o mm) Figure 12: Example Pin Pattern L A N 0 L 0 K° Page 6 of 13 I FLOW OF WATER OR 4' TYPICAL -� DIRECTION OF PREVAILING WIND (1.2 m) PINS ON 12" CENTERS ON 3" OVERLAP MIN ROLL EDGE OVERLAPS (75 mm) 5' TYPICAL (1.5 m ) I 1 i OFFSET PINS AS SHOWN TO CREATE A CHECKERBOARD PATTERN PIN Figure 13: Example Edge Overlap Pattern • Roll ends shall be overlapped a minimum of 6 in (150 mm) with upstream panel on top. Secure roll end overlaps with two rows of pins staggered 6 in (150 mm) apart on 12 in (300 mm) (Figure 14) NOTE: LANDLOK 450 SHOULD BE SHINGLED IN THE DIRECTION OF THE DOWN SLOPE AND FLOW TOP OF SLOPE / UP STREAM LANDLOK TRM COVERED END FLOW OF WATER OR PIN DIRECTION OF r 1' MAX PREVAILING WIND (300 mm) 6" MIN J (150 mm) l ROLL EDGE OVERLAPPING END BOTTOM OF SLOPE / DOWN STREAM • PIN Figure 14: Roll End Overlap LANDLOK' Page 7 of 13 i • For channel bank heights or channel bottom widths greater than 45 ft (13.7 m), install simulated check slots. This method includes placing two rows of pins 12 in (300 mm) apart on 12 in (300 mrn) centers at 45 ft (13.7 m) maximum intervals or across the midpoint of the slope for slope lengths less than 60 ft (18.2 m) (Figure 15). LANDLOK TRM i 45' MAX OR NEAR MIDPOINT OF SLOPE (13.5 m) 1' MAX • (300 mm) i PIN 1' MAX (300 mm) Figure 15: Simulated Check Slot • At the break in slope interface towards the channel bed, it is suggested that Pins be installed on 12 in (300 mrn) centers (Figure 16). Figure 16: Break In Slope Interface 8. Secure LANDLOK with pins in the opposite COS trench. Suggested placement of pins for the opposite COS trench is along the bottorn of the trench on 12 in (300 mm) centers (Figure 17). 9. Backfill and compact the opposite COS trench in the location of the first LANDLOK panel only (Figure 17). LANDLOKO Figure 17: Crest of Slope (COS) Trenches Complete Page 8 of 13 10. Continue to work down the length of the channel by repeating steps 6 through 9 overlapping each adjacent LANDLOK panel by 3 inches (75 mm) (Figure 13).The last LANDLOK panel should terminate on the Terminal Channel (TC) trench with pins on 12 in (300 mm) centers 11. Lay the last LANDLOK panel on the upstream side of the TC trench (Figure 18). Place the panel edge in the TC trench, ensuring full coverage along the bottom of the entire TC trench with the LANDLOK (Figure 19). 12. Secure LANDLOK with pins in the TC trench. Suggested placement of pins for the TC trench is along the bottom of the trench with pins on 12 in (300 mill) centers (Figure 19). FLOW OF WATER OR DIRECTION OF PREVAILING WIND TC TRENCH LANDLOKTRM itil II1-`III HI-IIII—III—III I� I —I I I-11 I — I 11 =1 I I=1 I I—III=1 II-1 I I I I 1-11l � 11 Figure 18: Terminal Channel (TC) Trench Alignment 13. Backfill and compact the TC trench (Figure 19). FLOW OF WATER OR DIRECTION OF PREVAILING WIND TO TRENCH LANDLOKTRM I IEd I LEI 111-1 i I-_H_ :— l 1-11 >=lT fib —III=1 I I —III —III i M I I-1 I -III- 1-11 11-1 I I=1 I PAW1-11 �11111111111�111—" Figure 19: Terminal Channel (TC) Trench Placement 14. Fold the LANDLOK panel over the top of the compacted TC trench (Figure 20) ensuring a minimum 3 inch (75 mm) overlap and place each panel end into the respective COS trenches. FLOW OF WATER OR DIRECTION OF PREVAILING WIND LANDLOKTRM TCTRENCH ROLL EDGE OVERLAP =1 I I —I I I—i I I —I I I=1 I I —II I I —I �'— "' = Mir III 1' I —I I I: PIN I I-1— 'i1.;�1I11=IIII�IIII. —I 11- Figure 20: Terminal Channel (TC) Trench Complete 10 Propex Operating Company, LLC - 4019 Industry Drive, Chattanooga, TN 37416 - p 800 6211273 - www.propexglobal.com LAN D LO K° Page 9 of 18 i 15. At a rninimum, LANDLOK panels should be pinned entirely across the channel surface, pins should be installed in the trenches, and the trenches should be backfilled and compacted at the end of each day to minimize rework in the case of a major rain event. Specific project conditions may warrant further evaluation of installation order for ease. An example isometric view (Figure 21) of a channel armored with LANDLOK can be seen below for overall reference. Consult Propex tngmeermg Jervlces a Z5UU.OLI.1L / J WILI I tll Iy quGJLIuI lJ LI Ial yuu may IICTvu. PIN LANDLOK 450 TERIAINAL CHANNEL COMPACTED TRENCH DACKFILL TOP OF DANK ANCHOR TRENCH / L . FLOW OF WATER OR • - DIRECTION OF PREVAILING WAND TOP OF DANK ANCHOR TRENCH COMPACTED ..............._..... ... _......