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SW6120502_HISTORICAL FILE_20120509
STORMWATER DIVISION CODING SHEET POST -CONSTRUCTION PERMITS PERMIT NO. SW &ZA,021 DOC TYPE ❑ CURRENT PERMIT ❑ APPROVED PLANS HISTORICAL FILE DOC DATE //fD1 YYYYMMDD AfflAaLWKWA NC®ENR North Carolina Department of Environment and Natural Resources . Beverly Eaves Perdue Governor Mr. K. Joshua Hurst, PE Clark Nexsen Architecture & Engineering 4000 We��s��tchase Blvd., Ste. 280 �c7.leiyii, iY,- 276017 Dear Mr. Hurst: Division of Water Quality Charles Wakild, P.E. Director May 9, 2012 Subject: Request for Additional Information Stormwater Project No. SW6120502 Ammo Pointe Blvd. & MacRidge Rd. Improvements Cumberland County Dee Freeman Secretary The Division of Water Quality Central Office received a Stormwater Management Permit Application for the subject project on May 4, 2012. A preliminary review of that information has determined that the application is not complete. As we discussed today on the phone, the following information is needed to continue the stormwater review: 1. The O&M Agreement provided is a photocopy. Please submit an original. 2. This application appears to be for two unrelated road improvement projects in two different locations. The MacRidge Rd. part has no net increase in BUA, and appears to be excluded from permitting under Section 8 of SI- 2006-246. 1 would like to these as two separate projects. There is no fee for requesting a permit exclusion for the MacRidge Rd. part. 3. The pond outlet structure rim elevation is not consistent on the talcs, plans, detail, and supplement form. 4. Note that if the future lane(s) and sidewalk will impact the adjacent wetlands, a 404/401 approval will be needed prior to impacts. 5. Note that table 10-3 may be used for projects in this location instead of table 10-4. Please note that this request for additional infort-rtation is in response to a preliminary review. The requested information should be received by this Office prior to June 9, 2012, or the application will be returned as incomplete. The return of a project will necessitate resubmittal of all required items, including the application fee. If you need additional time to submit the information, please mail or fax your request for a time extension to the Division at the address and fax number at the bottom of this letter. The request must indicate the date by which you expect to submit the required information. The Division is allowed 90 days from the receipt of a completed application to issue the permit. Wetlands and Stormwater Branch 1617 Mail Service Center, Raleigh, North Carolina 27699-1617 Location: 512 N. Salisbury St, Raleigh, North Carolina 27604 Phone: 919-807.63001 FAX: 919.807-6494 !nternet: 4n:vv,no:rate qua!!ty.o g An Equal Opportunity t Affirmative Action Employer Nne orthCarolina Naturally Mr. K. Joshua Hurst, PE SW6120502 - Ammo Pointe Blvd. & MacRidge Rd. Improvements May 9, 2012 The construction of any impervious surfaces, other than a construction entrance under an approved Sedimentation Erosion Control Plan, is a violation of NCGS 143-215.1 and is subject to enforcement action pursuant to NCGS 143-215.6A. All revised original signed documents must he returned or new originals must he provided, Copies are not acceptable. P%ny revised calculations or plans must be sealed, signed, and dated; and have a revision date shown. Please reference the State assigned project number SW6120502 on all correspondence. if you have any questions concerning this matter please feel free to call me at (919) 807-6375, or at robert.patterson@ncdenr.gov. Sincerely, Robert D. Patterson, PE Environmental Engineer Stormwater Permitting Unit cc: �SW6120502 File ec: David Heins - Ft. Bragg DPW Lee Ward - Ft. Bragg DPW / WMB Mike Lawyer - Fayetteville Regional Office Page 2 of 2 �I�IIIIII illll_IIIII IIIII IIIII I1111111 �38967 7 � FROM FAST LANE PICKUP DATE S'-7•-I 7 PICKUP TIME 1 • i ._.,L SAME DAY DRIVER # OF PIECES-L_WEIGHT BILL TO: SHIPPER RECEIVER 3RD PARTY. NEXT DAY CAR VAN ROUND TRIP CHARGES_ CLARK NEXSEN 4000 WESTCHASE BLVD., STE. 280 RALEIGH, NC 27607 (919) 828-1876 JOB# REF# Slr1IQ� 1 DATEr---,—T TIME 41f l 828-0303 TO COMPANY NAMEn STREET ADDRESSI Z N• S� I '�htxry S-�� nn iI ` r CITY KA1�P,roh ST AV' ZIP QXMI CONTACT NAME PHONE # SIGNATURE'//l,�G%� �� �1 n)1,p0•YL Architecture & Engineering 4000 Westchase Boulevard, Suite 280 Raleigh, NC 27607 P. 919.828.1876 F. 919,828.1877 www.claFknexsen.corn transmittal DATE: May 03, 2012 PROJECT: Ammo Pointe Boulevard and MacRidge Road Improvements TO: Stormwater Permitting Unit Division of Water Quality NC Department of Environment and Natural Resources 512 N. Salisbury Street, 9t' Floor, Raleigh, North Carolina 27604 919/807-6300 FROM: K. Joshua Hurst, PE SUBJECT: Post -Construction Stormwater Permit Application COMMISSION NUMBER: 3818 VIA: ROUTE TO: CC: We transmit the following: ® Drawings ❑ Change Order ❑ Computer File(s) D MAY 4 2012 DENR - -- WATER QUALITY b«--- ❑ Specifications ❑ Shop Drawings ❑ Samples ❑ Product Literature ® Calculations Copies Description 1 Stormwater Calculations 2 Construction Plans 2 Stormwater Permit Application (1 original, 1 copy) 1 Wet Detention Basin Supplement 1 Wet Detention Basin O&M Agreement 1 Stormwater Permit Application Fee ($505) Remarks: Attached are the Stormwater Calculations, Plans, Application, Supplement, 0&M Agreement, and Application Fee for the Ammo Pointe Boulevard and MacRidge Road Improvements (PN 70751) at Fort Bragg, for review. Please contact me via email (lhurst@clarknexsen.com) or at 919/576- 2120 if you have questions or need anything else regarding this submittal. Page i of 1 t Au P,w ` o K 4 6 r - 4Q-1 s,, / Application Completeness Review First Submittal ❑ Re -submittal Date Received:5 Date Reviewed Development/Project Name:Am.ri o roe, ke Receiving stream name .$omz: s eAZp E-f_ Classic Liver Basin: CA pE F'F_ L By Bill Diuguid N_ For post -construction requirements, a program will be dee.med compliant for the areas where it is implementing any of the following programs: WS-I, `dVS-II, v"JS-;II, 1JVS-IV, NQW, ORVIV, Neuse River Basin NSW, Tar -Pamlico River Basin NSW, and the Randleman Lake Water Supply Watershed Nutrient Management Strategy, High Density Projects that require a 401/404 within an NSW require 85% TSS, 30% TN and 30% TP removal. T&E Species (Goose Creek, Waxhaw Creek or Six Mile Creek Water Sheds): Al a Latitude and Longitude: 35 OS zf; qq Al -'Z d2 //. °I 1n/ ;urisdictionF e 6v�/� u� Project Address: v Engineer name and firm: a---;��•�� Phone: 9! 9-576 r2-/2,n Email. u X CA -If s C; 0 "Y1 Is the project confirmed to be in the State MSI Stormwater Permit jurisdiction? es or ❑ No ❑ Low Density (no curb and gutter) ❑ Low Density with curb and gutter outlets i en i ❑ Other yjl _-Le401/404 impacts to surface waters, wetlands, and buffers (add language to cover letter and/or add info letter) UA ,Check for $505.00 included W/ Original signature (not photocopy) on application Legal signature (Corporation-VP/higher, Partnership -General Partnerlhigher, LLC-member/manager; Agent). Check spelling, capitalization, punctuation: hitp://www.secretary.state.nc.us/corporations/thepage.aspx If an agent signs the application, a signed letter of authorization from the applicant must be provided which includes the name, title, mailing address and phone number of the person signing the letter. Voor subdivided projects, a signed and notarized deed restriction statement Baled, signed & dated calculations Correct supplement and O&M provided for each BMP on site (check all that were provided & number of each) ❑ Bioretention ❑ Dry Detention Basin ❑ Filter Strip ❑ Grass Swale ❑ Infiltration Basin ❑ Infiltration Trench ❑ Level Spreader ❑ Permeable Pavement ❑ Restored Riparian Buffer ❑ Rooftop Runoff Management ❑ Sand Filter ❑ S�ormwater Wetland et Detention Basin ❑ Low Density ❑ Curb Outlet ❑ Off -Site ❑ NCDOT Linear Road o sets of sealed, signed & dated layout & finish grading plans with appropriate details Description of stormwater management provided ��alrrative Sols report provided bra a T��1-t P P �- --cr—Wetlands delineated or a note on the plans or in the accompanying documents that none exist on site and/or adjacent property M/' Details for the roads, parking area, cul-de-sac radii, sidewalk widths, curb and gutter; w,"' Dimensions & slopes provided Drainage areas delineated Pervious and impervious reported for each ❑ Areas of high density We"' BMP operation and maintenance agreements provided VAppiication complete ❑ Application Incomplete Returned: (Date) is .9 r W sews o 17 TF_('_ May 5, 2011 Revision, Bill Diuguid 3L 2006-246 Section 9 Past Construction Requirements for Non -Coastal Counties Low -density protects ❑ No more than two dwelling units per acre or 24% built -upon area; ❑ Vegetated conveyances to the maximum extent practicable; ❑ Built -upon areas at least 30 feet landward of perennial and intermittent surface waters; ❑ Deed restrictions, protective covenants, and/.nr other restrictive languagelmeasures. High density protects ❑ Control and treat runoff from the first one -inch of rain, ❑ Runoff volume drawdown time must be a minimum of 48 hours, but not more than 120 hours; ❑ Discharge the storage volume at a rate equal to or less than the predevelopment discharge rate for the one-year, 24-hour storm. ❑ Achieve 85% average annual removal of total suspended solids. ❑ For BMPs that require a separation from the seasonal high-water table (SHWT), the separation shall include at least 12 inches of naturally occurring soil above the SHWT. ❑ Stormwater management measures must comply with the General Engineering Design Criteria For All Projects requirements listed in 15A NCAC 2H .1008(c); ❑ All built -upon areas are at least 30 feet landward of perennial and intermittent surface waters, ❑ Deed restrictions, protective covenants, and/or other restrictive language/measures ❑ Provide a mechanism to require long-term operation and maintenance of Best Management Practices Goose Creek, Six Mile Creek and Waxhaw Creek Watersheds Buffer Requirements ❑ Undisturbed riparian buffers within 200 feet of water bodies within the 100-Year Floodplain and within 100 feet of water bodies that are not within the 100-Year Floodplain. Exceptions to the undisturbed buffer requirements are set forth in 15A NCAC 02B .0607 Stormwater Controls as required by 15A NCAC 02B .0602 ❑ Control and treat the difference between the pre -development and post -development conditions for the one- year, 24-hour storm with structural controls. ❑ Development and redevelopment shall implement stormwater management measures that promote infiltration of flows and ground water recharge for the purpose of maintaining stream base flow. ❑ 85% average annual removal of total suspended solids. ❑ Draw down the treatment volume no faster than 48 hours, but no slower than 120 hours, for detention ponds. ❑ Discharge the storage volume at a rate equal or less than the pre -development discharge rate for the one- year, 24-hour storm. ❑ Meet design or stormwater management measures set forth in 15A NCAC 2H .1008. High Density Projects that require a 4011404 within an NSW ❑ 85% TSS ❑ 30% TN ❑ 30% TP May 5, 2011 Revision, Bill Diuguid 13 Architecture & Engineering 4000 Westchase Boulevard, Suite 280 Raleigh, NC 27607 P. 919.828.1876 F. 919.826.1877 www.clarknexsen.com transmittal DATE: We transmit the following: 5-10-12 PROJECT: ® Drawings Chicken Road ACP TO: Robert D. Patterson, PE Wetlands and Stormwater Branch 512 N. Salisbury Street, 9" Floor, Raleigh, North Carolina 27604 FROM: K. Joshua Hurst, PE SUBJECT: Additional Information ❑ Change Order ❑ Computer File(s) ❑ Specifications ❑ Shop Drawings ❑ Samples ❑ Product Literature ® Revised Permit Document Copies Description IFA 1 Revised Construction Plans Original Signed O&M ii11 ��''JJ J 1 SW6120502Ll Ammo Pointe Blvd. & MacRidge L(ENR 2�1� Rd. Improvements Remarks: R QUALITYCOMMISSION NUMBER: at@rBranch 3818 Robert, VIA: Enclosed you will find the revised stormwater documents per your review comment. We have included responses to your comments hPlnw_ cc 1.The O&M Agreement provided is a photocopy. Please submit an original. Response: The original 4&M is enclosed. 2.This application appears to be for two unrelated road improvement projects in two different locations. The MacRidge Rd. part has no net increase in BUA, and appears to be excluded from permitting under Section 8 of SL 2006-246. I would like to these as two separate projects. There is no fee for requesting a permit exclusion for the MacRidge Rd. part. Page Iof2 7 Architecture & Engineering COMMISSION NUMBER: 3818 DATE: 5-10-12 transmittal Response: These projects will be separated. An email was sent on May gth requesting for MacRidge Road to be excluded. 3. The pond outlet structure rim elevation is not consistent on the calcs, plans, detail, and supplement form. Response: The outlet structure has been updated to include slots that drain volumes in excess of the temporary pool. The calcs and supplements were for a structure with slots, however the plans did not accurately depict this. 4. Note that if the future lane(s) and sidewalk will impact the adjacent wetlands, a 404/401 approval will be needed prior to impacts. Response: Acknowledged. 5. Note that table 10-3 may be used for projects in this location instead of table 10-4 Response: Acknowledged. Thank you for your help during this review process and please feel free to contact us should you have any questions. Page 2 of 2 1111111 Hill 111111111111111 IIII IIII 38672 a a c 7 v o 0 0**4 A7 = Cl . S W D a FROM Is-110:4011:04:101 FAST LANE PICKUPDATE I Il� I Q, PICKUP TIME i 3 CC) DRIVER l I/'r # OF PIECES- WEIGHT SAME DAY BILL TO : SHIPPER RECEIVER 3RD PARTY NEXT DAY CAR VAN ROUND TRIP CHARGES 4000 WESTCHASE BLVD., STE. 280 RALEIGH, NC 27607 (919) 828-1876 ram.• .. ., •�. :.. ,,, 828=`0303 TO COMPANY NAME - # . STREET ADDRESS '-�I�KI. I 11_r\i}- CITY �f'1r� ST i�ic� ZIP CONTACT NAME JoB# REF#_ In_ A� PHONE # Q1� - S�`l t „-,C1C� SIGNATURE DATE �Ilhl 1 2_ TIME r��r1 1 I F lul lILY iviap mered by ArcGIS Server )pynghl 2008 ESRI. Ali ngtAs reserved Printed on Fri Oct 212011 0817M AM. Ammo Point Boulevard and MacRidge Road Improvements CN Comm. No. 3818 Stormwater Narrative & Calculations Clark*Nexsen Ammo POINTE BOULEVARD AND MACIRJDGE ROAD IMPROVEMENTS STORMWATER NARRATIVE & CALCULATIONS PERMIT SUBMITTAL 3 May 2012 I?ngineer.