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SW8110326_HISTORICAL FILE_20110503
STORMWATER DIVISION CODING SHEET POST -CONSTRUCTION PERMITS PERMIT NO. SW8 \\O�> 20 DOC TYPE ❑ CURRENT PERMIT ❑ APPROVED PLANS LV HISTORICAL FILE ❑ COMPLIANCE EVALUATION INSPECTION DOC DATE Z cm 05 0 3 YYYYMMDD ,r11vjnj,qV iaRoldw3 uopnV angewiyy 1 Nwnunddo lenb3 uy ) 6io F jjenbialeou m :tawalul BUI[O.IBDgIJON BCL9-R9-LL9-I :aOwas iawolsnot 600Z-09C-OL6 XVd 19LZL-96L-OL6 auo4d oU0 90VBZ eupweo 4PON'uolbuiwpM'uoisualx3 0n40 leuipleD LZt aoigo leuo16a8 uol6uiwliM al!d ialemwols a0140 1eu0169a uol6ulwl!M lu9w96euelry lelseoO to uo!s!nl0 suogoadsul bu!ppng /lunoo molsu0 'joloadsul 3d 'uewd!gS �eZ o0 9Z£OL L I!Wjad 90 I LOZ\OH 9Z£O L M LOZ\sloafoLd 'g sl!LWGd\J91emwJ0IS\S0M\ S :fdl /SOJ Al!lenO aaleMjo uolsln!p Jos!vuadnS aalemwiols AOoS .O la6joaO /lajaouls SIZL-96L (0l6) le aw JO'uosugof AIIGN loeluoo aseald 'aallew slgl buiumuoo uo!lewao;ul leuoll!ppe paau io 'suo!lsenb AUe aneq noR;l 6u!pu!q pue lew; aq llegs llwaad s!ql @pew aie spuewap Bons ssalufl 'LbbL-I 19LZ ON '019lea'L417LZ J9meJ0 'O d 's6uue9H an!leals!u!wpV 10 90!40 agl ql!m pal!; pue 'salnlelS lejauaO eugaeO WON agl;o 8091 JaldegO of bu!Lwo;uoo 'uoggad uallum e;o wjo; agl uw aq lsnw lsanbai s!ql l!wjad s!gl;o ld!aoaj 6wmollo; step (0£) Aingl u!gl!m lsanbai uallum uodn buueag Ajoleo!pnfpe ue lsanbea of lg6u aql aneg nog( 'algeldaooeun aje l!Lwad s!gl ui pau!eluoo suogel!wg ao 'sluawannbai 'sped Aue;l swalgad Emelldwoo amin; ui llnsaa ll!m walsRs luawa6euew jalemwols agl;o aoueualu!ew pue uollejado col walsAs alenbape ue gs!lgelsa of aml!ed l!Lwad s!gl uw sluawannbai aoueualuien pue uo!lejado all of uo!lualle le!oads Aed aseald wajagl pa!;loads se suogel!w!l pue suoll!puoo aq) of loafgns aq pegs pue ' IZOZ 'E Aen I!lun aouenss! 10 alep all woa; an!I0849 aq llegs llwaad sill loafoad loafgns agl;o uo!lonalsuoo aql jol ' I IOZ '£ Aen paleP 9Z£0 L 18MS 'ON I!wJ@d 6ufpJemao; aye aM 000L HZ O`dON V9I 91l!1 PUe I IZ-90OZ me3 uo!ssaS ui glio; las suo!lelnbaa jalemwjolS agl gl!m Aldwoo ll!m 'pasodad se 'loafoid agl legl pou!waalep seg suogeo!;!0ads pue sueld all;o malnaJ _4elS I IOZ ' 1Z I!jdy uo (OI£ I-d) Ll!I!oed luaweuwluoO leul-aid Jo; uo!leopddV l!Lujad luawa6euew jalemlwolS alaldwoo a p9n!a0aa 901�0 leu0169H u016wwl!m aql aaNee Jw Jeaa /flunoO molsuo ;oafoid uollua;aa-ol8 lefojawwoo Aj!suaa y6lH (o6CVd) AlWoe3 3u8w8ul;uo3 lelal-aad 9ZS06I 8MS 'ON llwaad JalemwJolS :IoofgnS L1798Z ON 'aunafal dweO peon laegoln 9001 aunafa-1 dweO aseg sdjoO auuew aunafag dweO aseg sdjoO auuew 'aao!.4O bulpuewwoO jao!yO "joM ollgnd Alndap '3d 'JW9 H PeO JW I lOZ E Aen tielaiaaS ioloanp JowanoO uewaaad a94 su!IInS'H uaaloO anpiad sane3 Auanag Llllenp JaleM 10 uols!nla saoanosa�j lein)eN pue }uawuoJinu3 }o )uaw)Jedaa eupoaeo WON MUM �PCGOV ; 810 Z abed loafoJd slgl woJl lol AUe 10 ales pue uolslnlpgns aql of Joud uolleo1llpow liwJad e winbaJ Minn AlJadoJd aql 10 uoisinipgns aql -ulaag palou se ldeoxe 'AlJadoJd aql 10 uollJod AUe 10 ales pue uolslnlpgns aq) Jol Mope lou seop 11wJad sigl .9 walsRs loJluoo JaleMwJols pappiad aql olul paloaip aq lsnw loafoJd sigl to eaJe a6eweJp palllwJad aql ulgllM eaJe uodn-lilnq Ile woJl l;ounJ agl 4 -laa1 aenbs oJaz of pallwll sl sueld agl uo unnogs seaJe luawdolanap aJnlnl paleu6lsep aql Jot eaJe uodn-lllnq aql sueld panoJdde agl pue sluawnoop uolleoildde agl Jad pue 'llwJad slgl 10 9•1 uopoaS ul poleoipw se eae uodn-llmq 10 lunowe agl of pallwll aq IIIM loeJl agl £ 'AlanlloadsaJ 'eaae snoln.iadwl 10 leal aJenbs 9l/'OZ PUe 0L6'86 woa11}ouni aql alpueg of pau6lsap uaaq aneg sloJluoo JaleMwJols aql liwJad sigl to 9•1 uolloaS ul paglJosep se 11ounJ JaleMwJols 10 luauJa6euew agl Jot panadde uaeq seq walsAs Jalemmols sigl -elep buipoddns Jaglo pue uolleolidde aql ui paquosap JalemwJols 10 awnlon pue amleu aql of loadsaJ gllM Aluo anlloal;a si liwJad sigl SONV4NVIS NJIS34 'I :suoge8wll pue suoilipuoo pa1lloads bulMollol aql of loafgns aq llegs pue ' L ZOZ '£ AeW pun aouenssi 10 alep agl woJ1 anlloal;a aq ilegs llwJad slgl 'llwJad s14110 }Jed a paJapisuoo pue Alllenp JaleM 10 uoisini0 eql !q panadde pue gllnn alit uo pue pagoelle se elep bullJoddns Jaglo pue suoileogioads pue sueld luawa6euew JaleMwJols panadde agl pue („solniialennwiols„ agl se 01 paJJalaJ AIleJanas pue Allulof JalleaJaq) 0006 HZ OVON V96 PUe 4 LZ-800Z Meg uolssaS 10 suoisinoJd aql gIIM eoueljdwoo ul swseq uolluelaJoiq Z 10 aoueuelwew pue uolleJado 'uollonJlsuoo 3Hl 210d AlunoO molsuO 'auna(a3 dweO 'pa /,Djad speauo 9 7S ueounQ (okck-d) Av!oed luewauljuoO leul-aid ouna(a-7 dweO ase8 sdioO auueyV Ol 031NV80 A83H3H SI NOISSIIN 13d suolleln6a�j pue 'salna 'snne-1 algeoildde Jaglo pue 'papuawe se eulloJeO 41JON 10 salnlelS leJauaO 'Ct7 . 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'wJolS u61saa 0 :Zli 'al!sllO s b d 0 u w OL6'86 :Z4 'al!suO OL6'86 :Zll'saoepns snopuadwl lelol q 0 :Zli 'al!sgo 17017'8£Z :Zu 'al!suO b04'8£Z saaoe 'easy 96euleja e 6# ulseg :sawg lie le uo!l!puoo u6!sap le poulelu!ew aq lsnw pue u!seq uogualejo!q aql ui pap!noid pue law ueaq aneq eualuo u61sap 6u!nnopo; aql Di 9ZU06 8MS 'ON l!wlad swalsf%S luawabeuelnl JolemwJolS alelS State Stormwater Management Systems Permit No. SW8 110326 The permittee shall at all time provide the operation and maintenance necessary to assure the permitted stormwater system functions at optimum efficiency. The approved Operation and Maintenance Plan must be followed in its entirety and maintenance must occur at the scheduled intervals including, but not limited to: a. Semiannual scheduled inspections (every 6 months). b. Sediment removal. C. Mowing and re -vegetation of slopes and the vegetated filter. d. Immediate repair of eroded areas. e. Maintenance of all slopes in accordance with approved plans and specifications. f. Debris removal and unclogging of outlet structure, orifice device, flow spreader, catch basins and piping. g. Access to the outlet structure must be available at all times. Records of maintenance activities must be kept and made available upon request to authorized personnel of DWQ. The records will indicate the date, activity, name of person performing the work and what actions were taken. The facilities shall be constructed as shown on the approved plans. This permit shall become void unless the facilities are constructed in accordance with the conditions of this permit, the approved plans and specifications, and other supporting data. Upon completion of construction, prior to issuance of a Certificate of Occupancy, and prior to operation of this permitted facility, a certification must be received from an appropriate designer for the system installed certifying that the permitted facility has been installed in accordance with this permit, the approved plans and specifications, and other supporting documentation. Any deviations from the approved plans and specifications must be noted on the Certification. 7. If the stormwater system BMP is used as an Erosion Control device during construction, more frequent maintenance will be required during construction to maintain functionality. Once the drainage area is stabilized and prior to occupancy of the facility, the BMP must be fully restored to design condition. 8. Access to the stormwater facilities shall be maintained via appropriate recorded easements at all times. 