__... DACKFILL - - - - PIN LANDLOK 450 ANDLOKTRM OVERLAP AT ROLL EDGE Figure 21: Completed Channel Isometric View 0 LANDLOK' ESTABLISH VEGETATION Page 10 of 13 Vegetation can be established with LANDLOK by broadcast seeding, hydraulic seed application (hydroseeding), or sodding. Seed application rate, seed type, sod type, and irrigation rate should be selected based on local or site specific knowledge and time of year. For best results, consider having a site specific soil test performed to help determine what soil amendments, such as lime and fertilizer, need to be incorporated into the soil to promote healthy vegetation. Irrigate as necessary to establish and maintain vegetation until 75% of vegetation has established and has reached a height of 2 inches. Frequent, light irrigation will need to be applied to seeded areas if natural rain events have not occurred within two weeks of seeding. When watering seeded areas, use a fine spray to prevent erosion of seeds or soil. Do not over irrigate. Proper irrigation guidance is provided under the Maintenance portion of this document. CONSIDER PROJECT SPECIFIC NEEDS 1. A deeper trench and/or hard armoring may be required when channels have severe scour potential at IC and TC trenches. 2. For installing LANDLOK panels around curved sections of a channel, trim panels at an angle so that no more than two layers of LANDLOK overlap at any point in time. Additional pins may be needed to secure panel edges towards the break in slope interface depending upon the radius of the curved channel. Install pins as necessary to securely fasten LANDLOK to the ground. 3. Vehicular traffic should not be allowed on LANDLOK at any time. 4. Disturbed areas should be reseeded. If ruts or depressions develop for any reason, rework soil until smooth and reseed or sod such areas. SHORT-TERM AND LONG-TERM MAINTENANCE OF LANDLOK The purpose of this section is to provide some general guidelines for performing short-term and long-term maintenance of LANDLOK with respect to maintaining vegetation reinforced with LANDLOK, and patching of LANDLOK (in the event it needs to be removed or replaced). These procedures are to be considered rninimum guidelines for proper maintenance, and further maintenance techniques may be appropriate considering local practices and procedures. LANDLOK PROTECTED CHANNEL For LANDLOK to be most effective, it is important to ensure that it is properly maintained both during construction and after construction. Identifying trouble areas is easy with LANDLOK, and it can make identifying potential threats much simpler and manageable. Look for areas with sparse, dying, or no vegetation as these are obvious signs that LANDLOK is losing intimate contact with the channel surface. If loss of ground surface occurs, LANDLOK will need to be removed and reinstalled as described in Patching and Repairs Section after the eroded area is backfilled with compacted soil that is similar to material of the channel. After LANDLOK is reinstalled, re-establish vegetation on the newly installed LANDLOK and disturbed areas. Monitor the sites to determine if frequent watering may be required to establish vegetation. To minimize exposure to unwanted maintenance and repair, LANDLOK armored channels should be free of vehicular traffic. Routine maintenance and channel inspections should be performed by foot traffic only. Tracked equipment such as skid steers, excavators, or dozers should only be allowed to traffic over LANDLOK in tirnes of ernergency after vegetation establishment is complete. Failure to control unauthorized traffic can result in LANDLOK being damaged resulting in erosion below LANDLOK during storm events. Propex Operating Company, LLC - 4019 Industry Drive, Chattanooga, TN 37416 - p 800 6211273 - www.propexglobal.com LAN D LO Km MAINTAINING VEGETATION Page 11 of 13 Good vegetative cover will ensure maximum performance of LANDLOK. Vegetative cover care starts before a project is complete and is ongoing until all LANDLOK is installed. Vegetative cover should be given every opportunity to grow and establish well. This will require that a contractor periodically fertilize and water the grasses as needed until a project is complete in the short- term, with the owner of the slope fulfilling the maintenance of the slope in a sirnilar fashion for the long-term. For the entire lifecycle of LANDLOK, every effort rnust be made to prevent unauthorized encroachments, grazing, vehicle traffic, the misuse of chernicals, or burning during inappropriate seasons. 