(s): Josh Hurst, PIS, Whitney Duff}, PE Wyatt Boric, ICI V 33574 U A CELEBRATING 90 PEARS Architecturr & Engineering 6160 Kemp.wille Circle, Suite 200 AT,Plk, l/,l 23502 111C$FI S Re i.rlrzrlion #C-1028 TABLE OF CONTENTS 1.0 PROJECT INFORMATION ............................................................................................ I 1.1 PROJECT LOCATION AND ]EXISTING CONDITIONS.................................................................. 1 2.0 DESIGN APPROACH ....................................................................................................... 2 2.1 STORM DRAINAGE- 13113INC . .................................................................................................... 2 2.2 WATFR Qu.,u,un, ANALYS1 ..................................................................................................... 3 2.3 WET POND DESIGN .............................................................................................................. 3 2.4 WeVIT RQu,\1.Tn7C,,u,Cul,\'fl0NS .......................................................................................... 3 2.5 WATER QUANTrn? ANALYSIS ................................................................................................ 3 2.5.1. l)Rl,--I-)I,-\TEI.(:)PNfEN'I'CONI:)1'1'ION'; .......................................................................................... 4 2.5.2. POST I)E\'E],OPINil,--N'I'CONDI'l'iON,; ....................................................................................... 4 APPENDIX A: STORM SYSTEM CALCULATIONS APPENDIX B: DRAINAGE AREA MAPS APPENDIX C: EROSION & SEDIMENTATION CONTROL CALCULATIONS APPENDIX D: GEOTECHNICAL REPORT Ammo Pointe Boulevard and MacRidge Road Improvments Calculations CN Comm. No. 3818 Stonnwater Calculations Clark*Nexsen 1.0 PROJECT INFORMATION 1.1 PROJECT LOCATION AND EXISTING CONDITIONS Ammo Pointe Boulevard is an existing roadway that serves as the primary access from Chicken Road to the 108th ADA Complex at the southern end of Fort Bragg. As part of the planned Patriot Point development north of the 108,h ADA Complex, approximately 1,500 linear feet of Ammo Pointe Boulevard will be shifted west on a new alignment. The project will also include traffic signal and turn lane inlprovetnents at the new intersection of Ammo Pointe Boulevard and Chicken Road. The site for the relocated Ammo Pointe Boulevard is east of Bones Creek V on partially to densely wooded lan''he site slopes from a high elevation of approximately 263 feet near the Ammo Pointe Boulevard / Chicken Road intersection to a low of 215 feet near where the new Ammo Pointe Ioulevard ties back, to existing Ammo Pointe Boulevard. The MacRidge Road "Triangle area consists of MacRidge Road which provides access between Chicken and Longstreet Road and Maclidge Triangle Road which provides access for construction traffic. Work in the area will reroute traffic off the existing MacRidge Road approaching Longstreet Road and onto MacRidge Road "Triangle Road approaching Longstreet Road. The general alignment of the construction road will be paged and serve as the new access between Chicken and Longstreet Road. The project will also include a traffic signal northwest of the intersection of MacRidge and MacRidge Traingle Road. The site for the roadway intersection is located on the existing MacRidge Road with a SOl" complex oil the north and a range Oil the south side. The site slopes from a Iligh elevation of approximately 370 feet along AacRidge Triangle Road to a low of 354 feet along MacRidge Road. Project Description "File total drainage area for the Ammo Pointe Boulevard site is 3.98 acres. The pre -development conditions are 5.30/4 impervious whereas the post development conditions are 61.65% impervious. The project site has no existing stormwater treatment. The site currently flows overland from north to south toward Bones Creek. A future \videning of Ammo Pointe Boulevard to a four -lane divided roadwa} is accounted for in the storm calculations and poi 64--'xisting Chicken Road will be widened where the new Ammo Pointe Blvd connects to it. Ammo Pointe Boulevard and MacRidge Road Improvments Calculations CN Comm. No. 3818 Stormwater Calculations C1ark*Nexsen This widening will account for an additional 0.50 acres of BUA that will discharge to the existing grassed road side swales. The total drainage area for the MacRidge Road Triangle site is 1.57 acres. The pre-developmenf conditions are 37.7% impervious whereas the post development conditions are 31.8% imperious. The project site has no existing stormwater treatment. No stonmvater treatment will be provided for these roadway improvements as there will be a reduction in 13UA from predevelopment to post development conditions. The site currently flows overland from the northwest to the southeast down MacRidge Road. 2.0 DESIGN APPROACH 2.1 STORM DRAINAGE PIPING Permanent storm drainage piping systems are designed for a 10-year storm event using the Rational Method for rainfall analysis. Rainfall intensity values were taken from the NOAA website. Runoff coefficients are based on the following values: Description Runoff Coefficient, C Paved and Roof Areas 0.95 Unimproved Areas 0.35 Using 1-laestad StormCAD version 5.5, the pre -development and post development storm water collection system was modeled. An analysis of the hydraulic grade line for the 10-year design rainfall event found the new structures' rim elevations to be above the water level. See Appendix A for detailed information of the post -developed analysis. The new system of pipes and inlets will collect storm water runoff from overland flow from the road area and some grassed areas. The new collection system will outfall into one wet pond to treat the 1" event. 2 Ammo Pointe Boulevard and MacRidge Road Improvments Calculations CN Comm. No. 3818 Stonnwater Calculations Clark*Nexsen 2.2 WATER QUALITY ANALYSIS The calculations for the wet pond system are based on the North Carolina Department of Environment and Natural Resources (NCDI---NR), Stormwater Best Management Practices (l3N41-') Manual, September, 2007. The wet pond was designed for 90% TSS removal rate. The impervious area for the wet pond is 2.45 acres and the drainage area is 3.98 acres. The pre - development percent impervious cover for the basin drainage area was 5.3%; the post development drainage area is 61.6% which was used to find the required volume of treatment of 8,741 ft3. The wet pond provides 10,889 ft3 of storage. 2.3 WET POND DESIGN One new wet pond will be provided on the site, located near the tie-in to existing Ammo Pointe Boulevard on the south end of the alignment. The bottom elevation of the wet pond is at elevation 211.0 feet. A clay liner will be used to maintain the water level at the permanent pool. 2.4 WATER QUALITY CALCULATIONS According to the NCDENR Design Guide, the stormwater treatment system should be designed to remove 90 percent of the average annual post development total suspended solids (1'SS), 40 percent of the average annual post development total phosphorus (113), and 25 percent of the average annual post development total nitrogen (1N) by implementing Best Management Practices (BMP's). 2.5 WATER QUANTITY ANALYSIS The wet pond routing was performed using the rational hydrograph storage estimation method in the l-iydraflow Hydrographs 2009 computer program. The analysis indicates that the total site post development condition peak ninoff for all the design storms is less than the predevelopment conditions. 3 a Ammo Pointe Boulevard and MacRidge Road Improvments Calculations CN Comm. No. 3818 Stormwater Calculations Clark*Ncxsen 2.5.1. PREDEVELOPMENT CONDITIONS The table below summarizes the predevelopment conditions peak runoff. Predevelopment Condition Peak Runoff Summary 1-year Peak 10-year Peak 100-year Peak Runoff (cfs) Runoff (cfs) Runoff (cfs) Total Existing Drainage 7.81 11.97 15.55 Area Runoff 2.5.2. POST DEVELOPMENT CONDITIONS The post development site drains from Chicken Road to the south and outfalls into the new wet pond. The method of conveyance is overland flow and piped system that includes catch basins. Construction details are provided on the plans; storm system sizing and basin routing calculations are provided in Appendix A. The table below summarizes the post development conditions peak runoff. Post development Condition Peak Runoff Summary 1-year Peak 10-year Peak 100-year Peak Runoff (cfs) Runoff (cfs) Runoff (cfs) Post Development Drainage — 14.80 22.68 29.46 Routed To BMP The analysis shows a decrease in post development runoff for all storm events analyzed. The table below summarizes the total predevelopment and post development runoff for the project. E Ammo Pointe Boulevard and MacRidge Road Improvments Calculations CN Comm. No. 3818 Stonnwater Calculations Clark*Ncxsen 1-year 10-year 100-year Peak Peak Peak Runoff Runoff Runoff (cfs) (cfs) (cfs) Total Predevelopment Runoff 7.81 11.97 15.55 Total Post Development Runoff With Pond 0.05 0.06 0.07 Net Difference in Runoff -7.76 -11.91 -15.48 a Profile Report Engineering Profile - Profile - A-1 to Pond (APB StormCAD_Full build_updated.stc) 265.00 ---j--A-1 ! Rio Inv 260.00 I 255.00 1-1k N.0 ft Circutai Pipe - 1 i 250.00 c 0 y ! 'L 240.00 235-00 i4 230,00 225.00 220.00 -0+50 0+00 0+50 1+00 1+50 2+00 2+50 3+00 3+50 4+p0 4+50 5-GO 5+50 6+00 6+50 7+00 7+50 8+00 8+50 9+00 9+50 10+00 10+50 11+00 11+50 12+00 12+50 13+00 13+50 14+00 Station Ift) ft Bft 6.00 ft 20.50 ft Bentley StormCAD V8i (SELECTseries 2) APB StormCAD_Full build_updated.stc Bentley Systems, Inc- Haestad Methods Solution Center [08.11.02.35) 2127/2012 27 Siemon Company Drive Suite 200 VV Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 1 AMMO POINTE BOULEVARD FORT BRAGG, NC 100% DESIGN SUBMITTAL FEBRUARY 2012 CAPACITY ANALYSIS AND DOT REPORT Label Upstream Inlet Area (acres) Upstream Rational Flow (ft31s) Upstream CA (acres) System CA (acres) System Intensity (inlh) Section Discharge Capacity (ft�ls) Length (User Defined) (ft} Slope (ft/ft) Conduit Description -Invert- Upstream Downstream (ft) Cover (Start) (ft) Cover (Stop) (ft) -HGL- Upstream Downstream (ft) -Ground- Upstream Downstream (ft) 3-4 0.334 7.41 1.257 1.257 5.850 7.41 303.0 0.045 Circular Pipe - 15.0 in 244.76 3.21 3.86 245.84 249.22 13.66 231.21 232.67 236.32 4-5 0.170 10.28 1.777 1.777 5.736 10.28 155.0 0.033 Circular Pipe - 15.0 in 231.21 3.86 3.85 232.40 236.32 11.72 226.11 227.74 231.21 5-6 M73 12.16 2.126 2.126 5.674 12.16 206.0 0.020 Circular Pipe - 18.0 in 226.11 3.60 3.83 227.43 231.21 14.69 222.08 223.98 227.41 6-8 0.056 14.11 2.509 2.509 5.579 14.11 38.0 0.042 Circular Pipe - 18.0 in 222.08 3.83 4.00 223.46 227.41 21.42 220.50 221.47 226.00 2-3 0.161 4.29 0.709 0.709 6.008 4.29 303.0 0.028 Circular Pipe - 15.0 in 253.19 5.60 3.21 254.03 260.04 10.77 244.76 246.01 249.22 1-1A 0.252 1.39 0.208 0.208 6.630 1.39 68.0 0.003 Circular Pipe - 15.0 in 254.30 3.40 3.58 255.00 258.95 3.59 254.09 254.96 258.92 1A-2 NIA 2.76 0.427 0.427 6.413 2.76 300.0 0.003 Circular Pipe - 15.0 in 254.09 3.58 5.60 254.92 258.92 3.54 253.19 254.12 260.04 5A-5 0.154 2.02 0.303 0.303 6.596 2.02 31.0 0.003 Circular Pipe - 15.0 in 226.20 3.00 3.85 227.77 230.45 3.54 226.11 227.74 231.21 4A-4 0.162 2.66 0.400 0.400 6.599 2.66 31.0 0.003 Circular Pipe - 15.0 in 231.31 3.00 3.86 232.72 235.56 3.67 231.21 232.67 236.32 7-7A 0.245 1.24 0.186 0.186 6.630 1.24 28.0 0.003 Circular Pipe - 15.0 in 222.25 3.00 3.53 224.00 226.50 3.66 222.16 223.99 226.94 7A-6 NIA 1.25 0.216 0.216 5.759 1.25 24.0 0.003 Circular Pipe - 15.0 in 222.16 3.53 4.08 223.99 226.94 3.73 222.08 223.98 227.41 6A-7A 0.133 0.20 0.030 0.030 6.630 0.20 33.0 0.017 Circular Pipe - 15.0 in 222.71 3.00 3.53 223.99 226.96 8.34 222.16 223.99 226.94 2/27/2012 DOT Report - Ammo Pointe Blvd AMMO POINTE BOULEVARD FORT BRAGG, NC 100% DESIGN SUBMITTAL FEBRUARY 2012 Spread Calculations Label Efficiency (%) Discharge (ft3/s) Slope (ft/ft) Grate Width (ft) Intercepted Flow (ft3/s) Bypass Flow (ft3/s) Spread (ft) Depth (ft) Flow Area (ft2) Velocity (ft/s) Combination Inlet On Grade - 1-1 95.28 0.83 0.0301 1.51 0.79 0.04 3.75 0.16 0.21 3.99 Combination Inlet On Grade - 1-2 99.97 0.59 0.05 1.5 0.59 0.00 2.30 0.14 0.12 4.91 Combination Inlet On Grade - 1-3 93.83 1.08 0.05 1.5 1.01 0.07 3.77 0.17 0.21 5.15 Combination Inlet On Grade - 1-4 100.00 0.48 0.051 1.5 0.48 0.00 1.81 0.13 0.1 4.78 Combination Inlet On Grade - 1-5 100.00 0.14 0.05 1.5 0.14 0.00 0.99 0.08 0.04 3.52 Combination Inlet On Grade - 1-6 100.00 0.19 0.0163 1.51 0.19 0.00 1.36 0.11 0.07 2.49 Combination Inlet On Grade - I-4A 100.00 0.53 0.05 1.51 0.53 0.00 2.04 0.13 0.11 4.85 Combination Inlet On Grade - I-5A 100.00 0.19 0.05 1.51 0.19 0.00 1.10 0.09 0.05 3.79 Combination Inlet On Grade - I-6A 1 97.95 0.57 0.0163 1.51 0.56 0.01 3.56 0.16 0.19 2.92 Comination Inlet in Sag - 1-7 N/A 0.68 N/A 1.5 N/A N/ I Al 2.051 0.12 N/A N/A Project Information WET DETENTION POND 1 Project Name: Ammo Pointe Blvd Project #: 3818 Designed by: WLS Date: 4/6/2012 Checked by: KJH Date: 416/2012 Site Information Sub Area Location: Wet Pond 1 Drainage Area (DA) = 173,433 sf Impervious Area (IA) = 106,914 sf Percent impervious (I) = 61.6 % Elevations Top of Bank Elevation = 224.00 it Emergency Elevation = 222.50 ft Temporary Pool Elevation = 221.50 Permanent Pool Elevation = 220.50 ft Bottom of Pond Elevation = 212.00 If Sediment Cleanout, Bottom Elevation = 211.00 ft Basin Areas/Volumes Area of Permanent Pool = 9,250 sf Area of Bottom of Shelf = 7.435 sf Area of Bottom of Pond = 550 sf Area of Temporary Pool = 12,184 sf Volume, main pool = 22,859 cf Volume, forebay (sum of forebays) = 6,100 cf Volume, permanent pool = 28,959 cf Forebay % of permanent pool volume = 211 % Average Depth A parrrpool (includes main pond & forebays) (Elev = 220.50 ) A p„ fhe1r (includes main pond & forebays) A bo, p d (excluding sediment storage & forebays) A lempyond (includes main pond and forebays) (Elev = 221,50 J Vmein_pool (from Hydraflow) V,Ofepey (from Hydraflow) V perm pool (VioreheY+Vmein_pool) OK Depth of Pond = 8 ft Depth (dist. btwn. bot. of shelf & btm. of pond, excludes sediment) Average Depth = 4.75 ft Use Average Depth of = 4.50 ft Round down to nearest 0.5 Required Surface Area - Wetland SAIDA = 4.92 (90% TSS Removal via Pond) Min Req'd Surface Area = 8,533 sf (at Permanent Pool) Required Storage Volume - Using Simple Method Design Storm = 1 inch (Project Does Not Drain to SA waters) Determine Rv Value = 0.05 + 0.009 (I) = 0.60 inlin Storage Volume Required = 8,741 cf (above Permanent Pool) Side Slopes of Pond = 3 :1 Is Permenant Pool Surface Area Sufficient (yes/no)? Yes ( 9250 n 8533 ) sf WET DETENTION POND 1 1.0" Volume Elevation Required Temporary Pool Volume = 8,741 cu ft Temporary Pool Lower Elevation Bound = 221.00 Temporary Pool Upper Elevation Bound = 222.00 Temporary Pool Lower Volume Bound = 5,114 cu ft Temporary Pool Upper Volume Bound = 16,980 cu ft Temporary Pool Elevation = 221.50 Orifice Sizing - Wet Detention 02D.,= 0.0630 cfs 05Dara= 0.0252 cfs Orifice Size = 1.75 in Driving Head (Ho) = 0.31 ft 0 onR_ = 0.045 cfs Drawdown Time = 2.3 days less than 5 days (yeslno) ? Yes greater than 2 days (yestno) ? Yes Anti -Flotation Device 4-ft x 4-ft Riser Box Top of Riser: 222.71 sf Invert of Riser: 220.50 cf Area: 16.0 st Volume: 35 cf Weight: 2,206 Ibs Factor of Safety 1.10 WT Req'd of Anti -Flotation Device: 2,427 Ibs Volume of Concrete Req'd: 27.7 cf Depth Provided: 1.75 ft Volume Provided: 28.0 cf WT of Anti -Flotation Device Provided: 2,453 Ibs Contour Contour Area Incremental Accumulated Volume Volume, S Stage, Z sq ft cu ft cu ft ft 220.50 9,250 0 0 0.00 221.00 11,241 5,114 5,114 0.50 221.50 11,866 5,775 10,889 1.00 222.00 12,505 6.091 16,980 1.50 223.00 13,825 13,158 30,138 2.50 224.00 15,202 14,507 44,645 3.50 (Flowrate required for a 2 day drawdown) (Flowrate required for a 5 day drawdown) (Diameter) (Top of Riser {Elev. 222.711 - Bottom of Riser [Elev. 220.501) (Outside Dim. = 4-ft x 4-ft, Inside Dim. = 3-ft x 3-ft) (Water Displaced - Top of Riser to Invert of Riser) (Weight Water Displaced) (Unit WT of Concrete = 150 pcf) Submerged Concrete Unit Weight 87.6 pcf (4-ft x 4-11 Box filled 1.75-ft deep with concrete) OK Hydraflow Table of Contents Pond.gpw Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, Inc. vB 1 - Year Friday, Apr 6, 2012 SummaryReport ......................................................................................................................... 