9. All stormwater collection and treatment systems must be located in public rights - of -way, dedicated common areas or recorded easements. The final plats for the project will be recorded showing all such required rights -of -way, common areas and easements, in accordance with the approved plans. 10. The permittee shall submit to the Director and shall have received approval for revised plans, specifications, and calculations prior to construction, for any . modification to the approved plans, including, but not limited to, those listed below: a. Any revision to any item shown on the approved plans, including the stormwater management measures, built -upon area, details, etc. b. Project name change. C. Transfer of ownership. d. Redesign or addition to the approved amount of built -upon area or to the drainage area. e. Further subdivision, acquisition, lease or sale of all or part of the project area. The project area is defined as all property owned by the permittee, for which Sedimentation and Erosion Control Plan approval or a CAMA Major permit was sought. f. Filling in, altering, or piping of any vegetative conveyance shown on the approved plan. Page 4 of 8 State Stormwater Management Systems Permit No. SW8 110326 11. Prior to construction, the permittee shall submit final site layout and grading plans for any future development areas with BUA allocations, as designated on the approved plans. 12. A copy of this permit, the permit application documents, the approved plans and specifications shall be maintained on file by the Permittee for the life of the permit. 13. The Director may notify the permittee when the permitted site does not meet one or more of the minimum requirements of the permit. Within the time frame specified in the notice, the permittee shall submit a,written time schedule to the Director for modifying the site to meet minimum requirements. The permittee shall provide copies of revised plans and certification in writing to the Director that the changes have been made. III. GENERAL CONDITIONS In the event that the facilities fail to perform satisfactorily, including the creation of nuisance conditions, the Permittee shall take immediate corrective action,. including those as may be required by this Division, such as the construction of additional or replacement stormwater management systems. 2. This permit is not transferable to any person or entity except after notice to and approval by the Director. At least 30 days prior to a change of ownership, or a name change of the permittee or of the project, or a mailing address change, the permittee must submit a completed and signed Name/Ownership Change form to the Division of Water Quality, accompanied by the appropriate documentation as listed on the form. The approval of this request will be considered on its merits and may or may not be approved. 3. The permittee is responsible for compliance with all permit conditions until such time as the Division approves a permit transfer request. Neither the sale of the project in whole or in part nor the conveyance of common area to a third party shall be considered an approved permit transfer request. 4. Failure to abide by the conditions and limitations contained in this permit may subject the Permittee to enforcement action by the Division of Water Quality, in accordance with North Carolina General Statute 143-215.6A to 143-215.6C. The issuance of this permit does not preclude the Permittee from complying with any and all statutes, rules, regulations, or ordinances, which may be imposed by other government agencies (local, state, and federal) having jurisdiction. 6. The permittee grants DENR Staff permission to enter the property during normal business hours for the purpose of inspecting all components of the permitted stormwater management facility. 7. The permit may be modified, revoked and reissued or terminated for cause. The filing of a request for a permit modification, revocation and re -issuance or termination does not stay any permit condition. 8. Unless specified elsewhere, permanent seeding requirements for the stormwater control must follow the guidelines established in the North Carolina Erosion and Sediment Control Planning and Design Manual. 9. Approved plans and specifications for this project are incorporated by reference and are enforceable parts of the permit. Page 5 of 8 State Stormwater Management Systems Permit No. SW8 110326 10. At least 180.days prior to the expiration date of this permit, the permittee shall submit a permit renewal request to the Division of Water Quality along with the required application feet. Permit issued this the 3`d day of May 2011. NORTH CAROLINA ENVIRONMENTAL MANAGEMENT COMMISSION By Authority of the Environmental Management Commission Page 6 of 8 State Stormwater Management Systems Permit No. SW8 110326• Pre -Trial Confinement Facility (P-1310) Stormwater Permit No. SW8 110326 Onslow County Designer's Certification I, , as a duly registered in the State of North Carolina, having been authorized to observe (periodically/ weekly/ full time) the construction of the project, (Project Name) for (Project Owner) hereby state that, to the best of my abilities, due care and diligence was used in the observation of the project construction such that the construction was observed to be built within substantial compliance and intent of the approved plans and specifications. The checklist of items on page 2 of this form is included in the Certification. Noted deviations from approved plans and specification: Signature Registration Number Date SEAL Page 7 of 8 DWQ USE ONLY Date Received Fee Paid Permit Number -? e U/�� Applicable Rules: ❑ Coastal SW —1995 ❑ Coastal SW — 2008 ❑ Ph II - Post Construction (select all that apply) ❑ Non -Coastal SW- HQW/ORW Waters ❑ Universal Stormwater Management Plan ❑ Other WQ M mt Plan: State of North Carolina Department of Environment and Natural Resources Division of Water Quality STORMWATER MANAGEMENT PERMIT APPLICATION FORM This form may be photocopied for use as an original I. GENERAL INFORMATION 1. Project Name (subdivision, facility, or establishment name -should be consistent with project name on plans, specifications, letters, operation and maintenance agreements, etc.): Pre -Trial Confinement Facility (P-1310) 2. Location of Project (street address): Adjacent to Intersection of Duncan Street and Sneads Ferry Road City:Camp Lejeune County:Onslow Zip:27547 3. Directions to project (from nearest major intersection): From Main Gate, Camp Lejeune, travel south along Holcomb Blvd. Bear left onto Sneads Ferry Road and make right onto Duncan Street. Project site is approximately 300 feet west of Sneads Ferry Road adjacent to 4. Latitude:34° 40' 04" N Longitude:77° 19' 29Co" W of the main entrance to the project. II. PERMIT INFORMATION: 1. a. Specify whether project is (check one): ®New ❑Modification b.If this application is being submitted as the result of a modification to an existing permit, list the existing permit number , its issue date (if known) , and the status of construction: ❑Not Started ❑Partially Completed* ❑ Completed* *provide a designer's certification 2. Specify the type of project (check one): ❑Low Density ®High Density ❑Drains to an Offsite Stormwater