1. After the installation of vegetation is complete, immediately water and soak the entire area using a fine spray to prevent erosion and loss of seeds. A suggested amount of water is identified below. Prior to installation if using sod, the sod pads in storage should be kept moist at all times and not stored for more than 24 hours frorn site arrival to installation. Warmer weather will necessitate more frequent applications than listed below. A. For each reach/segment of installed vegetation, watering shall be conducted immediately after each installation or the day's work. B. For initial vegetation establishment, water vegetation in a manner consistent with best practices for vegetation type and location. C. Establish a watering schedule and follow until vegetation is well established and will thrive in the absence of manual watering. D. Avoid excessive application of water, so that surface runoff does not occur. Runoff should be prohibited. However, additional watering may be required for repaired or darnaged areas. 2. Fertilizer should be applied as needed to address any nutrient deficiencies revealed in soil testing. 3. Mowing over LANDLOK is not permitted at any time. PATCHING AND REPAIRS LANDLOK rnay require localized repair at times. For emergency repairs, an adequate supply of LANDLOK should be maintained in inventory with the necessary tools to install. This will allow for a timely, initial repair of the systern. 1. In order to identify areas in need of repair, the site should be patrolled immediately after rain events of 2 inches or more. When patrolling look for areas of sparse vegetation, exposed edges of LANDLOK, and areas where direct contact between LANDLOK and the channel surface is compromised. LANDLOK should be rated as Acceptable, Minimally Acceptable, or Unacceptable during inspection. A. Acceptable (A) - The rated area is in satisfactory, acceptable condition, and will function as designed and intended during the rain event. LANDLOK has no exposed edges, is installed tightly by maintaining direct contact to the channel surface with no Tilling beneath, and has over 90% vegetation cover. There is no noticeable damage present. B. Minimally Acceptable (M) - The rated area has a minor deficiency that needs to be corrected. The minor deficiency will not seriously impair the functioning of the area during the next rain event; however, the overall reliability of the project will be lowered because of the minor deficiency. LANDLOK has 75% vegetation cover with ,un-vegetated patches as large as one square yard. Edges of LANDLOK are exposed with noticeable damage. Minimal erosion has occurred underneath LANDLOK. C. Unacceptable (U) - The rated area is unsatisfactory. The deficiency is so serious that the area will not adequately function in the next rain event. LANDLOK has been physically torn, ripped, or lifted from the channel surface. Less than LANOLOKO IT 11 Page 12 of 13 75% vegetation cover is present with un-vegetated patches being greater than 1 square yard, and there is evidence that erosion is occurring beneath LANDLOK. 2. Repair any raised or exposed edges of LANDLOK by driving existing and additional pins along the edges as necessary to securely fasten to the ground. Inspect areas where the vegetation is not growing on top of LANDLOK. Many times this is an indicator that LANDLOK has lost contact with the ground beneath. Check for voids beneath LANDLOK and fill any holes, gullies, etc. with compacted fill material if possible. Replace LANDLOK as described below. 3. To repair LANDLOK, cut out and remove damaged areas in a square configuration a minimum size of 2 ft by 2 ft. Remove all vegetation and debris atop of LANDLOK. Loosen the top 1 to 2 in of soil in the patch area then seed. The subgrade of area to be patched shall be prepared to be smooth and uniform and transition smoothly into the in -situ area. Cut a square LANDLOK patch a minimum of 12 in greater than the damaged area for all four sides of the patch. Overlap the patch area in all directions a minimum of 12 in. The patch overlaps shall be tucked under the existing damaged LANDLOK material (Figure 22 and Figure 23). ---- :... ,ate. VIVId r,...........—..v,....... Figure 22: LANDLOK Patch Cross Section / 61N MAXIMUM CENTER ON CENTER \ • / \i i\• • 2'MINIMUTA / • Y i • / 61MAXIMUM CENTER ON CENTER � • • 12'lAINIMUAI / AREA OF.- i DAMAGED 2'MINIMUM 12'MINIMUM LANDL/OK 450 • PIN Figure 23: LANDLOK Patch Plan View 4. Install pins on 6 in (150 mm) (max) centers. For larger areas of damage, anchors should be installed to match existing anchor pattern. Once LANDLOK is in place, vegetate per project specifications. Propex Operating Company, LLC - 4019 Industry Drive, Chattanooga, TN 37416 - p 800 6211273 - www.propexglobal.com 0 LANOLOK' SUMMARY Page 13 of 13 Maintenance should consist of watering and weeding, repair of all erosion, and any re -seeding as necessary to establish a uniform stand of vegetation during construction and beyond. A minimum of 70% of the armored area should be covered with no bare or dead spots greater than 10 ft2 (1 m2). Throughout the duration of the project, the Contractor should water all