1 HydrographReports................................................................................................................... 2 Hydrograph No. 1, Rational, Rational Pre................................................................................ Hydrograph No. 2, Rational, Rational Post.............................................................................. 3 Hydrograph No. 4, Reservoir, Rational Post wl Pond............................................................. 4 PondReport - Pond............................................................................................................. 10 - Year SummaryReport......................................................................................................................... 6 HydrographReports.......................................................................................... Hydrograph No. 1, Rational, Rational Pre................................................................................ 7 Hydrograph No. 2, Rational, Rational Post.............................................................................. 8 Hydrograph No. 4, Reservoir, Rational Post wl Pond............................................................. 9 100 - Year SummaryReport ....................................................................................................................... 10 HydrographReports................................................................................................................. 11 Hydrograph No, 1, Rational, Rational Pre.............................................................................. 11 Hydrograph No. 2, Rational, Rational Post............................................................................ 12 Hydrograph No. 4, Reservoir, Rational Post wl Pond........................................................... 13 Hydrograph Summary Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, lnc. v8 Hyd. No. Hydrograph type (origin) Peak flow (cfs) Time interval (min) Time to Peak (min) Hyd, volume (cult) Inflow hyd(s) Maximum elevation (ft) Total strge used (tuft) Hydrograph Description 1 Rational 7.813 1 5 2,344 ------ -- - ---- Rational Pre 2 Rational 14.80 1 5 4,441 ------ ------ ----- Rational Post 4 Reservoir 0.047 1 10 3,885 2 220.93 4,426 Rational Post w/ Pond Pond.gpw Return Period: 1 Year Friday, Apr 6, 2012 d ro ra h Report 2 H` Y 9 p` Hydraffow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, Inc. v8 Friday, Apr 6, 2012 Hyd. No. 1 Rational Pre Hydrograph type = Rational Peak discharge = 7.813 cfs Storm frequency = 1 yrs Time to peak = 5 min Time interval = 1 min Hyd. volume = 2,344 cuft Drainage area = 3.980 ac Runoff coeff. = 0.38* Intensity = 5.166 inlhr Tc by User = 5.00 min OF Curve = Ft. Bragg.IDF Asc/Rec limb fact = 111 ' Composite (Area/C) = [(0.200 x 0.95) + (3.780 x 0.35)] 13.980 Q (cfs) 8.00 .M Mid 2.00 Rational Pre Hyd, No. 1 -- 1 Year Q (cfs) 8.00 4.00 2.00 0.00 K_ , I I I I I I I _I -- v 0.00 0 1 2 3 4 5 6 7 8 9 10 Hyd No. 1 Time (min) Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, Inc. v8 Hyd. No. 2 Rational Post Hydrograph type = Rational Storm frequency = 1 yrs Time interval = 1 min Drainage area = 3.980 ac Intensity = 5.166 inlhr OF Curve = Ft. Bragg.IDF Composite (Area/C) = [(2.450 x 0.95) + (1,530 x 0.35)113.980 Q (cis) 15.00 12.00 R114181 N. fe 3.00 0.00 --X 0 3 Friday, Apr 6, 2012 Peak discharge = 14.80 cfs Time to peak = 5 min Hyd. volume = 4,441 cult Runoff coeff. = 0.72W Tc by User = 5.00 min Asc/Rec limb fact = 1 /1 Rational Post Hyd. No. 2 -- 1 Year 1 2 3 4 5 6 7 8 Hyd No. 2 Q (cfs) 15.00 12.00 Wile] MI 3.00 ` 0,00 9 10 Time (min) Hydrograph Report `4 Hydraflow Hydrographs Extension for AutoCAD® Civil 3DO 2011 by Autodesk, Inc. v8 Hyd. No. 4 Rational Post w/ Pond Hydrograph type = Reservoir Storm frequency = 1 yrs Time interval = 1 min Inflow hyd. No. = 2 - Rational Post Reservoir name = Pond Storage Indication method used. Q (cfs) 15.00 M1117 m . to c r� 0.00 -8 0 Peak discharge Time to peak Hyd. volume Max. Elevation Max. Storage Rational Post wl Pond Hyd. No. 4 -- 1 Year Friday, Apr 6, 2012 = 0.047 cfs = 10 min = 3,885 cult = 220.93 ft = 4,426 cuft Q (cfs) 15.00 12.00 ms, "O olt 3.00 0.00 300 600 900 1200 1500 1800 2100 2400 2700 3000 Time (min) Hyd No. 4 Hyd No. 2 [EEEEW Total storage used = 4,426 cuff Pond Report Hydraftow Hydrographs Extension for AutoCADO Civil 300 2011 by Autodesk, Inc. v8 Friday, Apr 6, 2012 Pond No. 1 - Pond Pond Data Contours -User-defined contour areas. Conic method used for volume calculation, Begining Elevation = 220.50 ft Stage 1 Storage Table Stage (ft) Elevation (ft) Contour area (sgft) Incr. Storage (cult) Total storage (cult) 0,00 220.50 9,250 0 0 0.50 221,00 11,241 5,114 5,114 1.00 221.50 11,866 5,775 10,890 1.50 222.00 12,505 6,091 16,981 2.50 223.00 13,825 13,158 30,139 3.50 224.00 15,202 14,507 44,646 Culvert 1 Orifice Structures Weir Structures [A) [B] [C] [PrfRsr] [A] [131 [C] [D] Rise (in) = 18.00 1.75 6.00 0.00 Crest Len (ft) = 12.00 20.00 0.00 0.00 Span (in) = 18.00 1.75 36.00 0.00 Crest El. (ft) = 222.71 222.50 0.00 0.00 No. Barrels = 1 1 3 0 Weir Coeff. = 3.33 3.33 3.33 3.33 Invert El. (ft) = 220,50 220.50 221.50 0.00 Weir Type = 1 Ciplti - --- Length (ft) = 33.67 0.00 0,00 0.00 Multi -Stage = Yes No No No Slope (%) = 0.30 0.00 0.00 nla N-Value = .013 .013 .013 nla Orifice Coeff. = 0.60 0.60 0.60 0.60 Exfil.(inlhr) = 0,000 (by Contour) Multi -Stage = nla Yes Yes No TW Elev. (ft) = 0.00 Stage (ft) 4,00 3.00 2,00 1.00 Note. CulvertlOdfice outflows are analyzed under inlet (ic) and outlet (oc) control, Weir risers checked for orifice conditions (ic) and submergence (s). Stage 1 Discharge Ell (ft) 224.50 223,50 222.50 221,50 0,00 220.50 0.0 10.0 20.0 30.0 40.0 50.0 60.0 70.0 80.0 90.0 100.0 110.0 120.0 130.0 140.0 Total Q Discharge (cfs) 6 Hydrograph Summary Report Hydraftow Hydrographs Extension for AutoCAl]®Civil 3DO 2011 by Autodesk, Inc. v8 Hyd. No. Hydrograph type (origin) Peak flow (cfs) Time interval (min) Time to Peak (min) Hyd. volume (cult) Inflow hyd(s) Maximum elevation (ft) Total strge used (cuft) Hydrograph Description 1 Rational 11.97 1 5 3,5911 - ------ ------ Rational Pre 2 Rational 22.68 1 5 6,805 - --- --- --- Rational Post 4 Reservoir 0.059 1 10 5,938 2 221.14 6,785 Rational Post w! Pond Pond.gpw Return Period: 10 Year Friday, Apr 6, 2012 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAIM Civil 3D® 2011 by Autodesk, Inc. v8 Hyd. No. 1 Rational Pre Hydrograph type = Rational Storm frequency = 10 yrs Time interval = 1 min Drainage area = 3.980 ac Intensity = 7.915 inthr OF Curve = Ft. Bragg.IDF " Composite (Area1C) = [(0.200 x 0.95) + (3,780 x 0.35)] / 3.980 Q (cfs) 12,00 10.00 m Am 4.00 W1191 7 Friday, Apr 6, 2012 Peak discharge = 11.97 cfs Time to peak = 5 min Hyd. volume = 3,591 cuft Runoff coeff. = 0.38* Tc by User = 5.00 min Asc/Rec limb fact = 111 Rational Pre Hyd. No. 1 -- 10 Year 0.00 -= 1 1 1 1 k I 0 1 2 3 4 5 6 7 Hyd No. 1 0 (cfs) 12.00 10.00 [•111I0] M 4.00 "1 0.00 8 9 10 Time (min) Hydrograph Report Hydraftow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, Inc. v8 Hyd. No. 2 Rational Post Hydrograph type = Rational Storm frequency = 10 yrs Time interval = 1 min Drainage area = 3.980 ac Intensity = 7.915 inlhr OF Curve = Ft. Bragg.IDF * Composite (Area/C) = 1(2.450 x 0.95) + (1.530 x 0.35)1/ 1980 Q (cfs) 24.00 20.00 16.00 12.00 M 4.00 Friday, Apr 6, 2012 Peak discharge = 22.68 cfs Time to peak = 5 min Hyd. volume = 6,805 cuft Runoff coeff. = 0.72* Tc by User = 5.00 min Asc/Rec limb fact = 111 Rational Post Hyd. No. 2 -- 10 Year Q (cfs) 24.00 20.00 16.00 12.00 I &MM 4.00 0.00 v ' 1 1 ! 1 1 1 1 1 N 0.00 0 1 2 3 4 5 6 7 8 9 10 Hyd No. 2 Time (min) Hydrograph Report 9 Hydraflow Hydrograp hs Extension for AutoCAD® Civil 3D® 2011 6y Autodesk, Inc. v8 Friday, Apr 6, 2012 Hyd. No. 4 Rational Post wl Pond Hydrograph type = Reservoir Peak discharge = 0.059 cfs Storm frequency = 10 yrs Time to peak = 10 min Time interval = 1 min Hyd. volume = 5,938 cult Inflow hyd. No. = 2 -Rational Post Max. Elevation = 221.14 ft Reservoir name = Pond Max. Storage = 6,785 cult Storage Indication method used. Q (cfs) 24.00 20.00 16.00 12.00 8.00 4.00 0.00 0 300 600 Hyd No. 4 Rational Post wl Pond Hyd. No. 4 -- 10 Year Q (cfs) 24.00 20.00 16.00 12.00 4,00 1 I I I ' 0.00 900 1200 1500 1800 2100 2400 2700 3000 Time (min) Hyd No. 2 [1=1� L1=1� Total storage used = 6,785 cult Hydrograph Summary Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, Inc. v8 Hyd. No. Hydrograph type (origin) Peak flow (cfs) Time interval (min) Time to Peak (min) Hyd. volume (tuft) Inflow hyd(s) Maximum elevation (ft) Total strge used (cuft) Hydrograph Description 1 Rational 15.55 1 5 4,664 -- --- -- - Rational Pre 2 Rational 29.46 1 5 8,837 ------ ----- ----- Rational Post 4 Reservoir 0.067 1 10 7,529 2 221.32 8,813 Rational Post w/ Pond Pond.gpw Return Period: 100 Year Friday, Apr 6, 2012 11 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil MID 2011 by Autodesk, Inc. v8 Friday, Apr 6, 2012 Hyd. No. 1 Rational Pre Hydrograph type = Rational Peak discharge = 15.55 cfs Storm frequency = 100 yrs Time to peak = 5 min Time interval = 1 min Hyd. volume = 4,664 cuft Drainage area = 3.980 ac Runoff coeff. = 0.38* Intensity = 10.279 in/hr Tc by User = 5.00 min OF Curve = Ft. Bragg.IDF Asc/Rec limb fact = 1/1 Composite (Area1C) _ [(0.200 x 0.95) + (3.780 x 0.35)] / 3.980 0 (cfs) 18.00 15.00 12.00 • m 3.00 Rational Pre Hyd. No. 1 -- 100 Year 0 (cfs) 18.00 15.00 12.00 3.00 0.00 V I I _ I I 1 l I 1 I V 0.00 0 1 2 3 4 5 6 7 8 9. 10 Time (min) Hyd No. 1 12 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2011 by Autodesk, Inc. v8 Friday, Apr 6, 2012 Hyd. No. 2 Rational Post Hydrograph type = Rational Peak discharge = 29.46 cfs Storm frequency = 100 yrs Time to peak = 5 min Time interval = 1 min Hyd. volume = 8,837 cult Drainage area = 3.980 ac Runoff coeff. = 0.72* Intensity = 10.279 inlhr Tc by User = 5.00 min OF Curve = Ft. Bragg.IDF Asc/Rec limb fact = 111 * Composite (Area1C) = [(2.450 x 0.95) + (1.530 x 0.35)] 13.980 Q (cfs) 30.00 25.00 15.00 10.00 5.00 Rational Post Hyd. No. 2 -- 100 Year Q (cfs) 30.00 25.00 20.00 15.00 10.00 5.00 0.00 V I , I I I I 1 I I N 0.00 0 1 2 3 4 5 6 7 8 9 10 Hyd No. 2 Time (min) 13 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3DID 2011 by Autodesk, Inc. v8 Friday, Apr 6, 2012 Hyd. No. 4 Rational Post wl Pond Hydrograph type = Reservoir Peak discharge = 0.067 cfs Storm frequency = 100 yrs Time to peak = 10 min Time interval = 1 min Hyd. volume = 7,529 cuft Inflow hyd. No. = 2 -Rational Post Max. Elevation = 221.32 ft Reservoir name = Pond Max. Storage = 8,813 cuft Storage Indication method used. Q (cfs) 30.00 25.00 20.00 15.00 10.00 5.00 0.00 0 300 Hyd No. 4 Rational Post wl Pond Hyd. No. 4 -- 100 Year 600 900 1200 Hyd No. 2 1500 1800 2100 2400 2700 fI TMjj Total storage used = 8,813 tuft Q (cfs; 30.00 25.00 20.00 15.00 10.00 5.00 --1- 0.00 3000 Time (min) h - - - - - - - - - - - - - - . 10 ((f PRE -DEVELOPMENT PROJECT DRAINAGE AREA MAP MACRIDGE ROAD FORT BRAGG, NTC FEBRUARY, 2012 SCALE NMR a 160. zaa' --------------- o�.;*ll POST -DEVELOPMENT PROJECT DRAINAGE AREA MAP MACRIDGE ROAD FORT BRAGG, NC FEBRUARY, 2012 SCALE OUR 0 10D' 200' I ,",1 1:01 IMPEPVIOVS-8.757 SF PERVIOUS-164.676 SF c-am m To 7 77=11 7 - It I AT/.' �� hf_�_ 77 P j LVD PRE -DEVELOPMENT PROJECT DRAINAGE AREA MAP AMMO POINTE BOULEVARD FORT BRAGG, NC FEBRUARY, 2012 SCALE 0 160, 200' POST -DEVELOPMENT PROJECT DRAINAGE AREA MAP AMMO POINTE BOULEVARD FORT BRAGG, NC FEBRUARY. 