System ❑Other 3. If this application is being submitted as the result of a previously returned application or a letter from DWQ requesting a state stormwater management permit application, list the stormwater project number, if assigned, and the previous name of the project, if different than currently proposed, 4. a. Additional Project Requirements (check applicable blanks; information on required state permits can be obtained by contacting the Customer Service Center at 1-877-623-6748): ❑LAMA Major ❑NPDES Industrial Stormwater ®Sedimentation/Erosion Control: 8 ac of Disturbed Area ❑404/401 Permit: Proposed Impacts b.If any of these permits have already been acquired please provide the Project Name, Project/Permit Number, issue date and the type of each permit:Erosion Control Permit -Permit ONSLO-2011-054 (Issued Dec. 2, 2010) Form SWU-101 Version 07Jun2010 Page I of 6 Ill. CONTACT INFORMATION 1. a. Print Applicant / Signing Official's name and title (specifically the developer, property owner, lessee, designated government official, individual, etc. who owns the project): Applicant/Organization:Commanding Officer Marine Corps Base Camp Leieune Signing Official & Title:Carl H. Baker, PE -Deputy Public Works Officer b.Contact information for person listed in item la above: Street Address:1005 Michael Road City:Camp Leieune State:NC Zip4547 Mailing Address (if applicable): City: State: Zip: Phone: (910 ) 451-5950 Fax: (910 ) 451-2927 Email:carl.h.baker@usmc.mil c. Please check the appropriate box. The applicant listed above is: ® The property owner (Skip to Contact Information, item 3a) ❑ Lessee* (Attach a copy of the lease agreement and complete Contact Information, item 2a and 2b below) ❑ Purchaser* (Attach a copy of the pending sales agreement and complete Contact Information, item 2a and 2b below) ❑ Developer* (Complete Contact Information, item 2a and 2b below.) 2. a. Print Property Owner's name and title below, if you are the lessee, purchaser or developer. (This is the person who owns the property that the project is located on): Property Owner/Organization: Signing Official & Title: b.Contact information for person listed in item 2a above: Street Address: Mailing Address (if. City: State: Phone: { ) Fax: 3. a. (Optional) Print the name and title of another contact such as the project's construction supervisor or other person who can answer questions about the project: Other Contact Person/Organization:David Towler Signing Official & Title: b.Contact information for person listed in item 3a above: Mailing Address:1005 Michael Road City:Cam�p LeLeieune State:NC Zip:27547 Phone: (910 ) 451-3235 Fax: { ) Email:david.towler@usmc.mil 4. Local jurisdiction for building permits: Camp Lejeune Point of Contact: Phone #: r> Form SWU-101 Version 07Jun2010 Page 2 of 6 IV.' PROJECT INFORMATION 1. In the space provided below, briefly summarize how the stormwater runoff will be treated. Stormwater will be treated by two bioretention cells Runoff will be conveyed via sheet flow into vegetated swales which will then send water to the BMP's for treatment. 2. a. If claiming vested rights, identify the supporting documents provided and the date they were approved: ❑ Approval of a Site Specific Development Plan or PUD Approval Date: ❑ Va id Building Permit Issued Date: ❑ Other: Date: b.lf claiming vested rights, identify the regulation(s) the project has been designed in accordance with: ❑ Coastal SW —1995 ❑ Ph II — Post Construction 3. Stormwater runoff from this project drains to the White Oak River basin. 4. Total Property Area: 8.89 acres 5. Total Coastal Wetlands Area: 0 acres 6. Total Surface Water Area: 0 acres 7. Total Property Area (4) —Total Coastal Wetlands Area (5) —Total Surface Water Area (6) = Total Project Area': 8.89 acres Total project area shall be calculated to exclude the following the normal pool of im ounded structures, the area between the banks of streams and rivers, the area below the Normal High Water (N W) line or Mean High Water (MHW) line, and coastal wetlands landward from the NHW (or MHW) line. The resultant project area is used to calculate overall percent built upon area (BUA). Non -coastal wetlands landward of the NHW (or MHW) line may be included in the total project area. S. Project percent of impervious area: (Total Impervious Area / Total Project Area) X 100 = 30.91 % 9. How many drainage areas does the project have?2 (For high density, count 1 for each proposed engineered stormwater BMP. For low density and other projects, use 1 for the whole property area) 10. Complete the following information for each drainage area identified in Project Information item 9. If there are more than four drainage areas in the project, attach an additional sheet with the information for each area provided in the same format as below. Basin Information Drainage Area 1 Drainage Area 2 Drama e Area 3 Drainage Area Receiving Stream Name UT Cogdels Creek UT Cogdels Creek Stream Class * SC -NSW SC -NSW Stream Index Number * 19-23 19-23 Total Drainage Area (sf) 238,404 51,244 On -site Drainage Area (sf) 238,404 51,244 Of -site Drainage Area (sf) 0 0 Proposed Impervious Area** (sf) 98,970 20,716 % Impervious Area** (total) 41.51 40.42 Im ervious" Surface Area Drainage Area 1 Draina e Area 2 Drainage Area _ Drainage Area _ On -site Bui dings/Lots (sf) 31,864 2,114 On -site Streets (sf) 29,468 17,323 On -site Parking (sf) 31,413 On -site Sidewalks (sf) 2,025 1,279 2011 Other on -site (sf) 4,200 Future (sf) BY: Off -site (sf) Existing BUA*** (sf) Total (sf): 98,970 20,716 Stream Class and Index Number can be determined at: htt : [portal.ncdenr.orQ/web/ems csu/classif cations ** Im ervious area is defined as the built upon area including, but not limited to, buildings, roads, parking areas, sidewalks, gravel areas, etc. Report only that amount of existing BUA that will remain after development. Do not report any existing BUA that is to be removed and which will be replaced by new BUA. Form SWU-101 Version 07Jun2010 Page 3 of 11. How was the off -site impervious area listed above determined? Provide documentation. Projects in Union County: Contact DPVQ Central Office staff to check if the project is located within a Threatened & Endangered Species watershed that maybe subject to more stringent stormwater requirements as per NCAC 02B .0600. V. SUPPLEMENT AND O&M FORMS The applicable state stormwater management permit supplement and operation and maintenance (O&M) forms must be submitted for each BMP specified for this project. The latest versions of the forms can be downloaded from ho-.ZZportal.ncdenr.org/web/wq/ws/su/bmp-manual. V1. SUBMITTAL REQUIREMENTS Only complete application packages will be accepted and reviewed by the Division of Water Quality (DWQ). A complete package includes all of the items listed below. A detailed application instruction sheet and BMP checklists are available from htt ://portal.ncdenr.or, webLwq/ws/su _statesw/forms does. The complete application package should be submitted to the appropriate DWQ Office. (The appropriate office may be found by locating project on the interactive online map at htt//tortal.ncdenr.