grassed areas as often as necessary to establish satisfactory growth and to maintain its growth throughout the duration of the project. After the project is complete, it is the responsibility of the Owner to maintain and upkeep all LANDLOK installed areas for long term performance and best results as described herein for superior slope armoring. IMESCIL Propex Operating Company, LLC - 4019 Industry Drive, Chattanooga, TN 37416 - p 800 6211273 - www.propexglobal.com Storniwater Pollution Prevention Plan Permit No. NCG010000 Appendix I Vegetated Conveyance Agreement All About Plumbing - Building Addition eration & dVlaintenance reement Project Name: All About Plumbing Project Location: 5521 Old Haywood Road, Suite 1, Mills River, NC 28759 Covor 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 (he 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: 0 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: 0 0 0 0 0 0 0 0 0 0 0 0 No No Yes De aaaeo aUtomaticaiin es I acknowledge and agree by my signature below that I am responsible for the performance of (lie 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: Title & Organization: Street address: City, state, zip: Phone number(s): Email: All About Plumbing Caleb Wilson 5521 Old Haywood Rd Mills River, NC 28759 828-778-2425 office@allaboutplumbingne.corn atkf_==,: Signature: Date: / 7 I, isaa(_ r_Da {yYr_ , a Notary Public for (ite State of fl,6*k County of Rej)Aas �do hereby cuuert//ify that (xt� IW d S� personally appeared before me this �— day of N(1V(, l\6fZ_V ` I(_I 2 Z _ and acknowledge (lie due execution of the Operations and Maintenai ce Agreement Witness my hand and official seal, /LOAr Seal " /1i-11i1in 116" My commission expires JVYI& a3i Qwv� STORM-EZ 11/16/2022 Version 1.5 OW Agreement Page 1 of 1 1 dw'pensity laii�te►iance Requiirients'' ;` Important maintenance procedures: The drainage area to the vegetated conveyance or vegetated receiving area will be carefully managed to reduce the sediment load to the vegetated conveyance or vegetated receiving area. After the initial fertilization to establish the grass in the vegetated conveyance or the vegetated receiving area, fe►lilizer will not be applied to the vegetated receiving areas, The vegetated conveyance or vegetated receiving area 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. SCM element: Potential problem: Now to remediate the problem: Vegetation is too short or Maintain grassed vegetation such that the swale or vegetated Vegetation too long, area does not erode during the peak flow from the 10-year storm Trash/debris is present. Remove the trash/debris, Areas of bare soil and/or Regrade the soil if necessary to remove the gully, and then re - Vegetated receiving erosive gullies have sod (or plant with other appropriate species) and water until areas formed. established. Provide lime and a onetime fertilizer application, Trees and/or other woody Remove the trees and woody vegetation from the swale, vegetation are present in regrade the swale if necessary and re-establish grass as shown the swale, on the approved plans, Trash/debris is present, Remove the trash/debris. Areas of bare soil and/or Regrade the soil if necessary to remove the gully, and then re - erosive gullies have sod (or plant with other appropriate species) and water until formed, established, Provide time and a one-time fertilizer application. Sediment covers the grass Remove sediment and dispose in an area that will not impact Vegetated conveyances / at the bottom of the swale. streams or SCMs, Re -sod if necessary, swales / roadside ditches (other than curb The side slope is steeper Regrade the slopes to the permitted configuration per the outlet swales) than the approved approved plan and reestablish vegetation. If as -built or existing configuration, conditions do not allow the slopes to be regraded, contact the applicable permitting agency. Determine the source of the problem: soils, hydrology, disease, Grass is dead, diseased etc, Remedy the problem and replace plants. Provide a one - or dying, time fertilizer application to establish the ground cover if necessary. Tr Trees and/or other woody vegetation are present in Remove the trees and woody vegetation from the vegetated the vegetated conveyance, regrade the vegetated conveyance if necessary conveyance, and reestablish grass as shown on the approved plans, Clogging has occurred. Clean out the outlet device. Dispose of the sediment off. -site. The outlet device (if 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. Discharges from the site The receiving water are causing erosion or Contact the local NCDEQ Regional Office, sedimentation in the receiving water.