2012 SCALE mm 0 160, 200' M\ POST -DEVELOPMENT PROJECT DRAINAGE AREA MAP AMMO POINTE BOULEVARD FORT BRAGG, NC FEBRUARY, 2012 SCALE 0 100' 200' APPENDIX C EROSION AND SEDIMENTATION CONTROL CALCULATIONS DESIGN OF RIPRAP OUTLET PROTECTION WORKSHEET Project Ammo Point Boulevard Date Apr-06-2012 Location Fort Bragg, NC Designed W. Bone Project No. 3818 Checked K. Hurst Outlet ID Skimmer Outlet Pipe diameter 4 inches Pipe slope 0.5 percent Roughness Coe£ 0.013 Full Flow Capacity 0.13 cfs Full now velocity 1.54 ft/sec o 0 1 2 3 4 5 6 7 8 9 10 Pipe diameter (ft) Zone from graph above = 1 Is grade of apron 10% or more Y YIN Zone used = 1 Outlet pipe diameter 4 in. Outlet flowrate 0.1 cfs Outlet velocity 1.54 ft/sec Material = Class A Length = 1.3 ft. Width at Outlet = 1.0 ft. Width at end of Pad 2.5 ft. Stone diameter= 4 in. Thickness = 9 in. Zone Material Diameter Thickness I Length 1 Class A 4 9 4 x D(o) 2 Class B 8 18 6 x D(o) 3 Class I 10 25.5 8 x D(o) 4 Class I 10 25.5 8 x D(o) 5 Class II 14 34.5 10 x D(o) 6 Class II 14 34.5 10 x D(o) 7 Special study required Calculations based on NY DOT method - Pages 8.06.05 through 8.06.06 in NC Erosion Control Manual Rip Rap Apron Design 4/6/2012 DESIGN OF RIPRAP OUTLET PROTECTION WORKSHEET Project Ammo Point Boulevard Date Apr-06-2012 Location Fort Bragg, _ NC Designed W. Bone T Project No. 3818 Checked K. Hurst Outlet ID A-8 Pipe diameter 18 inches Pipe slope 0.6 percent Roughness Coef. 0.013 Full Flow Capacity 8.14 efs Full flow velocity 4.60 ft/sec Zoac 2 0 0 l 2 3 4 5 6 7 8 9 10 Pipe diameter (ft) Zone from graph above = Is grade of apron 10% or more Y Y/N Zone used = Outlet pipe diameter 18 in. Outlet llowrate 8.1 cfs Outlet velocity 4.60 it/sec Material = Class A Length = 6.0 ft. Width at Outlet = 4.5 ft. Width at end of Pad 11.4 ft. Stone diameter= 4 in. Thickness = 9 in. Zone Material Diameter Thickness I Length 1 Class A 4 9 4 x D(o) 2 Class B 8 18 6 x D(o) 3 Class 1 10 25.5 8 x D(o) 4 Class I 10 25.5 8 x D(o) 5 Class II 14 34.5 10 x D(o) 6 Class 1I 14 34.5 10 x D(o) 7 Special study required Calculations based on NY DOT method - Pages 8.06.05 through 8.06.06 in NC Erosion Control Manual Rip Rap Apron Design 4/6/2012 DESIGN OF RIPRAP OUTLET PROTECTION WORKSHIEET Project Ammo Point Boulevard Date Apr-06-2012 Location Fort Bragg, NC Designed W. Bone Project No. 3818 Checked K. Hurst Outlet ID C3 Pipe diameter 36 inches Pipe slope 0.3 percent Roughness Coef. 0.013 Full Flow Capacity 36.53 cfs Full flow velocity 5.17 f /sec — e a-4- 0 0 1 2 3 4 5 6 7 8 9 10 Pipe diameter (ft) Zone from graph above = 1 Is grade of apron 10% or more N Y/N Zone used = I Outlet pipe diameter 36 in. Outlet flowrate 36.5 cfs Outlet velocity 5.17 It/sec Material = Class A Length = 12.0 ft. Width at Outlet = 9.0 ft. Width at end of Pad 22.9 ft. Stone diameter = 4 in. Thickness = 9 in. Zone Material Diameter Thickness I Length 1 Class A 4 9 4 x D(o) 2 Class B 8 18 6 x D(o) 3 Class I 10 25.5 8 x D(o) 4 Class 1 10 25.5 8 x D(o) 5 Class 11 14 34.5 10 x D(o) 6 Class II 14 34.5 10 x D(o) 7 Sp eciai study required Calculations based on NY DOT method - Pages 9.06.05 through 8.06.06 in NC Erosion Control Manual Rip Rap Apron Design 4/6/2012 DESIGN OF RIPRAP OUTLET PROTECTION WORKSHEET Project Amino Point Boulevard Location Fort Bragg, NC Project No. 3818 Outlet ID 2 Culvert Pines Pipe diameter 48 inches Pipe slope 1.79 percent Roughness Coef. 0.013 Full Flow Capacity 192.18 cfs Full flow velocity 15.29 ft/sec Date Designed Checked Apr-06-2012 W. Bone K. Hurst 0 Zone.2 a, 0 1 2 3 4 5 6 7 8 9 la Pipe diameter (ft) Zone from graph above = 5 Is grade of apron 10% or more N YIN Zone used = 5 Length = Outlet pipe diameter 48 in. Width at Outlet, W 1 = Outlet flowrate 192.2 cfs Width at end of Pad, W2 Outlet velocity 15.29 ft/sec Stone diameter = Material = Class li Thickness = 40.0 ft. 18.7 ft. DOUBLE PIPES 64.8 ft. DOUBLE PIPES 14 in. 35 in. Zone Material Diameter Thickness I Length 1 Class A 4 9 4 x D(o) 2 Class B 8 18 6 x D(o) 3 Class I 10 25.5 8 x D(o) 4 Class I 10 25.5 8 x D(o) 5 Class 11 14 34.5 10 x D(o) 6 Class 11 14 34.5 10 x D(o) 7 Special study required Calculations based on NY DOT method - Pages 8.06.05 through 8.06.06 in NC Erosion Control Manual Rip Rap Apron Design 4/6/2012 SUBSURFACE EXPLORATION AND GEOTECHNICAL ENGINEERING REPORT (PRELIMINARY) NZ Ammo Pointe Boulevard and MacRidge Road`I p\ovements /-,FY-12, FIN70\5J/� Fort. ragg, North Carolina UJVJ 0 Geotechnical & HTRW Branch U.S. Army Engineer District, Savannah April 2012 This report was prepared by the Savannah District of the U.S. Army Corps of Engineers. The initials or signatures and registration designation of individuals appear on these documents within the scope of their employment as required by the Engineer Regulation 1110-1-8152. Date: 30 April 2012 0 NO. 28134 if PRQFMOM r Leland H Schuman, P.E. Georgia Registration No. 25134 Expiration Date;31 December 2012 Table of Contents Section Page 1. PURPOSE.......................................................................................................................................... 2. QUALIFICATION OF REPORT...................................................................................................... 1 3. PROJECT DESCRIPTION......................................................................................................... i 4. EXPLORATION PROCEDURES.....................................1....................................................2 a. Site Reconnaissance..............................................................-----.----.-----..............----.---•-.-----.......2 b. Field Exploration..................................................../....!\.�.................................... .... 5. SITE AND SUBSURFACE CONDITIONS........ n..3 ........... -- -....................................... a. Site Description ................................................ ...........................\..........................................3 b. Regional and Site Geology. l.................................................... 3 c. Subsurface Conditions -............................... .\---.............................\..\.................................3 d. Groundwater Conditions ................................. \..\........�................\.\............................4 e. Seasonal High Water Table......... .................. ... ....................... .........................4 6. ENGINEERING EVALUATIONS�AND�RECOMMENDATIONS................................................5 a. General ..........................................� \\ \ \ \ 5 ................................................................................. b. Site Preparation ................................ \\....................................................5 c. Pavement Design Criteria- �. �....... � 5 .................... d. Groundwater and Surface -Water Consid'erations...... ^.. ..... e. Structural Fili....�...`........\.�. \ ... 6 .. ..... ..... ...... l f. Construction Quality ControlTesting ......... ..................................................�-----.-----.-----.-•------...----7 g. Drawings ................ N. �...... j....E-.................. .................................................................. 8 h. Specificafions 1........ v --- ----.- .............8 ...... ............................................................ 7. FINAL/GEOTECHNIGAL EV,A1.,UATION,REPORT ....................................................................8 ATTACHMENT A Soil Test Boring.Location Plan ATTACHMENT B Soil\1 east Boring Logs ATTACHMENT\C NRCS Soil Survey Report ATTACHMENT D� OnetPoint and Two -Point Compaction Method SUBSURFACE EXPLORATION AND GEOTECHNICAL ENGINEERING REPORT (PRELIMINARY) Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, PN 70751/� Fort Bragg, North Carolina 1. PURPOSE. \\ � \\ The Government has conducted a preliminary geotechnical,investigation for the,proposed project. This subsurface characterization report provides a general overview of the site conditions, including subsurface soil and groundwater conditions, with detailed 'descriptions at individual exploration locations. 2. QUALIFICATION OF -REPORT. The field explorations performed \r this report were made twdetermine the subsurface soil and groundwater conditions�and were not intended to serve as an assessment of site wetlands, environmental,-or_coniammait\conditions:No effort�was made to define, delineate, or designate any areas -of enviro�i nental concern ro of contamination. The contractor's seam shall include a licensed geote hni al engineer to,interpret the report•and develop foundation and earthwork recommendations and design parameters on which to base the contractor's proposal. The preliminary fin dings and evaluation presented in this report are based on widely -spaced explorations performed at the project site. Any,additionalsubsurface investigations and laboratory analyses conducted to better characterize�the site and to develop the final design shall be performed under the direction of a licensed geotechnical engineer and shall be the full responsibility of the contractor. V 3. PROJECT DESCRIPTION. As part of the proposed Patriot Point development in the southwestern portion of the Fort Bragg Military Installation located in Cumberland County, North Carolina it is planned that approximately 1,500 linear feet of Ammo Pointe Boulevard will be shifted west for a new four - lane alignment and a new intersection for MacRidge Road and MacRidge Triangle Road will be constructed. The relocated portion of Ammo Pointe Boulevard will include a storm water detention basin to the south and a traffic signal and turn lane improvements at its intersection. with Chicken Road to the north. Subsurface Exploration and Geotechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road lmprovcments FY-12, PN 70751 Fort Bragg, North Carolina 4. EXPLORATION PROCEDURES. a. Site Reconnaissance. Prior to the field explorations, the proposed project site and surrounding areas were visually inspected by a geotechnical engineer. The observations were used in planning the exploration, in determining areas of special interest, and in relating site conditions to known geologic conditions in the area. b. Field Exploration. (1) Subsurface conditions at the project sites were explored by eight soil test borings, (designated P-1 through P-5, SHWT-1, SP-1, and SP=2) The locations of the borings are shown on the attached Boring Plans in Attachment A. Borings were drilled to,depths of 10 to l I feet beneath the existing ground surface. (2) Boring locations were established in the field using a hand-held'Global Positioning System (GPS) device having sub -meter, accuracy. The ground surface elevation�t each boring location was interpolated from plans,pro` ided by Josh Hurst of Clark Nexsen Architecture & Engineering via email on March 20, 201'2"%Since the measurements were not precise, the locations shown on the boring location plan as nd the.elevation indicated on the boring logs should be considered approximate. (3) The soil itest,bor ni gs� e drilled by+roehling &Robertson, Inc. of Raleigh, North Carolina, under contract to the Savannah District. The borings were drilled with an ATV CME 550 drill rig; a 2 1/4-inch inside diameter (I.D.) hollow stem auger was used to advance the boreholes S`plif--Barresampling with -Standard Penetration Testing (SPT) was performed in the soil test,boring"s at•intervals shown,on the boring-logs.)A11 soil sampling and Standard i 'I-,X \. 1% m Penetration Testing were lsubstantlal accordance,with ASTM D 1586. In the Standard Penetration Test, a soil sample,\ obtained with a standard I % inch I.D., 2 inch O.D. split -barrel sampler. The sampler is first,seated 6 inches and then driven an additional 12 inches with blows from a 140-pound hammer falling a distance of 30 inches. The number of blows required to drive the sampler'the,final 12 inches is recorded and is termed the "standard penetration resistance," or the `N value." Penetration resistance, when properly evaluated, is an index of the soil's strength, density ndffoiundation support capability. (4) Representative portions of the soil samples obtained at each of the standard penetration test intervals were sealed in airtight containers and transported back to the Savannah District office where they will be stored in case additional laboratory testing is determined to be necessary. During drilling, classification of the soil samples was performed in general accordance with ASTM D 2488 (Visual -Manual Procedure for Descriptions of Soils). The soil classifications include the use of the Unified Soil Classification System described in ASTM D 2487 (Classification of Soils for Engineering Purposes). Since the soil descriptions and classifications are based on visual examination, they should be considered approximate. 2 Subsurface Exploration and Geotechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, PN 70751 Fort Bragg, North Carolina (5) Logs of the soil test borings graphically depicting soil descriptions, standard penetration resistances, and observed groundwater levels are included in Attachment B of this report. 5. SITE AND SUBSURFACE CONDITIONS. a. Site Description. The relocated portion of Ammo Pointe Boulevard is located tc the east of Bones Creek in a relatively undeveloped portion of the installation. Site vegetationforthis area consists mainly of medium to large trees with light to moderate underbrush!Site topography consists of gentle to moderate slopes descending to the south from an elevatlon,o`f-approximately 263 feet near Chicken Road to an elevation of 215 feet where the,"roadway willjoin with the existing Ammo Pointe Boulevard. The new MacRidge Road/MacRidge Road Triangle intersection is located on an existing portion of MacRidge Road just south of Longstreet Road Based on the provided plans, finish grades are anticipated to be at or near•existing grades with only minimal cuts and fills (less than 5 ft) for portions of the proposed Ammo Point'Boulevard relocation. Cuts in excess of 10 feet are anticipated for the.new storm water 'detention basin located in the southern portion of the Ammo Pointe Boulevard relocation. b. Regional and Site Geology. T� (1) Fort Bragg'is located'in the Sand Hills area ftl e.Coastal Plain physiographic province of North Carolina. The Coastal Plain extends westward- from the Atlantic Ocean to the Fall Line, a distance of approximately 130 miles. The Fall Line is the boundary between the Coastal Plain and the Piedmo nt yslograp\ro�aging rs. �(-2) Geologic�mt`F gg.area;from oldest to youngest, include the Caroli \ State Belt rocks., which comprise the basement rock, the Cape Fear Formation, and the MiddendorfFormation. The Cape Fear and Middendorf Formations overlie the basement rock and are a part, of the generally southeast \ rd-dipping and thickening wedge of sediments that constitute the Atlantic Coastal Plain deposits. (3) The�Mddendorf Formation is exposed at land surface throughout the Fort Bragg area. The formation it composedfof tan, cross -bedded, medium- and fine-grained, micaceous quartz sand and clayey sand interbedded with clay or sandy clay lenses or layers. Layers of hematite -cemented sandstone occur locally throughout the Middendorf Formation as do thin layers of hard kaolin and kaolin -cemented sandstone. Below the water table, these units are generally friable or plastic. In places, the Middendorf Formation is mottled orange, gray, and tan color with streaks and laminae of red and purple hematite and manganese oxide stains. c. Subsurface Conditions. (1) Subsurface soils for all boring locations consist primarily of interbedded