�/web/w /ws su maps.) Please indicate that the following required information have been provided by initialing in the space provided for each item. All original documents MUST be signed and initialed in blue ink. Download the latest versions for each submitted application package from httpl/portal.ncdenr.00rweb/wq/ws/su/statesw/forms does. Initials 1. Original and one copy of the Stormwater Management Permit Application Form. 2. Original and one copy of the signed and notarized Deed Restrictions & Protective Covenants Form. (if required as per Part Vll below) 3. Original of the applicable Supplement Form(s) (sealed, signed and dated) and O&M agreement(s) for each BMP. 4. Permit application processing fee of $505 payable to NCDENR. (For an Express review, refer to http://www.envhelp.org/pages/onestopexpress.html for information on the Express program and the associated fees. Contact the appropriate regional office Express Permit Coordinator for additional information and to schedule the required application meeting.) 5. A detailed narrative (one to two pages) describing the stormwater treatment/management for the project. This is required in addition to the brief summary provided in the Project Information, item 1. 6. A USGS map identifying the site location. If the receiving stream is reported as class SA or the receiving stream drains to class SA waters within'7i mile of the site boundary, include the'h mile radius on the map. 7. Sealed, signed and dated calculations. 8. Two sets of plans folded to 8.5" x 14" (sealed, signed, & dated), including: a. Development/Project name. b. Engineer and firm. c. Location map with named streets and NCSR numbers. d. Legend. e. North arrow. f. Scale. g. Revision number and dates. h. Identify all surface waters on the plans by delineating the normal pool elevation of impounded structures, the banks of streams and rivers, the MHW or NHW line of tidal waters, and any coastal wetlands landward of the MHW or NHW lines. • Delineate the vegetated buffer landward from the normal pool elevation of impounded structures, the banks of streams or rivers, and the MHW (or NHW) of tidal waters. i. Dimensioned property/project boundary with bearings & distances. j. Site Layout with all BUA identified and dimensioned. k. Existing contours, proposed contours, spot elevations, finished floor elevations. I. Details of roads, drainage features, collection systems, and stormwater control measures. in. Wetlands delineated, or a note on the plans that none exist. (Must be delineated by a qualified person. Provide documentation of qualifications and identify the person who made the determination on the plans. n. Existing drainage (including off -site), drainage easements, pipe sizes, runoff calculations. o. Drainage areas delineated (included in the main set of plans, not as a separate document). p. Vegetated buffers (where required). Form SWU-101 Version 07Jun2010 Page 4 of 6 9. 'Copy of any applicable soils report with the associated SHWT elevations (Please identify elevations in addition to depths) as well as a map of the boring locations with the existing elevations and boring logs. Include an 8.5"xll" copy of the NRCS County Soils map with the project area clearly delineated. For projects with infiltration BMPs, the report should also include the soil type, expected infiltration rate, and the method of determining the infiltration rate. (Infiltration Devices submitted to WiRO: Schedule a site visit for DWQ to verify the SH WT prior to submittal, (910) 796-7378.) 10. A copy of the most current property deed. Deed book: Page No:t 11. For corporations and limited liability corporations (LLC): Provide documentation from the NCg Secretary of State or other official documentation, which supports the titles and positions held by the persons listed in Contact Information, item la, 2a, and/or 3a per NCAC 2H.1003(e). The corporation or LLC must be listed as an active corporation in good standing with the NC Secretary of State, otherwise the application will be returned. http: / / www.secretary.state.nc.us /Corporations /CSearch.asi)x [rANW11x�F�StT 7tlTti[4�i (i] Y:`.Ci7�sL�Tilfx iPlti�L�Pix I V016� For all subdivisions, outparcels, and future development, the appropriate property restrictions and protective covenants are required to be recorded prior to the sale of any lot. If lot sizes vary significantly or the proposed BUA allocations vary, a table listing each lot number, lot size, and the allowable built -upon area must be provided as an attachment to the completed and notarized deed restriction form. The appropriate deed restrictions and protective covenants forms can be downloaded from httl2://12ortal.ncdenr.org/web/wq/ws/su/statesw/forms does. Download the latest versions for each submittal. In the instances where the applicant is different than the property owner, it is the responsibility of the property owner to sign the deed restrictions and protective covenants form while the applicant is responsible for ensuring that the deed restrictions are recorded. By the notarized signature(s) below, the permit holders) certify that the recorded property restrictions and protective covenants for this project, if required, shall include all the items required in the permit and listed on the forms available on the website, that the covenants will be binding on all parties and persons claiming under them, that they will run with the land, that the required covenants cannot be changed or deleted without concurrence from the NC.DWQ, and that they will be recorded prior to the sale of any lot. VIII. CONSULTANT INFORMATION AND AUTHORIZATION Applicant: Complete this section if you wish to designate authority to another individual and/or firm (such as a consulting engineer and/or firm) so that they may provide information on your behalf for this project (such as addressing requests for additional information). Consulting Engineer:Zak Shipman, PE Consulting Firm: Timmons Group Mailing Address:5410 Trinity Road, Suite 112 State:NC Zip:27607 Phone: (919 ) 866-4937 Fax: (919 ) 859-5663 Email:zak.shil2man@timmons.com timmons.com IX. PROPERTY OWNER AUTHORIZATION (if Contact Information, item 2 has been filled out, complete this section) 1. •r I, (print or type name of person listed in Contact Information, item 2a) _. certify that.I own the pproperty identified in this permit application, and thus give permission to (print or type name of person listed in Cantnct Information, item ln) with (print or type name ojorgnnizntion listed in Contact Information, item la) to develop the project as currently proposed. A copy of the lease agreement or pending property sales contract has been provided with the submittal, which indicates the party responsible for the operation and maintenance of the stormwater system. j MAR 2 4 2011 Form SWU-101 Version 07Jun2010 Page 5 of 6 As the legal property owner I acknowledge, understand, and agree by my signature below, that if my designate& agent (entity listed in Contact Information, item 1) dissolves their company and/or cancels or defaults on their' lease agreement, or pending sale, responsibility for compliance with the DWQ Stormwater permit reverts back to me, the property owner. As the property owner, it is my responsibility to notify DWQ immediately and submit a completed Name/Ownership Change Form within 30 days; otherwise I will be operating a stormwater treatment facility without a valid permit. I understand that the operation of a stormwater treatment facility without a valid permit is a violation of NC General Statue 143-215.1 and may result in appropriate enforcement action including the assessment of civil penalties of up to $25,000 per day, pursuant to NCGS 143-215.6. Signature: Date: I, a Notary Public for the State of . County of do hereby certify that personally appeared before me this _ day of and acknowledge the due execution of the application for a stormwater permit. Witness my hand and official seat, SEAL My commission X. APPLICANT'S CERTIFICATION I, (print or type name of person listed in Contact Information, item 1a) Cam I gck Ke.r certify that the information included on this permit application form is, to the best of my knowledge, correct and that the project will be constructed in conformance with the approved plans, that the required deed restrictions and protective covenants will be recorded, and that the proposed project complies with the requirements of the applicable stq n water rukvundgr 15A NCAC 21-1.1000, SL 2006-246 (Ph. II - Post Construction) or SL 2008-211. I, before me thislcLv stormwater permit 0r Ft 5 a Notary Public for the State of KOC4N QA(D\lY)O-,, County of _, do hereby certify that Cox I 60.-ker personally appeared ay of Feinr u� O(L and ac�nowled�e the due execution of the application for a Witness my hand and official seal, SYLVIA NORRIS NOTARY PUBLIC ONSLOW COUNTY Wn [My COMMISSION EXPIRES SEAL My commission expires .3 aots Form SWU-101 Version 07Jun2010 Page 6 of 6 n a NtlId BOON N"l $10311HOdVA313SOW ai 1,lIl10tl31N3W3NIdNOO lM211-3Hd �� vxai na.. reior � r„r�m •`e j zz 3Nf13f3l dWtlO OLEL-d:()21I/1N:�1 {AIV�J, i gar � � � 3nnarazawv= axn3rn mm 3sreaxm 3vrcm p p l f E 1 .w 1NV101W-ONbWW070NIa33Nl`JN3 S31111gVl ltlAtlN �r� 4 1= a o Q ` 0 z z E e ' OOO �.r� II 5 'a °0` �e LU 0 U 07 Q ) J Design Calculations Pre -Trial Confinement Facility Camp Lejeune, North Carolina Owners: NAVFAC MidAtlantic Prepared by: Timmons Group 5410 Trinity Road Suite 112 Raleigh, NC 27607 Date: 1-21-11 Revised 3-23-11 Revised 4-20-11 ��.eee• TIMMONS GROUP YOUR VISION >CNI IIV FO TNROUON OURS. xw-.Ummem.�em 0350271� ; ,GINE,�\ APR 2 1 2011 Project Name and File Number: Pre -Trial Confinement Facility; 30032 I 1 NCDENR Treatment Volume and Watershed Analysis 1 1 I Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ C.A. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: aAS�nl y IhcwvTAeNr zoe '.af1C ft ^' Z�diyuN SF 5.97A,) i ..pcR��e„a Ao�n- Qv�a'10 SF p •�e0�®�1w e U TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. C .y 5410 Trinity Road. TEL 919.866.4951 Suite 112 FA 919.859.5663 Raleigh, NC 27607 IAe 1 41l f�i ltvo % CA�Lu�ATI' 1 a^TTAe*T' VO1_4W6•. rr 5r fC Is AI aT 4Mjd^&-z ff coUstoEwnnHs; WAtE25{�D 5�-�`�J> ��-o.ohra,�LAJv = o•os *D9�D\41�i1�= 0.4235E J= �''�2v R•VY�' 3(a3o�o�1•z'�1��''S��S•4?� = izlcc�re cr' BIO-RETENTION AREA"I" DESIGN SHEET Project Information Project Name: Pre -Trial Detainee Center Timmons Project #: 30022 Designed by: DA Date: 4/19/2011 Revised by: Date: Checked by: ZS Date: 4/19/2011 Per the Julv 2007 BMP Manual sizina is based on the Site Runoff Volume for the 1.5" runoff I. Runoff Treatment Volume Simple Method Runoff for 1.5" design storm: Bioretention Cell Volume Under overflow. 12616 cf 17,020 CF 1 of II. Bio-retention Depth and Soil Type Minimum depth of bio-retention area = Conductivity of Bio-Soil Mix Soil Conductivity K n/hr Sand 6 Loamy Sand 2 Sandy Loam 0.5 - 1 K, = 2.0 2ft 71 Site Soil Conductivit Soil Conductivit n/hr W B 1 1.28 Underdrains to be used to drain bioretention area Bio-soil '�7 Water Fill Soil Layer- With Set Hydraulic Conductivity (K). K expected to range ` I* from 0.5 to 6 m1hr (1-2 in/hr TYP) Q L Q H Rock Layer w/ rain Pipes III. Calculate Water Draw Throu h R e _ 1 q- t c).bq Q(cfs)=(2.3E-5)'K, *A H/L LZ Where: Q = Flow (Rate of draw) through Bio-Retention Soil (cfs) •�tk '1.IO� K„y = Hydraulic Conductivity of Soil (in/hr) A = Surface Area of Bio-Retention Area (sf) H = Height of water above gravel envelope/drainage pipe zone L = Thicknes of Soil (as determined above) �L .� K„9= 2.0 in/hr -�Aj� A = I 14.920 'sf H3 = 2.67 ft L3 = 2.0 ft 3 H - L, (or unless L is small, such as 2.0 feet), allow H/L = 1 Q= 0.92 cfs Find time to drawdown water from inundation to saturation at surface: Bioretention Volume (V,.,) = SA x Depression Depth V,.,=(_ 14_920Icf Time to remove V,-j of water at flowrate, Q Ta-t = WdQ T,., = 16284 seconds T,-r = 4.52 hours < 12 hours 2 of Time to drawdown water from saturation at surface to X feet below surface: Porosity, n = 0.45 X = 2.0 ft Calculate volume of water to drawdown in 24 feet of soil: V,, = X (ft)' SA' n V,.z = 13428 cf Time to remove water from V,.,: T,_Z = V,.,/Q T,.2 = 14656 seconds T,.z = 4.07 hours Total time to draw water through soil: Time = Ts.r + T,.z Drawdown Time= 8.59 hours <48 hours IV. Sizing Underdrain Pioes and Gravel Envelooe Q = 0.92 cis Size drains so they are able to carry 10X the sail drawdown 0 = 9.2 cfs Manning Roughness Coefficients: Pipe Type and Diameter Manninq Roughness Coefficient 4" Single Wall Corrugated Plastic 0.0145 4" Smooth Wall Plastic 0.0105 6" Single Wall Corrugated Plastic 0.0145 6" Smooth Wall Plastic 0.0105 8" Single Wall Corrugated Plastic 0.0155 N * D = 16 * (O•nls"0.5)".375 n = 0.0105 s = 0.0025 (internal slope - recommended 0.5%) N • D = 3.6 inches • 3.2 inches is less than 5.13 N=0 3.6 inches Is less than 5.13 Inches, therefore, two 2 " PVC pipe, or smooth wall plastic pipes are required. The gravel envelope surrounding the drainage pipe to be 8" deep at a minimum. * Refer to Hyraflow calculations for primary and emergency overflow calculations. 3 of Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ C.A. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: 201 'I Ito SF c ••0000 u TIMMONS GROUP N 5 YOUR VISION ACHIEVED THROUGH OURS. C .y 5410 Trinity Road TEL 919.866.4951 Suite 112 FAX 919.859.5663 Raleigh, INC 27607 Iu f - 440, hi/. u5E 91. fua tAeT*00 --ra CAL.CAa -rE IiZnT✓.2�+1 yoL4Vrc. — R voFF 'aw li= I S" OfTb4w �V= 0,01c TDAAASJ = 0.u5 t 0, I (6,VWL�= V° F-V rc $li3o �bS ",`0.4IS-76)C I I�b> = cJCo ar BIO-RETENTION AREA "2" DESIGN SHEET Project Information Project Name: Pre -Trial Detainee Center Timmons Project #: 30022 Designed by: DA Date: 3/23/2011 Revised by: Date: Checked by: ZS Date: 3/23/2011 Design Notes: • Per the July 2007 BMP Manual sizing is based on the Site Runoff Volume for the 1.5" runoff. I. Runoff Treatment Volume Simple Method Runoff for 1.5" design storm: 2649 CF Bioretention Cell Volume Under overflow: 3868 CF 0 1 of II. Bio-retention Depth and Soil Type Minimum depth of bio-retention area = 2 ft Conductivity of Bio-Soil Mix Soil Conductivity K n/hr Sand 6 Loamy Sand 2 Sandy Loam 0.5 - 1 K„y = 2.0 Site Soil Conductivity Soil F Conductivi (in/hr) W B 1 1.28 Underdrains to be used to drain biorelention area Sio-soil 0 Water Fill Soil Layer- With Set Hydraulic Conductivity (K). K expected to range from 0.5 to 6 in/hr (1-2 in/hr TYP) Rock Layer w//Arain Pipes n Rate \ \ \ L Q(cfs) = (2.3E-5)'K.,-A-H/L I ,,,, ! I L� I 1 =1 (7 Where: Q = Flow (Rate of draw) through Bio-Retention Soil (cfs) K„y = Hydraulic Conductivity of Soil (in/hr) A = Surface Area of Bio-Retention Area (sf) H = Height