layers of clayey and silty sands (SC, and SM). A few isolated layers of lean sandy silt (ML) and sandy, silty clays (CH) were also encountered. Standard penetration resistance values in these materials 3 Subsurface Exploration and Geolechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, [IN 70751 Fort Bragg, Norlh Carolina were generally indicative of loose to dense and firm to stiff consistency. Neither hard drilling materials nor auger refusal was encountered at any of the boring locations. Groundwater was encountered as noted on the individual Drilling Logs and below in the Groundwater Conditions section. (2) The above subsurface description is of a generalized nature to highlight the major subsurface stratification features and material characteristics. The boring logs should be reviewed for specific information at individual boring locations. The stratifications shown on the boring logs represent the conditions only at the actual boringlocations. Variations may occur and should be expected between boring locations. The stratification lines shown on the boring logs represent the approximate boundaries between the subsurface materials-, the actual transitions are typically more gradual. d. Groundwater Conditions. (1) Water levels were measured at the completion of drilling at cach of the boring locations. Groundwater was encountered at SHWT-I\a`a dep't�of approximately 9.0 feet (elev. 210.0 feet) at the time of drilling. SHWT-1 was performed within the proposcd,slorm water detention basin. According to provided,plans the proposed detention pond has been designed as a "wet" detention basin with a permanent pool elevation of�?2 0 50 feet. Groundwater was not encountered at any of the other boring locati nos llnless perched -water conditions are encountered, ground water -should not be ofconseq consequence during general site grading for the Ammo Pointe Boulevard relocatibn\and thetM\acR dgee/MacRidge Triangle intersection. \ (2) A "perched -water" condition occurs �when water seeping downward is blocked by an impermeable soil layer, such,as clayey -sand or clay�and saturates the more permeable soil above it. The true grou dwater level can be-several.to many.feet below the perched -water level. Due to the prealen eof-interbedded sands, clayey and`and clays at the project site, perched -water conditions during and after�construction, could�be.encountered. (I should be no\th t groundwater conditions vary during periods of prolonged drought and excessive rainfall as well as seasonally. Therefore, fluctuations in the elevation of the groundwater should be anticipated with changing climatic and rainfall conditions. Seasonal H (1) The depth to the seasonal high water table (SHWT) is an important parameter in determining suitability of storm water features. It is defined as the highest groundwater observed, at atmospheric pressure, for anaerobic conditions to be established. In North Carolina, this typically occurs during the wet months or during the winter or spring. The SHWT is estimated by soil color, redoximorphic features, saturation observations, and professional assessment. (2) A wet storm water detention pond is anticipated at the lowest point of the proposed site. The subsurface within the footprint of the proposed storm water detention area was investigated by soil boring SHWT-1 which was drilled to a depth of I I feet. The soil encountered in this boring consists of clayey sand (SC). The coloration of this clayey sand varied with depth and exhibited 4 Subsurface Exploralion and Geotechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, PN 70751 Fort Bragg, North Carolina the low chroma characteristic of extensively submerged soils from a depth of 5.5 feet. According the NRCS Soil Resource Report (see Attachment C), the main NRCS soil identified in this area, is Blaney loamy sand, 8 to 15 percent slopes (BaD). Per the report, groundwater is typically encountered in these soils at a depth in excess of 80 inches below the ground surface; however, groundwater was encountered in the boring during drilling at 7 feet, and measured at approximately 9 feet after drilling. Based on these observations, it is recommended that for the purposes of designing the proposed storm water detention structure, the seasonal high water table 'should be placed at a depth of three feet below the surface, corresponding to an approximate elevation of 216 feet msl. 6. ENGINEERING EVALUATIONS AND RECOMMENDATIONS. a. General. \\ The following evaluations and recommendations �e'based on the mfor`mation available on the proposed roadway improvements, observations made at the project site, interpretation of the data obtained from the soil test borings, and previousexperiencewith soils and subsurface conditions similar to those encountered at the site. It is emphasized thatthe,preliminarytindings and evaluation presented in this report are,based on widely -spaced explorations performed at the project site. Additional subsurface investigations and/or laboratoryranalyses required to determine site soil conditions and develop the final design. hs all be performed under the direction of a licensed geotechnical engineer and shall be the full responsibility of the contractor. b. Site Preparation,i \ ` . Following cicaring and removal �of4ees, structures. epave ment . etc., along the proposed roadway improvements. theconstruc Lion area should be grubbed and stripped of all vegetation, topsoil, organics, and other deleterious_materials lean topsoil can be stockpiled and reused in landscaped areas It,is recommended-tha the zonerofstripping extend a minimum of 10 feet beyond tl e outer -edges of pavements and any�prvsed structures. c: Pavement Design Criteria. 1 i\\� like\\ encountered at the i e clayey sands SC an silty sand O The so types most y to be tered site are y y sa ( } d s y s (SM). Any unsatisfactory subgrade soils that are encountered should be removed and replaced with satisfactory soils in accordance with the requirements of Specification Section 31 00 00 EARTHWORK. Soft c nsistency surface soils were encountered at boring locations P-I and P-2 extending to depths of 12\to J 4 inches beneath the existing ground surface. It is possible that some of these soft soils will be removed during site stripping and grading operations; however, any remaining soft soils should be stabilized by compaction or undercut and replaced with suitable compacted fill. (2) The following subgrade values for satisfactory soils are anticipated for design of the pavements; however, these values shall be confirmed by the Contractor's consulting geotechnical engineer when grade and location of pavements have been finalized: (1) Flexible Pavement: Compacted subgrade, use CBR of 8. subsurface Exploration and Geotechnical Report {Preliminary} Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, ]IN 70751 Fort Bragg, North Carolina (2) Rigid Pavement: (a) Corrected modulus of subgrade reaction, use K of 150 psi per inch. (b) Design 28-day concrete flexural strength, use 650 psi. d. Groundwater and Surface -Water Considerations. Due to the presence of clayey sand and clay layers in the subsoils at the project site, "perched - water" conditions could be encountered, and the accumulation of run-off water or seepage at the base of excavations will likely occur during underground utility installation and site work. e. Structural Fill. In order to achieve high density structural fill, the following evaluations and recommendations are offered: //�> (1) Based on the soil test borings, excavated on-site'soils (excluding any organics/topsoil and debris) can be used as structural fill. Some moisture content adjustmen�will probably be necessary to achieve proper compaction. If water must `be/added, it should be;n f rmly applied and thoroughly mixed into the soil by discing. (2) It is recommended that the contractor have appropriate disc harrows available during earthwork for mixing, drying, and wetting of the•soils for any areas to undergo mass grading. 3 Materials srleetedfo-r,use as s\uctural fill shouldlbe free'from roots and other organic matter, traszdebris, frozen soil, and stones larger tHan 3,,inches in any dimension, and in general, should have \liquid limitless than 50�percent and a plastic index of less than 30. The following soils represented by their Unified SoihClassification System (ASTM D 2487) group symbols will"be usus itable for use as structural fill: 36GW, GC, GM, SP, SP-SM, SP-SC, SW, SC, SMSM=SC; CL, and ML. The following soil types are considered unsuitable: Pt, OH, OL, CH, and MH. \(4),N'�Iuitable fill soils should be placed in lifts of maximum 8 inches loose measurement. The soil should`e, co mpacted by rmechanical means such as steel drum, sheepsfoot, tamping, or rubber -tired rollers. Compaction of clays is best accomplished with a sheepsfoot or tamping roller. Periodically rolling with heavily loaded, rubber -tired equipment may be desirable to seal the surface of the compact`ed,fill,,thus reducing the potential for absorption of surface water following a rain. This seaii`g,o`peration is particularly important at the end of the work day and at the end of the week. Within confined areas or foundation excavations, the use of manually operated, internal combustion activated compactors ("whacker packers" or sled tamps) is recommended. The compactors should have sufficient weight and striking power to produce the same degree of compaction that is obtained on the other portions of the fill by the rolling equipment, as specified. Where hand operated equipment is used, the soils should be placed in lifts of maximum 4 inches loose measurement. C'' Subsurface Fxploratiun and Geolechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road Improvements PY-12, PN 70751 Port Bragg, North Carolina (5) It is recommended that the structural till and subgrades be compacted to the following minimum percents of the modified Proctor maximum dry density (ASTM D 1557): Beneath structures and building slabs, to 5 feet beyond building and structure line, around footings and in trenches 92 percent Beneath paved areas, except top 12 inches 92 percent Beneath paved areas, top 12 inches 95" ercent Beneath shoulders ,'90 percent Beneath sidewalks and grassed areas / 85' ercent Base course beneath paved areas ( / 1 dQ ercent f. Construction Quality Control T (1) Prior to initiating any structural fill placement ands/ r compact iomoperations, it is recommend that representative samples•of the soils, which.will be used as structural fill or subgrade, both suitable on -site soils el �ana aff sib sails (bo>;ra \), be obtained and tested to determine their classification and compaction characteristics The samples should be carefully selected to represent the full range of soil types tobe,used. The moisture content, maximum dry density, optimum moisture —content, grain -size, and plasticity characteristics should be determined. These tests are required to de ermine•if the fill and subgrade soils are acceptable and for compaction quality control of the subgrades,and structural fill. Tests for the above soil properties should be in,accordance with the following: ,IVloisture Content \ �\ \ \ 1 ASTM D 2216 Maximum Dry'Densii ,and O timum,Moisture ASTM D 1557 Grain -Size (Wash'No. 200, -less h drornefer ASTM D 422 and D 1140 P- sticit \ \ \ \ ASTM D 4318 (2) A representative number of in -place field density tests should be performed in the subgrade of compacted on -site soils and in the structural fill and backfill to confirm that the required degree of compaction'has�been obtained. In -place density tests should be performed in accordance with the sand, one method prescribed in ASTM D 1556. It is recommend at least one density test be performed for each 5,000 square feet and 12,500 square feet, or portion thereof, for buildings and pavements, respectively, of compacted native soil subgrade and in each lift of compacted structural fill. It is also recommend that at least one density test be performed for each 100 linear feet in the bearing level soils of continuous footings. Density tests should be performed at 100-foot intervals along roadway subgrades. In addition, a density test should be performed for each 100 linear feet of backfill placed per foot of depth in trenches for utilities systems. Where other areas are compacted separately by manually operated compactors, a minimum of one density test should be performed for every 250 square feet, or portion thereof, of fill placed per foot of depth. h Subsurface Exploration and Geotechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, PN 70751 Fort Bragg, North Carolina (3) Compaction control of soils requires the comparison of fill water content and dry density values obtained in the field density tests with optimum water content and maximum dry density determined in a laboratory compaction test performed on the same soil. It is, however, not feasible to do this as the testing could not keep pace with fill construction. It is, therefore, recommended that compaction control of the earthwork construction be performed using a "family" of compaction curves and the one -point or two -point compaction methods. Excerpts from construction specifications which describe the approach and its use are included in Attachment D. (4) Any area that does not meet the required compaction'criteria should be reworked and retested. If the moisture content of the soil is within the recommended range, additional compaction may be all that is necessary to increase the density, if the moisture content is not within the recommended range; then, the moisture content should be,adjusted to within the range and the area recompacted. (5) All laboratory and field density testing should be performed by a commercial testing laboratory that has been validated by the Engineer,Research,i nd%Development Center Materials Testing Center (MTC) under the Corps•of Engineers laboratory inspection and validation program. g. Drawings. The drawings showing locations and results of the soil borings completed by the Government are included in this RFP. These locations and the loc itions of�any additional investigations (SPT r f N \ i� borings, test pits, cone penetrometentests, laboratory/soils test,data, etc.) performed by the AE's consulting geotechnical engineer shall be shown on the final design and on the project as -built drawings completed by the design'build.contraciorNIn addition, the selected design -build contractor shal sl how.