of water above gravel envelope/drainage pipe zone L = Thicknes of Soil (as determined above) K„y= 2.0 in/hr A = 3,213 sf H3 = 2 ft L3 = 2.7 ft unless L is small, such as 2.0 feet), allow H/L = 1 Q= 0.11 cfs Find time to drawdown water from inundation to saturation at surface: Biorelention Volume (V,.,) = SA x Depression Depth V,.r = 3,854 cf Time to remove V,.r of water at flowrate, Q T., = VF./Q T,., = 34812 seconds T,.I = 9.67 hours < 12 hours 2of3 Time to drawdown water from saturation at surface to X feet below surface: Porosity, n = 0.45 X = 2.0 ft Calculate volume of water to drawdown in 4 feet of soil: V1.2=X(ft)'SA"n V,.2 = 2892 cf Time to remove water from V,., Ta.z = V,.,/Q T12= 26120 seconds T,.2 = 7.26 hours Total time to draw water through soil: Time = T,.r + T12 Drawdown Time = 16.93 hours < 48 hours IV. Sizino Underdrain Pines and Gravel Envelo Q = 0.11 cfs Size drains so they are able to carry 10X the soil drawdown Q = 1.1 cfs Manning Roughness Coefficients: Pipe Type and Diameter Mannino Roughness Coefficient 4" Single Wall Corrugated Plastic 0.0145 4" Smooth Wall Plastic 0.0105 6" Single Wall Corrugated Plastic 0.0145 6" Smooth Wall Plastic 0.0105 8" Single Wall Corrugated Plastic 0.0155 N • D = 16' (Q•n/s"0.5)".375 n = 0.0105 s = 0.005 (internal slope - recommended 0.5%) N' D = 1.4 Inches ' 1.4 inches is less than 5.13 N= .5 nc es rs less than 5.13 inches, therefore, two 2 4" PVC pipe, or smoot wall lastic pipes are required. The gravel envelope surrounding the drainage pipe to be 8" deep at a minimum. Refer to Hyraflow calculations for primary and emergency overflow calculations. 3of3 I 1 Watershed Model Schem;"jgow Hydrographs Extension for AutoCAD®Civil 3D®2010 by Autodesk. Inc. v9.25 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Hydrograph Return Perio0yRA9yNgraphs Extension for AutoCAD@Civil 31302010 by Autodesk, Inc. v9.25 Hyd. Hydrograph Inflow Peak Outflow (cfs) Hydrograph No. type hyd(s) Description (origin) 1-yr 2-yr 3-yr 5-yr 10-yr 25-yr 50-yr 100-yr 1 SCS Runoff 3.834 6.375 17.33 22.72 32.48 Drainage Area 1-Post 2 SCS Runoff 0.827 1.375 -- 3.738 4.902 7,006 Drainage Area 2-Post 3 Reservoir 1 0.000 0.000 3.258 7.311 11.71 Bio Cell 1 Routing 4 Reservoir 2 0.000 0.000 0.996 2.247 5.438 Bio Cell 2 Route 5 SCS Runoff 0.000 0.000 0.133 1.021 4.744 Predevelopment DA 1 6 SCS Runoff 2.410 4.031 11.04 14.49 20.79 Predevelopment DA 2 7 SCS Runoff 0.000 0.001 0.074 0.546 2.026 Predevelopment DA 3 8 SCS Runoff 0.010 0.105 1.278 1.976 3.333 Predevelopment DA 4 9 SCS Runoff 0.000 0.001 0.059 0.287 0.903 Predevelopment DA 5 10 SCS Runoff 0.000 0.004 0.350 1.704 5.364 Predevelopment DA 6 Proj. file: BMP Flood Routings -Revised 3-21-11.gpw Tuesday, Apr 19, 2011 I ■ Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3D0 2010 by Autodesk, Inc. v9.25 tHyd. No. 1 Drainage Area 1-Post F Tuesday, Apr 19, 2011 type = SCS Runoff Peak discharge = 3.834 cfs 'Hydrograph Storm frequency = 1 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 14,136 cuft Drainage area = 5.470 ac Curve number = 63' ' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min precip. = 3.70 in Distribution = Type III 'Total Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) _ [(2.270 x 98) + (3.200 x 39)] / 5.470 ' Drainage Area 1-Pos1 Q (cfs) Hyd. No. 1 -- 1 Year 4.00 3.00 ' 2.00 ' 1.00 0.00 0 2 4 6 8 10 12 14 16 ' — Hyd No. 1 1 Q (Cfs) 4.00 3.00 2.00 Ewell] 'I g 0.00 18 20 22 24 26 Time (hrs) Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Hyd. No. 2 Drainage Area 2-Post 4 Tuesday, Apr 19, 2011 Hydrograph type = SCS Runoff Peak discharge = 0.827 cfs Storm frequency = 1 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 3,049 cuft Drainage area = 1.180 ac Curve number = 63" Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 3.70 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.480 x 98) + (0.700 x 39)] / 1.180 (cfs) Drainage Area 2-Post Hyd. No. 2 -- 1 Year 1.00 oil 0.60 0.50 0.40 0.30 111K 7 0.10 0.00 ' ' 0 2 4 — Hyd No. 2 Q (cfs) 1.00 KOV141 0.80 0.70 0.60 [1bY1l 0.40 0.30 0.20 Tj 0.10 0.00 6 8 10 12 14 16 18 20 22 24 26 Time (hrs) 5 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAI& Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 3 Bio Cell 1 Routing Hydrograph type = Reservoir Peak discharge = 0.000 cfs Storm frequency = 1 yrs Time to peak = 12.27 hrs Time interval = 2 min Hyd. volume = 0 cult Inflow hyd. No. = 1 - Drainage Area 1-Post Max. Elevation = 26.37 ft Reservoir name = Bioretention Cell 1 Max. Storage = 6,230 cuft Storage Indication method used. Exfltration extracted from Outflow. Q (cfs) 4.00 . 3.00 2.00 1.00 0.00 0 2 4 Hyd No. 3 Bio Cell 1 Routing Hyd. No. 3 -- 1 Year 6 8 10 12 14 16 18 20 22 24 Hyd No. 1 ® Total storage used = 6,230 cuft Q (cfs) 4.00 3.00 2.00 1.00 _L__ 0.00 26 Time (hrs) Pond Report s Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Pond No. 2 - Bioretention Cell 1 Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 26.00 it Stage / Storage Table Stage (ft) Elevation (ft) Contour area (sqft) Incr. Storage (cult) Total storage (cuft) 0.00 26.00 14,920 0 0 1.00 27.00 19,213 17,020 17,020 2.00 28.00 24,223 21,668 38,687 3.00 29.00 29,379 26,757 65.444 Culvert / Orifice Structures Weir Structures [A] [B] [C] [PrfRsr] [A] [B] [C] [D] Rise (in) = 15.00 0.00 0.00 0.00 Crest Len (ft) = 12.00 15.00 0.00 0.00 Span (in) = 15.00 0.00 0.00 0.00 Crest El. (ft) = 27.00 28.00 0.00 0.00 No. Barrels = 10 0 0 0 Weir Coeff. = 3.330.00 3.33 3.33 3.33 Invert El. (ft) = 23.00 0.00 0.00 0.00 Weir Type = 1 Ciplti - - Length (ft) = 38.00 0.00 0.00 0.00 Multi -Stage = Yes No No No Slope (%) = 0.50 0.00 0.00 n/a N-Value = .013 .013 .013 n/a Orifice Coeff. = 0.60 0.60 0.60 0.60 Exfil.(in/hr) = 20 (by Contour) Multi -Stage = Na No No No TW Elev. (ft) = 0.00 Stage (ft) 3.00 2.00 1.00 0.00 ' 0.00 6.00 - Total Q Note:CoN.WOririce outflows are analysed under inlet(ic) and wind(w) contra. Weir risers checked for onfoe conditions tc) and submergence(a) Stage / Discharge 12.00 18.00 24.00 30.00 36.00 42.00 48.00 54.00 60.00 Elev (ft) 29.00 28.00 27.00 -1 26.00 66.00 Discharge (cfs) I ■ Hydrograph Report . Hydraflow Hydrographs Extension for AutoCADO Civil 3D®2010 by Autodesk, Inc. v9.25 Hyd. No. 4 Bio Cell 2 Route Hydrograph type = Reservoir Peak discharge ' Storm frequency = 1 yrs Time to peak Time interval = 2 min Hyd. volume Inflow hyd. No. = 2 - Drainage Area 2-Post Max. Elevation ' Reservoir name = Bioretention Cell 2 Max. Storage Storage Indication method used. Exfiltration extracted from Outflow. t Q (cfs) ' 1.00 0.80 0.70 T ' 0.60 ' 0.50 0.40 0.30 ' 0.20 0.10 Bio Cell 2 Route Hyd. No. 4 -- 1 Year Tuesday, Apr 19, 2011 = 0.000 cfs = 14.67 hrs = 0 cult = 28.34 ft = 1,322 cuft 8 12 16 20 24 28 32 36 40 — Hyd No. 2 ® Total storage used = 1,322 cuft Q (cfs) 1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 44 Time (hrs) Pond Report 8 Hydraflow Hydrographs Extension for Al Civil 3D0 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Pond No. 3 - Bioretention Cell 2 Pond Data Contours -User-defined contour areas. Conic method used for volume calculation. Begining Elevation = 28.00 It Stage / Storage Table Stage (ft) Elevation (ft) Contour area (si Incr. Storage (cuft) Total storage (cult) 0.00 28.00 3,213 0 0 1.00 29.00 4,564 3,868 3,868 2.00 30.00 5,947 5,240 9,108 Culvert / Orifice Structures Weir Structures [A] [B] [C] [PrfRsr] [A] [B] [C] [D] Rise (in) = 15.00 0.00 0.00 0.00 Crest Len (ft) = 12.00 10.00 0.00 0.00 Span (in) = 15.00 0.00 0.00 0.00 Crest El. (ft) = 29.00 29.75 0.00 0.00 No. Barrels = 10 0 0 0 Weir Coeff. = 3.330.00 3.33 3.33 3.33 Invert El. (ft) = 25.00 0.00 0.00 0.00 Weir Type = 1 Ciplti - - Length(ft) = 14.25 0.00 0.00 0.00 Multi -Stage = Yes No No No Slope (%) = 3.50 0.00 0.00 n/a N-Value = .013 .013 .013 n/a Orifice Coeff. = 0.60 0.60 0.60 0.60 Exfil.