` boring'logsNZ ; GKI'/DMT soundings, and soil laboratory test data including those in this report and any additional investigations or test data used for design on the final design drawings and on the as -built drawing raw ni gs! \\Supecifications . It is recommended that the AE use the Savannah District's EARTHWORK specification, 31 00 00, when editing the specifications for this project. The specification (Specslntact format) can be found at the following website: http://en.sas.usace.army.mil/enwebAittproot/ae/index.htm, under menu "SAS Guide Specifications 7. FINAL GEOTECHNICAL EVALUATION REPORT. A final geotechnical evaluation report shall be prepared by the contractor's licensed geotechnical engineer and submitted along with the first design submittal. The geotechnical report shall summarize the subsurface conditions and provide recommendations for the design of appropriate retaining walls, embankments, roadways, and pavements. The report shall recommend the type of any retaining wall system to be used, lateral load resistance capacities for any retaining wall systems, and appropriate design values for roadways, pavements, etc. Recommendations regarding lateral earth pressures (active, at -rest, and passive) to be used in the design of retaining walls shall be provided. Calculations shall be included to support the recommendations for pavement sections. Supporting documentation shall be included for all 8 Subsurface Exploration and Geotechnical Report (Preliminary) Ammo Pointe Boulevard and MacRidge Road Improvements FY-12, PN 70751 Fort Bragg, North Carolina recommended design parameters such as shear strength, earth pressure coefficients, friction factors, subgrade modulus, California Bearing Ratio (CBR), etc. In addition, the report shall provide earthwork recommendations, expected frost penetration, expected groundwater levels, recommendations for dewatering and groundwater control, and identify the possible presence of any surface or subsurface features that may affect the construction of the project such as sinkholes, boulders, shallow rock, undocumented fill, old structures, soft areas, or unusual soil conditions. 6 C C B 1 2 3 4 15 VS ARMY CORPS OF ENGINEERS SAVANNAH rr ` w \ � I �p I I i - i N 486,752 II I I o E 1,988,580 I I \ TOH EL. 256.0 SP-1 P_ 2,� � � N 486,718 78.5 X5880EL. Xs38� TOH988, N486,667— I y — 1 E 1,988,637 1 yl r` I TOH EL. 261.0 y I ``� x FIELD OPERATIONS ly ', ; BREAK oi OFFICE AND ' LJ ROOM o� CHANGE HOUSE ` 6 yy 00 P- 00 � I I » �s r. X I OLD ASP SITE z „ m o G s Ez W o y N 486,216 y E 1,988,853 1 �� ,� r-, y x TOH EL. 259.5In Z Z O W �0 2 Z i/ PARKING do� _— a c� N aa5,850 ' - ZZ E 1,989,013 h0 J GU RD TOH EL. 236.5 a w cna- INERT SE �4� (� STORAGE (� �1' N 485.592 LEGEND 0 W o [] PUMP �p1 E 1.989.149 (3 SOIL TEST BORING LOCATIONS ~ } f X7169 HOUSE TOH EL. 219.0� Y 2 O 7 S cn II PLATE 100 50 0 100 200F1 REFERENCE FERE RE B-101 SCALE: V- 100' SHEET SIDGrureu! 1 1 DON5 PCC33 SSVSERNAME$S 0 lam 9 / I I a D rI I pO6o \ I \\ r r FT� \\ I ! D VI I! 4V /I 14 // rl // II // II // II // II // II // i AkLEI, rRA1NjNG / D^ r \1 D MOD 11\V r_PI) FmOD ^'N) rn O IIV W cn 111 Ln I V\ O 1 1 1\ V 1 11 VI 1V 1 VI \ \\ 11 \\ V V \\ l y\ \ \\ II V \\ 1 V \\ V 1 \\\ Vyl \\ l \ V\ \ V 0 m o � m O Z n r- m to m cn C) m o p X `z C, c) rr a n N O o p z W AMMO POINTE BOULEVARD AND MACRIDGE ROAD IMPROVEMENTS In M m W FORT EIRAG.NORTH CAROLINA C m N n� SOIL TEST BORING m LAYOUT PLAN U. S. ARMY ENGINEER DISTRICT CORPS OF ENGINEERS SAVANNAH DISTRICT DESIGNED BY: DATE: own BY: CKO Bv: 90ucrcAnON Noy SUBMITTEOBY: CONTRACT NO-' FILE NAME: SSFILENAME33 CATEGORY CODE: 221-tl�5 SRE:D PLOTSCALF: PLOTDATE: 22'XM' 33PLOT SCALESS SSPLOT DArt33 z yNy y Z DJ Z 2 K a K M 9 BYMBOL DESCRIPTION DATE BY SOIL CLASSIFICATION CHART MAJOR DIVISIONS SYMBOLS TYPICAL DESCRIPTIONS GRAPH I LETTER GRAVEL AND CLEAN GRAVELS '` • '• �' I .• GW WELL -GRADED GRAVELS. GRAVEL - SAND MIXTURES, LITTLE OR NO FINES SOILS {LITTLE OR NO FINES) P °Qa Qa o �� o p °p G p POORLY -GRADED GRAVELS, GRAVEL -SAND MIXTURES, LITTLE OR NO FINES COARSE ° GRAINED SOILS MORE THAN 50% OF COARSE GRAVELS WITH F1NES °Q�'° o a o GM SILTY GRAVELS. GRAVEL -SAND - SILT MIXTURES FRACTION RETAINED ON NO, 4 SIEVE (APPRECIABLE AMOUNT OF FINES) GC CLAYEY GRAVELS, GRAVEL - SAND - CLAY MIXTURES MORE THAN SO% OF MATERIAL IS SAND AND CLEAN SANDS SW WELL -GRADED SANDS, GRAVELLY SANDS, LITTLE OR NO FINES :. Sp POORLY -GRADED SANDS, GRAVELLY SAND, LITTLE OR NO FINES LARGER THAN NO, 200 SIEVE SIZE SANDY SOILS (LITTLE OR NO FINES) SANDS WITH FINES :: ' qq j:'•i:1;>: .;'i; SM SILTY SANDS, SAND - SILT MIXTURES MORE THAN 50% OF COARSE FRACTION PASSING ON NO. 4SIEVE (APPRECIABLE AMOUNT OF FINES) SC CLAYEYSANDS.SAND -CLAY MIXTURES INORGANIC SILTS AND VERY FINE M L SANDS. ROCK FLOUR, SILTY OR CLAYEY FINE SANDS OR CLAYEY SILTS WITH SLIGHT PLASTICITY SILTS INORGANIC CLAYS OF LOW TO FINE GRAINED SOILS AND E88TAMIT LH CLAYS CL MEDIUM PLASTICITY, GRAVELLY CLAYS, SANDY CLAYS. SILTY CLAYS. LEAN CLAYS OL ORGANIC SILTS AND ORGANIC SILTY CLAYS OF LOW PLASTICITY MORE THAN 50% OF MATERIAL IS SMALLER THAN NO. 200 SIEVE M H INORGANIC SILTS, MICACEOUS OR DIATOMACEOUS FINE SAND OR SILTY SOILS SIZE SILTS AND LIQUID LIMIT CLAYS GREATER THAN 50 CH INORGANIC CLAYS OF HIGH PLASTICITY ssss OH I ORGANIC CLAYS OF MEDIUM TO HIGH PLASTICITY, ORGANIC SILTS HIGHLY ORGANIC SOILS —' " PT PEAT. HUMUS, SWAMP SOILS WITH HIGH ORGANIC CONTENTS NOTE: DUAL SYMBOLS ARE USED TO INDICATE BORDERLINE SOIL CLASSIFICATIONS CSINCE r& FROEHLING 1 tee,' & ROBERTSONp INC. BORING LOG Boring: P-1 (1 of 1) Project No: 66L-0454-0015 Elevation: 236.5 (EST. FROM PLAN) Drilling Method: 2.25" ID HSA Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 485,850 E 1,989,013 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth Description of Materials (Classification) * Sample Blows Sample Depth feet N Value (blows/ft) Remarks 0.4 SURFIClAL ORGANIC SOIL W H-WOH H 0 GROUNDWATER DATA: 0 Hrs.: Dry /caved at 6.7' NATIVE: Very loose, moist, tan -brown silty fine SAND (SM), trace small roots. 1.5 2.0 2.5 Loose, moist, red -brown clayey fine SAND (SC). 2-4-5 9 4.0 4.0 Stiff, moist, red, orange & tan fine sandy silty CLAY (CH). J 5.0 3-5-8 13 6.5 - 7.0 Loose, moist, orange -tan silty fine SAND (SM), trace small roots. 8'5 4-4-4 8 10.0 Boring terminated at 10.0 feet. u1.1 - vi ui- icyuii cu n ivi o i-ry iu annnl/ cl uI VPn IV, w w U51vc L V.U., 1..]i3 I.U. SdMPIUF J WWI flT io mcnes In [nree t) increments. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. BORING LOG SINCE �& FROEHLING & ROBERTSONg INC. Boring: P-2 (1 of 1) Project No: 66L-0454-0015 Elevation: 259.5 (EST. FROM PLAN) Drilling Method: 2.25" ID H5A Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 486,216 E 1,988,853 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth Description of Materials (Classification) * Sample Blows Sample Depth feet N-Value (blows/ft) Remarks 0.3 SURFICIAL ORGANIC SOIL 1-2-3 5 GROUNDWATER DATA:}, 0 Hrs.: Dry / caged at 6.5' NATIVE: Loose, moist, tan silty fine SAND (SM trace small roots. 1.5 2.a Loose, moist, orange -brown clayey fine SAND (SC)- 2.5 2-2-3 5 4.0 5.0 4-4-5 9 6.5 7.0 Dense, moist, red -tan clayey fine to coarse SAND (SC), with quartz rock fragments. 8.5 26-26-22 48 10.0 Boring terminated at 10.0 feet. IlclnniCl 44 uppli Ir, JU LU VI IVC L v. V., i.j/7 I.U. Sdfllplef d LOLdI D, 18 Imes In Lnree t) Increments. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. SINCE r& FROEHLING 1 1BB1 & ROBERTSON9 1 NC. BORING LOG Boring: P-3 (1 of 1) Project No: 66L-0454-0015 Elevation: 259.5 (EST. FROM PLAN) Drilling Method: 2.25" ID HSA Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 486,667 E 1,988,637 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth Description of Materials {Classification} ` Sample Blows Sample Dfet eet N-Value (blows/ft) Remarks SURFICIAL ORGANIC SOIL 2-3-4 GROUNDWATER DATA: 0 Hrs.: Dry /caved at 6.2' NATIVE: Loose, moist, brown clayey fine SAND Y Y (SC). 1.5 2.0 2 5 Medium dense, moist, red -brown clayey fine SAND (SC), with trace coarse sand. 4-12-16 28 4 0 4.0 Dense, moist, orange -brown silty fine SAND (SM). 15-18-22 5.0 40 6.5 15-19-26 8.5 45 10.0 Boring terminated at 10.0 feet. I�UI,IUCf VI UIVwJ [LIqu IFUU IVr d 1•iv IU rid(r1rtiur vrvpping 3u to anve z u.U., l.�n i.u. sampler a iotai oT its incnes in tnree b increments. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. BORING LOG SINCE F& FROEHLING & ROBERTSONp INC. Boring: P-4 (1 of 1) Project No: 66L-0454-0015 Elevation: 360.5 (EST. FROM PLAN) Drilling Method: 2.25" ID HSA Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 502,675 E 1,982,630 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth p Description of Materials (Classification) * Sample Blows Sample Dfeeth N-Value (blows/ft) Remarks 0.3 SURFICIAL ORGANIC SOIL 4-4-7 11 GROUNDWATER DATA: 0 Hrs.: Dry / caved at 7.0' NATIVE: Medium dense, moist, red & brown clayey fine SAND (SC), trace small roots. 1.5 2.0 2.5 Medium dense, moist, orange -tan clayey fine SAND (SC). 6-5-11 16 4.0 4.0 Stiff, moist, brown & tan fine sandy SILT (ML). 5.0 3-6-7 13 6.5 7.0 Loose, moist, brown & tan silty fine SAND (SM). 8'5 3-3-5 8 10.0 Boring terminated at 10.0 feet. • •-••••-.-• • ma +.". y. -�........— u. vVF ..5 w w UI I.O L W.V., 1.JIJ I.L.I. �auIPICI d LULdI VI tomr ley rrl lrlree O IrlUel lens. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. SINCE BORING FROEHLING & ROP-5LOG BERT5ON, INC. Boring: -5 (1 of 1) 18BM1 Project No: 66L-0454-0015 Elevation: 369.0 (EST. FROM PLAN) Drilling Method: 2.25" ID HSA Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 502,961 E 1,982,553 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth Description of Materials (Classification) * Sample Blows Sample Depth feet N-Value blows/ft) Remarks 1 POSSIBLE FILL: Medium dense, moist, dark brown silty fine to coarse SAND (SM), some gravel. 4-9-8 1 5 17 GROUNDWATER DATA: 0 Hrs.: Dry /caved at 6.4' NATIVE: Medium dense, moist, red -brown clayey fine SAND (SC). 2.0 2.5 Medium dense, moist, red, orange & tan silty fine SAND (SM). 7-6-7 13 4.0 4.0 Medium dense to loose, moist, orange -tan silty fine SAND (SM). 5.0 6-8-8 16 6.5 8.5 6-4-5 9 I 10.0 Boring terminated at 10.0 feet. 'Ivumuer OT mows require❑ Tor a 14u to nammer uropping 3u to ❑rive L U.U., I.U. Sampler a total vT lb Incnes In inree O Increments. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. SINCE F& FROEHLING 1661 ROBERT5ONy INC. BORING LOG Boring: SP-1 (1 of 1) Project No: 66L-0454-0015 Elevation: 256.0 (EST. FROM PLAN) Drilling Method: 2.25" ID HSA Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 486,752 E 1,988,580 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth Description of Materials (Classification) * sample Blows Sample Depth feet N-Value ft blows/i Remarks 0.2 SURFICIAL QRGANIC SOIL 1-5-16 1.0 21 GROUNDWATER DATA. 0 Hrs.: Dry / caved at 6.6 NATIVE: Medium dense, moist, red, orange & tan silty fine SAND {SM), trace small roots. Dense, moist, red -brown clayey fine to coarse SAND (SC) with quartz rock fragments. 1.5 11-15-20 2.5 35 4.0 5.0 5.0 Medium dense, moist, pink -tan silty fine SAND 6-9-9 (SM). 18 6.5 7.0 Firm, moist, tan, gray & mauve fine sandy CLAY (CH). 8.S 9-4-4 8 10.0 Boring terminated at 10.0 feet. vuniuci vi U-3 icyuiicu IVI a aYV lu nanlrf]CI UTUP.lInt' u w unve [ v.u., 1.3fo I.U. sampler a imal oT L?J Incnes In inree b Increments. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. SINCE FROEHLING & BORING LOG z c RoBERTSE3N, INC. Boring: SP-2 (1 of 1) Project No: 66L-0454-0015 Elevation: 258.5 (EST. FROM PLAN) Drilling Method: 2.25" ID HSA Client: US Army Corps of Engineers Total Depth: 10.0' Hammer Type: Automatic Project: 108 ADA Infrastructure, LI: 70751, FY-12 Boring Location: N 486,718 E 1,988,678 Date Drilled: 4/4/12 City/State: Ft. Bragg, NC Driller: F&R Tignor Elevation Depth p Description of Materials (Classification) * Sample Blows Sample Depth N-Value (blows/ft) Remarks . SURFICIAL ORGANIC SOIL 2-2-4 b GROUNDWATER DATA: 0 Hrs.: Dry /caved at 6.7' NATIVE: Loose, moist, orange -brown clayey fine SAND (SC). 1.5 2.a 14-18-16 2.5 Dense, moist, red, orange & tan clayey fine to medium SAND (SC), trace coarse sand. 34 4.0 4.0 Dense, moist, red -brown clayey fine SAND (SC). 18-19-22 5.0 41 6.5 7.a Medium dense, orange -brown clayey fine SAND (SC). 8.5 9-10-8 18 10.0 Boring terminated at 10.0 feet. uivNNnig w W 4'-G V.V., S.J/J LU. �OfI1FJICf d LVld, Uf 18 In Cr1eS In Lflfee O Increments. The sum of the second and third increments of penetration is termed the standard penetration resistance, N-Value. LOG OF BORING SHEET 10F1 BORING NO. CONTRACTED WITH; U.S. ARMY CORPS OF ENGINEERS - SAVANNAH SHWT-1 DATE: PROJECT NAME: Ammo Pointe Boulevard and MacRid a Road Improvements - PN 70751, FY12 4/4/2012 LOCATION: Fort Bragg, North Carolina - Cumberland County Auto Hammer, 2-114"I.D. HSA NC STATE PLANE COORDINATES: N 485 50 F 1 9R9 1d9 ELEV. DESCRIPTION DEPTH (ft) �" SAMPLES NOTES Topsoil - 3.0" dark brown clayey sand with some organics No. TYPEJ BLOWSI6" "N" FEET 219.0 Clayey Sand, Orangish Brown, fine to Drilling soft medium grained, moist (SC) 1 2 3 4 5 5 Clayey Sand , Light Brown, fine to medium grained, moist (SC) 7 Clayey Sand , Greyish Brown, fine to medium grained, wet (SC) 8 210.0 9 Water table at 0 hrs 10 208.0 12 Boring terminated at 11.0 feet 13 14 Note: hole plugged at 10.4 ft 15 at 0 hrs 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 USDA United States Department of Agriculture o NRCS Natural Resources Conservation Service A product of the National Cooperative Soil Survey, a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local participants Custom Soil Resource Report for Cumberland County, North Carolina April 12, 2012 Preface Soil surveys contain information that affects land use planning in survey areas. They highlight soil limitations that affect various land uses and provide information about the properties of the soils in the survey areas. Soil surveys are designed for many different users, including farmers, ranchers, foresters, agronomists, urban planners, community officials, engineers, developers, builders, and home buyers. Also, conservationists, teachers, students, and specialists in recreation, waste disposal, and pollution control can use the surveys to help them understand, protect, or enhance the environment. Various land use regulations of Federal, State, and local governments may impose special restrictions on land use or land treatment. Soil surveys identify soil properties that are used in making various land use or land treatment decisions. The information