(in/hr) = 20 (by Contour) Multi -Stage = n/a No No No TIN Elev. (ft) = 0.00 Stage (ft) 2.00 1.80 1.60 1.40 1.20 1.00 0.80 0.60 0.40 0.20 0.00 0.00 2.00 Total O Note:CulvertiCnfice au0taas are analyzed under inlet (id) and outlet(m) control. Weir risers checked for onfice coniitions(ic) and submergence(s). Stage / Discharge 4.00 6.00 8.00 10.00 12.00 14.00 16.00 Elev (ft) 30.00 29.80 29,60 29.40 29.20 29.00 28.80 28.60 28.40 28.20 � 28.00 18.00 Discharge it 1 9 i Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 31302010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 ' Hyd. No. 5 Predevelopment DA 1 'Hydrograph type = SCS Runoff Peak discharge = 0.000 cfs Storm frequency = 1 yrs Time to peak = n/a Time interval = 2 min Hyd. volume = 0 Cuft Drainage area = 3.790 ac Curve number = 31' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min 'Total precip. = 3.70 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) _ [(0.060 x 98) + (3.730 x 30)1 / 3.790 Predevelopment DA 1 Q (Cfs) Hyd. No. 5 -- 1 Year 0.10 0.09 ' 0.08 0.07 ' 0.06 0.05 ' 0.04 0.03 0.02 0.01 000 Q (Cfs) 0.10 0.09 0.08 0.07 0.06 KIIIII 0.04 0.03 [0x0➢a 0.01 0.00 0.0 0.3 0.7 1.0 1.3 1.7 2.0 Time (hrs) Hyd No. 5 10 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 6 Predevelopment DA 2 Hydrograph type = SCS Runoff Peak discharge = 2.410 cfs Storm frequency = 1 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 5,401 cult Drainage area = 2.560 ac Curve number = 60' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conic. (Tc) = 5.00 min Total precip. = 3.70 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.920 x 98) + (1.640 x 39)] 12.560 Q (cfs) 3.00 2.00 1.00 0.00 ' 0 2 4 — Hyd No. 6 Predevelopment DA 2 Hyd. No. 6 -- 1 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 3.00 2.00 1.00 -L-- 0.00 26 Time (hrs) 11 Hydrograph Report Hydratlow Hydrographs Extension for AutoCAD@ Civil 3DO 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 7 Predevelopment DA 3 type = SCS Runoff Peak discharge = 0.000 cfs 'Hydrograph Storm frequency = 1 yrs Time to peak = n/a Time interval = 2 min Hyd. volume = 0 cult Drainage area = 1.340 ac Curve number = 32" ' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min precip. = 3.70 in Distribution = Type II 'Total Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = [(0.049 x 98) + (1.293 x 30)] / 1.340 ' Predevelopment DA 3 Q (cfs) Hyd. No. 7 -- 1 Year ' 0.10 0.09 0.08 t 0.07 1 0.06 0.05 0,04 0.03 0.02 0.01 0.00 0.0 0.3 0.7 - Hyd No. 7 1.0 1.3 Q (cfs) 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 1.7 2.0 Time (hrs) 12 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAM) Civil M 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 8 Predevelopment DA 4 Hydrograph type = SCS Runoff Peak discharge = 0.010 cfs Storm frequency = 1 yrs Time to peak = 12.43 hrs Time interval = 2 min Hyd. volume = 279 cuft Drainage area = 0.700 ac Curve number = 45' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 3.70 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 *Composite (Area/CN) = [(0.158 x 98) + (0.541 x 30)] / 0.700 Q (cfs) 0.10 0.09 0.08 0.07 0.05 0.04 0.03 0.02 0.01 000 0 2 4 Hyd No. 8 Predevelopment DA 4 Hyd. No. 8 -- 1 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 0.10 Gxr1;', 0.08 0.07 0.06 [1111um 0.04 0.03 0.02 [11M 1 0.00 26 Time (hrs) ' 13 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 9 Predevelopment DA 5 'Hydrograph type = SCS Runoff Peak discharge = 0.000 cfs Storm frequency = 1 yrs Time to peak = n/a Time interval = 2 min Hyd. volume = 0 Cuft ' Drainage area = 0.510 ac Curve number = 33' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 3.70 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = I(0.024 x 98) + (0.486 x 30)] / 0.510 Predevelopment DA 5 Q (cfs) 1 Hyd. No. 9 -- 1 Year 0.10 0.09 0.08 _ 0.07 ' 0.06 t 0.05 0.04 0.03 0.02 0.01 ' 0.00 0.0 0.3 0.7 1.0 - Hyd No. 9 1.3 Q (Cfs) 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 1.7 2.0 Time (hrs) 14 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADOO Civil 3D® 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 10 Predevelopment DA 6 Hydrograph type = SCS Runoff Peak discharge = 0.000 Cfs Storm frequency = 1 yrs Time to peak = n/a Time interval = 2 min Hyd. volume = 0 cult Drainage area = 3.030 ac Curve number = 33' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 3.70 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = [(0.117 x 98) + (2.918 x 30)] / 3.030 Q (Cfs) 0.10 0.08 0.07 0.06 0.05 0.04 0.03 0.02 [a[1yM 0.00 0.0 0.3 — Hyd No. 10 Predevelopment DA 6 Hyd. No. 10 — 1 Year 0.7 1.0 1.3 1.7 Q (cfs) 0.10 0.09 0.08 0.07 0.06 0.05 [Q1L! 0.03 0.02 0.01 —4- 0.00 2.0 Time (hrs) 15 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3D®2010 by Autodesk, Inc. v9.25 ' Hyd. No. 1 Drainage Area 1-Post Tuesday, Apr 19, 2011 'Hydrograph type = SCS Runoff Peak discharge = 6.375 cfs Storm frequency = 2 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 21,285 cuft ' Drainage area = 5.470 ac Curve number = 63* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min 'Total precip. = 4.40 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 1 ' Composite (Area/CN) = [(2.270 x 98) + (3.200 x 39)] / 5.470 ' Drainage Area 1-Post Q (cfs) - ^^ Hyd. No. 1 -- 2 Year -V 0 2 4 6 8 10 — Hyd No. 1 12 14 16 18 20 22 24 Q (cfs) 7.00 6X1li] Exile] 3.00 2.00 —1 0.00 26 Time (hrs) 16 Hydrograph Report Hydraflow Hydrographs Extension for AutoCACO Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 2 Drainage Area 2-Post Hydrograph type = SCS Runoff Peak discharge = 1.375 cfs Storm frequency = 2 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 4,592 cuft Drainage area = 1.180 ac Curve number = 63' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = i(0.480 x 98) + (0.700 x 39)1/ 1.180 Q (cfs) 2.00 1.00 0.00 ' 0 2 4 — Hyd No. 2 Drainage Area 2-Post Hyd. No. 2 -- 2 Year 6 8 10 12 14 16 18 20 22 24 Q (Cfs) 2.00 1.00 --1- 0.00 26 Time (hrs) I Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3DOO 2010 by Autodesk, Inc. v9.25 Hyd. No. 3 Bio Cell 1 Routing ' Hydrograph type = Reservoir Peak discharge Storm frequency = 2 yrs Time to peak Time interval = 2 min Hyd. volume ' Inflow hyd. No. = 1 - Drainage Area 1-Post Max. Elevation Reservoir name = Bioretention Cell 1 Max. Storage ' Storage Indication method used. Exfltration extracted from Outflow. Q (Cfs) 7.00 1 6.00 ' 5.00 4.00 3.00 2.00 ' 1.00 ' 000 0 2 4 ' — Hyd No. 3 Bio Cell 1 Routing Hyd. No. 3 -- 2 Year 6 8 10 — Hyd No. 1 12 lib Tuesday, Apr 19, 2011 = 0.000 cfs = 25.47 hrs = 0 cult = 26.57 ft = 9,700 cult Q (cfs) 7.00 5.00 4.00 11101111111 Walls] wa,IQ 0.00 14 16 18 20 22 24 26 28 Time (hrs) ® Total storage used = 9,700 tuft 18 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3D©2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 