is intended to help the land users identify and reduce the effects of soil limitations on various land uses. The landowner or user is responsible for identifying and complying with existing laws and regulations. Although soil survey information can be used for general farm, local, and wider area planning, onsite investigation is needed to supplement this information in some cases. Examples include soil quality assessments (http://soils.usda.gov/sqi/) and certain conservation and engineering applications. For more detailed information, contact your local USDA Service Center (http://offices.sc.egov.usda.gov/locator/app? agency=nres) or your NRCS State Soil Scientist (http://soils.usda.gov/contact/ state offices/). Great differences in soil properties can occur within short distances. Some soils are seasonally wet or subject to flooding. Some are too unstable to be used as a foundation for buildings or roads. Clayey or wet soils are poorly suited to use as septic tank absorption fields. A high water table makes a soil poorly suited to basements or underground installations. The National Cooperative Soil Survey is a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local agencies. The Natural Resources Conservation Service (NRCS) has leadership for the Federal part of the National Cooperative Soil Survey. Information about soils is updated periodically. Updated information is available through the NRCS Soil Data Mart Web site or the NRCS Web Soil Survey. The Soil Data Mart is the data storage site for the official soil survey information. The U.S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin, age, disability, and where applicable, sex, marital status, familial status, parental status, religion, sexual orientation, genetic information, political beliefs, reprisal, or because all or a part of an individual's income is derived from any public assistance program. (Not all prohibited bases apply to all programs.) Persons with disabilities who require alternative means for communication of program information (Braille, large print, audiotape, etc.) should contact USDA's TARGET Center at (202) 720-2600 (voice and TDD). To file a complaint of discrimination, write to USDA, Director, Office of Civil Rights, 1400 Independence Avenue, S.W., Washington, D.C. 20250-9410 or call (800) 795-3272 (voice) or (202) 720-6382 (TDD). USDA is an equal opportunity provider and employer. Contents Preface....................................................................................................................2 How Soil Surveys Are Made..................................................................................5 SoilMap..................................................................................................................7 SoilMap................................................................................................................8 Legend..................................................................................................................9 MapUnit Legend................................................................................................10 MapUnit Descriptions........................................................................................10 Cumberland County, North Carolina...............................................................12 BaD—Blaney loamy sand, 8 to 15 percent slopes......................................12 FaB—Faceville loamy sand, 2 to 6 percent slopes.....................................12 References............................................................................................................14 4 How Soil Surveys Are Made Soil surveys are made to provide information about the soils and miscellaneous areas in a specific area. They include a description of the soils and miscellaneous areas and their location on the landscape and tables that show soil properties and limitations affecting various uses. Soil scientists observed the steepness, length, and shape of the slopes; the general pattern of drainage; the kinds of crops and native plants; and the kinds of bedrock. They observed and described many soil profiles. A soil profile is the sequence of natural layers, or horizons, in a soil. The profile extends from the surface down into the unconsolidated material in which the soil formed or from the surface down to bedrock. The unconsolidated material is devoid of roots and other living organisms and has not been changed by other biological activity. Currently, soils are mapped according to the boundaries of major land resource areas (MLRAs). MLRAs are geographically associated land resource units that share common characteristics related to physiography, geology, climate, water resources, soils, biological resources, and land uses (USDA, 2006). Soil survey areas typically consist of parts of one or more MLRA. The soils and miscellaneous areas in a survey area occur in an orderly pattern that is related to the geology, landforms, relief, climate, and natural vegetation of the area. Each kind of soil and miscellaneous area is associated with a particular kind of landform or with a segment of the landform. By observing the soils and miscellaneous areas in the survey area and relating their position to specific segments of the landform, a soil scientist develops a concept, or model, of how they were formed. Thus, during mapping, this model enables the soil scientist to predict with a considerable degree of accuracy the kind of soil or miscellaneous area at a specific location on the landscape. Commonly, individual soils on the landscape merge into one another as their characteristics gradually change. To construct an accurate soil map, however, soil scientists must determine the boundaries between the soils. They can observe only a limited number of soil profiles. Nevertheless, these observations, supplemented by an understanding of the soil -vegetation -landscape relationship, are sufficient to verify predictions of the kinds of soil in an area and to determine the boundaries. Soil scientists recorded the characteristics of the soil profiles that they studied. They noted soil color, texture, size and shape of soil aggregates, kind and amount of rock fragments, distribution of plant roots, reaction, and other features that enable them to identify soils. After describing the soils in the survey area and determining their properties, the soil scientists assigned the soils to taxonomic classes (units). Taxonomic classes are concepts. Each taxonomic class has a set of soil characteristics with precisely defined limits. The classes are used as a basis for comparison to classify soils systematically. Soil taxonomy, the system of taxonomic classification used in the United States, is based mainly on the kind and character of soil properties and the arrangement of horizons within the profile. After the soil scientists classified and named the soils in the survey area, they compared the Custom Soil Resource Report individual soils with similar soils in the same taxonomic class in other areas so that they could confirm data and assemble additional data based on experience and research. The objective of soil mapping is not to delineate pure map unit components; the objective is to separate the landscape into landforms or landform segments that have similar use and management requirements. Each map unit is defined by a unique combination of soil components and/or miscellaneous areas in predictable proportions. Some components may be highly contrasting to the other components of the map unit. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The delineation of such landforms and landform segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, onsite investigation is needed to define and locate the soils and miscellaneous areas. Soil scientists make many field observations in the process of producing a soil map. The frequency of observation is dependent upon several factors, including scale of mapping, intensity of mapping, design of map units, complexity of the landscape, and experience of the soil scientist. Observations are made to test and refine the soil - landscape model and predictions and to verify the classification of the soils at specific locations. Once the soil -landscape model is refined, a significantly smaller number of measurements of individual soil properties are made and recorded. These measurements may include field measurements, such as those for color, depth to bedrock, and texture, and laboratory measurements, such as those for content of sand, silt, clay, salt, and other components. Properties of each soil typically vary from one point to another across the landscape. Observations for map unit components are aggregated to develop ranges of characteristics for the components. The aggregated values are presented. Direct measurements do not exist for every property presented for every map unit component. Values for some properties are estimated from combinations of other properties. While a soil survey is in progress, samples of some of the soils in the area generally are collected for laboratory analyses and for engineering tests. Soil scientists interpret the data from these analyses and tests as well as the field -observed characteristics and the soil properties to determine the expected behavior of the soils under different uses. Interpretations for all of the soils are field tested through observation of the soils in different uses and under different levels of management. Some interpretations are modified to fit local conditions, and some new interpretations are developed to meet local needs. Data are assembled from other sources, such as research information, production records, and field experience of specialists. For example, data on crop yields under defined levels of management are assembled from farm records and from field or plot experiments on the same kinds of soil. Predictions about soil behavior are based not only on soil properties but also on such variables as climate and biological activity. Soil conditions are predictable over long periods of time, but they are not predictable from year to year. For example, soil scientists can predict with a fairly high degree of accuracy that a given soil will have a high water table within certain depths in most years, but they cannot predict that a high water table will always be at a specific level in the soil on a specific date. After soil scientists located and identified the significant natural bodies of soil in the survey area, they drew the boundaries of these bodies on aerial photographs and identified each as a specific map unit. Aerial photographs show trees, buildings, fields, roads, and rivers, all of which help in locating boundaries accurately. A Soil Map The soil map section includes the soil map for the defined area of interest, a list of soil map units on the map and extent of each map unit, and cartographic symbols displayed on the map. Also presented are various metadata about data used to produce the map, and a description of each soil map unit. Custom Soil Resource Report Soil Map m N A O� r 35' 5' 5" w •M � 3 G 35' 5' 0" _ 678980 678990 679000 Map Scale: 1:484 if printed on B size (11"x 117") sheet. N N Meters 0 3 6 12 18 Feet 0 10 20 40 60 JSU b/9U4U b/`JUSU bfYUbU bf`JVYU N ' F N m ^i� n NQQ W M S OI - ' W M W J t00n Q 1' ' {{ S M t o I W � t ' tYr I J r :� 9 "+C ac- o C r� Cc+ q Ca LLiCL _ -¢a �•. � o0 o n d �M1 b C � .� '[p - � - CG-�m-iGv ^'•'='C r� P9010 679020 67903( In 35' 5' 5" 35. 5' 0" m N vA, Custom Soil Resource Report MAP LEGEND MAP INFORMATION Area of Interest (AOI) IZ Very Stony Spot Map Scale: 1:484 if printed on B size (11" x 17"),sheet. Area of Interest (AOI) � Wet Spot The soil surveys that comprise your AOI were mapped at 1:24,000. Soils Other 0 Soil Map Units Special Line Features Warning: Soil Map may not be valid at this scale. Special Point Features r,,L 44.•-� Gully V Blowout Is,J '�' r Short Steep Slope Enlargement of maps beyond the scale of mapping can cause ® Borrow Pit misunderstanding of the detail of mapping and accuracy of soil line M. Other placement. The maps do not show the small areas of contrasting X.. Clay Spot. soils that could have been shown at a more detailed scale. Political Features Closed Depression 0 cities x Gravel Pit water Features Please rely on the bar scale on each map sheet for accurate map measurements. Gravelly Spot y.. Streams and Canals Landfill transportation Source of Map: Natural Resources Conservation Service I Rails Web Soil Survey URL: hftp:Nwebsoitsurvey.nrrs.usda.gov !ova Flow Coordinate System: UTM Zone 17N NAD83 .& Marsh or swamp Interstate Highways x Mine or Quarry .v US Routes This product is generated from the USDA-NRCS certified data as of Major Roads the version date(s) listed below. © Miscellaneous Water (D Perennial Water Local Roads Soil Survey Area: Cumberland County, North Carolina Survey Area Data: Version 10, Jun 5, 2009 v Rock Outcrop + Saline Spot Date(s) aerial images were photographed: 6/22/2006 Sandy Spot The orthophoto or other base map on which the soil fines were Severely Eroded Spot compiled and digitized probably differs from the background imagery displayed on these maps. As a result, some minor shifting C Sinkhole of map unit boundaries may be evident. 37 Slide or Slip Sodic Spot _ Spoil Area j) Stony Spot Custom Soil Resource Report Map Unit Legend Cumberland County, North Carolina (NC051) Map Unit Symbol Map Unit Name Acres in AOI Percent of AOI Bad Blaney loamy sand, 8 to 15 percent slopes 1.6 97.2% FaB Faceville loamy sand, 2 to 6 percent slopes 0.0 2.8% Totals for Area of Interest 1.7 100.0% Map Unit (Descriptions The map units delineated on the detailed soil maps in a soil survey represent the soils or miscellaneous areas in the survey area. The map unit descriptions, along with the maps, can be used to determine the composition and properties of a unit. A map unit delineation on a soil map represents an area dominated by one or more major kinds of soil or miscellaneous areas. A map unit is identified and named according to the taxonomic classification of the dominant soils. Within a taxonomic class there are precisely defined limits for the properties of the soils. On the landscape, however, the soils are natural phenomena, and they have the characteristic variability of all natural phenomena. Thus, the range of some observed properties may extend beyond the limits defined for a taxonomic class. Areas of soils of a single taxonomic class rarely, if ever, can be mapped without including areas of other taxonomic classes. Consequently, every map unit is made up of the soils or miscellaneous areas for which it is named and some minor components that belong to taxonomic classes other than those of the major soils. Most minor soils have properties similar to those of the dominant soil or soils in the map unit, and thus they do not affect use and management. These are called noncontrasting, or similar, components. They may or may not be mentioned in a particular map unit description. Other minor components, however, have properties and behavioral characteristics divergent enough to affect use or to require different management. These are called contrasting, or dissimilar, components. They generally are in small areas and could not be mapped separately because of the scale used. Some small areas of strongly contrasting soils or miscellaneous areas are identified by a special symbol on the maps. if included in the database for a given area, the contrasting minor components are identified in the map unit descriptions along with some characteristics of each. A few areas of minor components may not have been observed, and consequently they are not mentioned in the descriptions, especially where the pattern was so complex that it was impractical to make enough observations to identify all the soils and miscellaneous areas on the landscape. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The objective of mapping is not to delineate pure taxonomic classes but rather to separate the landscape into landforms or landform segments that have similar use and management requirements. The delineation of such segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, however, onsite investigation is needed to define and locate the soils and miscellaneous areas. 10 Custom Soil Resource Report An identifying symbol precedes the map unit name in the map unit descriptions. Each description includes general facts about the unit and gives important soil properties and qualities. Soils that have profiles that are almost alike make up a soil series. Except for differences in texture of the surface layer, all the soils of a series have major horizons that are similar in composition, thickness, and arrangement. Soils of one series can differ in texture of the surface layer, slope, stoniness, salinity, degree of erosion, and other characteristics that affect their use. On the basis of such differences, a soil series is divided into soil phases. Most of the areas shown on the detailed soil maps are phases of soil series. The name of a soil phase commonly indicates a feature that affects use or management. For example, Alpha silt loam, 0 to 2 percent slopes, is a phase of the Alpha series. Some map units are made up of two or more major soils or miscellaneous areas. These map units are complexes, associations, or undifferentiated groups. A complex consists of two or more soils or miscellaneous areas in such an intricate pattern or in such small areas that they cannot be shown separately on the maps. The pattern and proportion of the soils or miscellaneous areas are somewhat similar in all areas. Alpha -Beta complex, 0 to 6 percent slopes, is an example. An association is made up of two or more geographically associated soils or miscellaneous areas that are shown as one unit on the maps. Because of present or anticipated uses of the map units in the survey area, it was not considered practical or necessary to map the soils or miscellaneous areas separately. The pattern and relative proportion of the soils or miscellaneous areas are somewhat similar. Alpha - Beta association, 0 to 2 percent slopes, is an example. An undifferentiated group is made up of two or more soils or miscellaneous areas that could be mapped individually but are mapped as one unit because similar interpretations can be made for use and management. The pattern and proportion of the soils or miscellaneous areas in a mapped area are not uniform. An area can be made up of only one of the major soils or miscellaneous areas, or it can be made up of all of them. Alpha and Beta soils, 0 to 2 percent slopes, is an example. Some surveys include miscellaneous areas. Such areas have little or no soil material and support little or no vegetation. Rock outcrop is an example. 11 Custom Soil Resource Report Cumberland County, North Carolina BaD—Blaney loamy sand, 8 to 15 percent slopes Map Unit Setting Elevation: 160 to 660 feet Mean annual precipitation: 38 to 52 inches Mean annual air temperature: 61 to 70 degrees F Frost -free period: 210 to 245 days Map Unit Composition Blaney and similar soils: 85 percent Description of Blaney Setting Landform: Low hills Landform position (two-dimensional): Shoulder Landform position (three-dimensional): Crest Down -slope shape: Convex Across -slope shape: Convex Parent material: Sandy and loamy marine deposits Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Drainage class. Well drained Capacity of the most limiting layer to transmit water (Ksat): Moderately high (0.20 to 0.57 inlhr) Depth to water table: More than 80 inches Frequency of flooding. None Frequency of ponding: None Available water capacity: Low (about 4.0 inches) Interpretive groups Land capability (nonirrigated). 3e Typical profile 0 to 4 inches: Loamy sand 4 to 25 inches: Loamy sand 25 to 62 inches: Sandy clay loam 62 to 80 inches: Loamy coarse sand FaB—Faceville loamy sand, 2 to 6 percent slopes Map Unit Setting Elevation: 80 to 330 feet Mean annual precipitation: 38 to 55 inches Mean annual air temperature: 59 to 70 degrees F Frost -free period., 210 to 265 days 12 Custom Soil Resource Report Map Unit Composition Faceville and similar soils. 80 percent Description of Faceville Setting Landform: Broad interstream divides on marine terraces, ridges on marine terraces Landform position (two-dimensional): Shoulder, summit Landform positron (three-dimensional): Crest Down -slope shape: Convex Across -slope shape: Convex Parent material: Clayey marine deposits Properties and qualities Slope. 2 to 6 percent Depth to restrictive feature: More than 80 inches Drainage class: Well drained Capacity of the most limiting layer to transmit water (Ksat): Moderately high to high (0.57 to 1.98 inlhr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency ofponding: None Available water capacity: Moderate (about 7.8 inches) Interpretive groups Land capability (nonirrigated): 2e Typical profile 0 to 7 inches: Loamy sand 7 to 17 inches., Loamy sand 17 to 80 inches: Clay 13 References American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing. 24th edition. American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes. ASTM Standard D2487-00. Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe. 1979. Classification of wetlands and deep -water habitats of the United States. U.S. Fish and Wildlife Service FWS/OBS-79131. Federal Register. July 13, 1994, Changes in hydric soils of the United States. Federal Register. September 18, 2002. Hydric soils of the United States. Hurt, G.W., and L.M. Vasilas, editors. Version 6.0, 2006. Field indicators of hydric soils in the United States. National Research Council. 1995. Wetlands: Characteristics and boundaries. Soil Survey Division Staff. 1993. Soil survey manual. Soil Conservation Service. U.S. Department of Agriculture Handbook 18. http://soils,usda.gov/ Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys. 2nd edition. Natural Resources Conservation Service, U.S. Department of Agriculture Handbook 436. http://soils.usda.gov/ Soil Survey Staff. 2006. Keys to soil taxonomy. 10th edition. U.S. Department of Agriculture, Natural Resources Conservation Service. http:/isoils.usda.gov/ Tiner, R.W., Jr. 1985. Wetlands of Delaware. U.S. Fish and Wildlife Service and Delaware Department of Natural Resources and Environmental Control, Wetlands Section. United States Army Corps of Engineers, Environmental Laboratory. 1987. Corps of Engineers wetlands delineation manual. Waterways Experiment Station Technical Report Y-87-1. United States Department of Agriculture, Natural Resources Conservation Service. National forestry manual. http://soils.usda.gov/ United States Department of Agriculture, Natural Resources Conservation Service. National range and pasture handbook. http://www.glti.nrrs.usda.gov/ United States Department of Agriculture, Natural Resources Conservation Service. National soil survey handbook, title 43041. http://soils.usda.gov/ United States Department of Agriculture, Natural Resources Conservation Service. 2006. Land resource regions and major land resource areas of the United States, the Caribbean, and the Pacific Basin. U.S. Department of Agriculture Handbook 296. http://soils.usda.gov/ 14 Custom Soil Resource Report United States Department of Agriculture, Soil Conservation Service. 1961. Land capability classification. U.S. Department of Agriculture Handbook 210. 15 I ATTACHMENT D One -Point and Two -Point Compaction Method ♦. J Compaction Control For fine grained (clayey and silty) soils and for sands with appreciable fines such that normal shaped compaction curves are obtained, results of all compaction tests shall be plotted on a common plot as a family of curves. For each field density test performed, a one -point compaction test, with additional points as needed, shall be performed on the same material on which the field density test was conducted. The one -point compaction test shall be performed on the dry side of the optimum moisture content. For comparison of field density data to the proper laboratory compaction test results, the procedures for the one -point and/or two -point compaction control methods as described in paragraph Compaction Procedure, shall be used. Compaction curves plotted on the family of curves shall be of such a scale that the optimum moisture content can be interpreted to the nearest 0.1 percent and the maximum dry density can be interpreted to the nearest 0.1 pcf (or 2 kg/m). When a one -point test plots outside the range of the family of curves, an additional five -point compaction test shall be performed. Compaction Procedure General The following paragraphs describe methods of relating field density data to desired or specified values. Compaction control of soils requires comparison of fill water content and/or dry density values obtained in field density tests with optimum water content and/or maximum dry density. At a minimum, control shall be in accordance with the One -Point Compaction Method. Where conditions require, the Two -Point Compaction Method shall be used. One -Point Compaction Method The material from the field density test is allowed to dry to a water content on the dry side of estimated optimum, and then compacted using the same equipment and procedures used in the five -point compaction test. Thorough mixing is required to obtain uniform drying; otherwise, results obtained may be erroneous. The water content and dry density of the compacted sample are determined and then used to estimate its optimum water content and maximum dry density as illustrated in Figure I at the end of this section. In Figure 1, the line of optimums is well defined and the compaction curves are approximately parallel to each other, consequently, the one -point compaction method could be used with a relatively high degree of confidence. However, in Figure 2 at the end of this section, the curves are not parallel to each other and in several instances will cross if extended on the dry side. Consequently, the correct curve cannot be determined from the one -point method; therefore, the two -point compaction method should be used. The one -point method should be used only when the data define a relatively good line of optimums. Two -Point Compaction Method 1 • . In the two -point test, one sample of material from the location of the field density test is compacted at the fill water content if thought to be at or on the dry side of optimum water content (otherwise, reduced by drying to this condition) using the same equipment and procedures used in the five -point compaction test. A second sample of material is allowed to dry back about 2 to 3 percentage points dry of the water content of the first sample and then compacted in the same manner. At least one point shall fall within 3 percent of the line of optimums. After compaction, the water contents and dry densities for the two samples are determined. The results are used to identify the appropriate compaction curve for the material being tested as shown in Figure 2 at the end of this section. The data shown in Figure 2 warrant the use of the two -point compaction test because the five -point compaction curves are not parallel. Using point A only, as in the one -point test method, would result in appreciable error as the shape of the curve would not be defined. The estimated compaction curve can be more accurately defined by two compaction points. P ,t; V) z w 0 100 0 i.1.G00 95 (�1.520. 90 (1440) 5 PROCEDURE: LOCUS :OF MAX'. DRY DENS''ITY AND OPT.]MUM`WATER CONTENT (LINE OF OPTIMUMS) ESTIMATED MAX. DENSITY = '104 PCF 0 (1664 Kg/m3) �� OF A � \ O A v� EST]MATED V GOf OPT. We = ,20- i \ os COMi'ACTiON CURVE- FROM FIVE -POINT TEST REQUIRED � \� BY SPECIFICATIONS 10 15 20 25 130 35 WATER CONTENT - 7 1. Point A is the result of a one -point compaction test on material from field density test. This point must be on the dry side of optimum water content. 2. Point O is the estimated optimum water content and maximum density of the fill material based on a projection of point A approximately parallel to the adjacent compaction curves. 3. Point A must plot within 3 percent of the line of optimums. Figure 1. Illustration of one -point compaction method. r' w -11'5 (r`1.840 110 (`1760` '1 05 (1,680 1010, 95 (.1.520 S,C) C1440') 5 PROCEDURE: r 1 1 \ L.00US OF ;MAX. DRY DENSITY AND OPTIMUM WATER CONTENT \ \ (LANE ;OF OPTIMUMS) \ \ EST I MATED, 1. 6 COMPACTION \ CURVE \. p: - \ G Q�as COMPACTION CURVES FROM FIVE —POINT TEST REQUIRED BY SPEC I F.ICAT.I ONS \ 10 1.5 20 25 30 35 WA7ER. 'OQNTENT — '- 1. Points A and B are results of a two -point compaction test on material from field density test. Points A and B must be on the dry side of optimum water content. 2. The estimated compaction curve based on Points A and B establishes Point O on the locus, which is the estimated maximum dry density and optimum water content of the fill material. 3. One point must plot within 3 percent of the line of optimums. Figure 2. Illustration of two -point compaction method.