4 Bio Cell 2 Route Hydrograph type = Reservoir Peak discharge = 0.000 cfs Storm frequency = 2 yrs Time to peak = 18.63 hrs Time interval = 2 min Hyd. volume = 0 cult Inflow hyd. No. = 2 - Drainage Area 2-Post Max. Elevation = 28.53 ft Reservoir name = Bioretention Cell 2 Max. Storage = 2,062 cuft Storage Indication method used. EWtration extracted from Outflow. Q (cfs) 2.00 1.00 0.00 ' 0 4 — Hyd No. 4 Bio Cell 2 Route Hyd. No. 4 -- 2 Year 8 12 16 20 24 28 32 36 40 — Hyd No. 2 ® Total storage used = 2,062 cult Q (cfs) 2.00 1.00 --W- 0.00 44 Time (hrs) ' 19 ' Hydrograph Report Hydraflow Hydro9raphs Extension for AutoCADO Civil 3D® 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 ' Hyd. No. 5 Predevelopment DA 1 Hydrograph type = SCS Runoff Peak discharge = 0.000 cfs Storm frequency = 2 yrs Time to peak = n/a Time interval = 2 min Hyd. volume = 0 Cuft ' Drainage area = 3.790 ac Curve number = 31' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) _ [(0.060 x 98) + (3.730 x 30)113.790 ePredevelopment DA 1 Q (cfs) Hyd. No. 5 -- 2 Year 0.10 0.09 0.08 - 0.07 ' 0.06 0.05 0.04 ' 0.03 0.02 0.01 L 0.00 0.0 0.3 0.7 1.0 - Hyd No. 5 1.3 Q (cfs) 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 1.7 2.0 Time (hrs) 20 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 313®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19. 2011 Hyd. No. 6 Predevelopment DA 2 Hydrograph type = SCS Runoff Peak discharge = 4.031 cfs Storm frequency = 2 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 8,417 cuft Drainage area = 2.560 ac Curve number = 60* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.920 x 98) + (1.640 x 39)1 / 2.560 Q (Cfs) 5.00 4.00 101111111 2.00 1.00 0.00 ' 0 2 4 — Hyd No. 6 6 8 Predevelopment DA 2 Hyd. No. 6 -- 2 Year Q (cfs) 5.00 4.00 3.00 2.00 1.00 ' I ' ' ' ' 0.00 10 12 14 16 18 20 22 24 26 Time (hrs) 21 ' Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D® 2010 by Autodesk, Inc. v9.25 Hyd. No. 7 Predevelopment DA 3 Tuesday, Apr 19, 2011 'Hydrograph type = SCS Runoff Peak discharge = 0.001 cfs Storm frequency = 2 yrs Time to peak = 24.00 hrs Time interval = 2 min Hyd. volume = 5 Cuft Drainage area = 1.340 ac Curve number = 32' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 " Composite (Area/CN) _ ((0.049 x 98) + (1.293 x 30)111.340 Predevelopment DA 3 Q (cfs) Hyd. No. 7 -- 2 Year f 0.10 0.09 ' 0,08 - 0.07 0.06 0.05 ' 0.04 ' 0.03 0.02 0.01 t 0.00 0 2 4 6 8 10 12 14 16 — Hyd No. 7 18 20 22 24 Q (Cfs) 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 26 Time (hrs) 22 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 8 Predevelopment DA 4 Hydrograph type = SCS Runoff Peak discharge = 0.105 cfs Storm frequency = 2 yrs Time to peak = 12.00 hrs Time interval = 2 min Hyd. volume = 642 cuft . Drainage area = 0.700 ac Curve number = 45* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 *Composite (Area/CN) = [(0.158 x 98) + (0.541 x30)]10.700 Q (cfs) 0.50 ux0.y 0.40 0.35 0.30 111K 1 0.20 0.15 0.10 0.05 000 0 2 4 — Hyd No. 8 Predevelopment DA 4 Hyd. No. 8 -- 2 Year 6 8 10 12 14 Q (cfs) 0.50 0.45 DM1tf: 0.35 0.30 0.25 0.20 0.15 0.10 0.05 I I 1 R 0.00 16 18 20 22 24 26 Time (hrs) I Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 31302010 by Autodesk, Inc. v9.25 Hyd. No. 9 Predevelopment DA 5 23 Tuesday, Apr 19, 2011 1 Hydrograph type = SCS Runoff Peak discharge = 0.001 cfs Storm frequency = 2 yrs Time to peak = 24.00 hrs Time interval = 2 min Hyd. volume = 10 Cuft Drainage area = 0.510 ac Curve number = 33' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ` Composite (Area/CN) _ [(0.024 x 98) + (0.486 x 30)] / 0.510 Predevelopment DA 5 Q (Cfs) ' Hyd. No. 9 -- 2 Year 0.10 0.09 0,08 0.07 0.06 r 0.05 0.04 0.03 0.02 0.01 0.00 0 2 4 6 8 10 12 14 16 ' — Hyd No. 9 Q (Cfs) 0.10 0.09 0.08 0.07 0.06 91111111 0.04 0.03 0.02 0.01 0.00 18 20 22 24 26 Time (hrs) 24 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 10 Predevelopment DA 6 Hydrograph type = SCS Runoff Peak discharge = 0.004 cfs Storm frequency = 2 yrs Time to peak = 24.00 hrs Time interval = 2 min Hyd. volume = 58 cuft Drainage area = 3.030 ac Curve number = 33' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 4.40 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.117 x 98) t (2.918 x 30)] / 3.030 Q (cfs) 0.10 0.09 0.08 0.07 [1IQy 0.05 0.04 0.03 0,01 000 0 2 4 — Hyd No. 10 Predevelopment DA 6 Hyd. No. 10 -- 2 Year 6 8 10 12 14 Q (cfs) 0.10 0.09 [1xIR1 94111A 0.06 0.05 0.04 E411161 0.02 0.01 0.00 16 18 20 22 24 26 Time (hrs) 25 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADOO Civil 3D®2010 by Autodesk, Inc. v9.25 Hyd. No. 1 Drainage Area 1-Post Hydrograph type = SCS Runoff Storm frequency = 10 yrs Time interval = 2 min Drainage area = 5.470 ac Basin Slope = 0.0 % Tc method = User Total precip. = 6.90 in Storm duration = 24 hrs I- Composite (Area/CN) = [(2.270 x 98) + (3.200 x 39)] / 5.470 i Q (cfs) 18.00 15.00 12.00 9.00 ' 6.00 3,00 - ' 000 - Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Drainage Area 1-Post Hyd. No. 1 -- 10 Year Tuesday, Apr 19, 2011 = 17.33 cfs = 12.07 hrs = 52,611 cuft = 63* = Oft = 5.00 min = Type III = 484 0 2 4 6 8 10 12 14 16 18 20 22 24 ' — Hyd No. 1 Q (cfs) 18.00 15.00 12.00 WilI$] 1 0.00 26 Time (hrs) 26 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 31)@ 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 2 Drainage Area 2-Post Hydrograph type = SCS Runoff Peak discharge = 3.738 cfs Storm frequency = 10 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 11,349 cuft Drainage area = 1.180 ac Curve number = 63* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.480 x 98) + (0.700 x 39)] / 1.180 Q (cfs) 4.00 3.00 2.00 1.00 0.00 0 2 4 Hyd No. 2 Drainage Area 2-Post Hyd. No. 2 -- 10 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 4.00 3.00 PA1Z41 1.00 —1 0.00 26 Time (hrs) r r Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3D® 2010 by Autodesk, Inc. v9.25 Hyd. No. 3 Bio Cell 1 Routing Hydrograph type = Reservoir Peak discharge Storm frequency = 10 yrs Time to peak Time interval = 2 min Hyd. volume r Inflow hyd. No. = 1 - Drainage Area 1-Post Max. Elevation Reservoir name = Bioretention Cell 1 Max. Storage Storage Indication method used. Exfiltration extracted from Outflow. r Q (cfs) 18.00 r 15.00 r r 12,00 ' 9.00 ' 6.00 - r 3.00 - 000 0.0 2.0 r— Hyd No. 3 r Bio Cell 1 Routing Hyd. No. 3 -- 10 Year 27 Tuesday, Apr 19, 2011 = 3.258 cfs = 12.47 hrs = 11,659 cuft = 27.19 ft = 21,056 cuft 4.0 6.0 8.0 10.0 12.0 14.0 — Hyd No. 1 ® Total storage used = 21,056 cult Q (cfs) 18.00 15.00 12.00 1141111 3.00 — 0.00 16.0 Time (hrs) 28 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 313®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 4 Bio Cell 2 Route Hydrograph type = Reservoir Peak discharge = 0.996 cfs Storm frequency = 10 yrs Time to peak = 12.40 hrs Time interval = 2 min Hyd. volume = 2,164 cuft Inflow hyd. No. = 2 - Drainage Area 2-Post Max. Elevation = 29.08 ft Reservoir name = Bioretention Cell 2 Max. Storage = 4,281 cuft Storage Indication method used. ExFltration extracted from Outflow. Q (cfs) 4.00 3.00 PAIII1I 1.00 0.00 0.0 2.0 — Hyd No. 4 Bio Cell 2 Route Hyd. No. 4 -- 10 Year 4.0 6.0 — Hyd No. 2 8.0 10.0 12.0 14.0 ® Total storage used = 4,281 cuft Q (cfs) 4.00 BZ1Z11 2.00 1.00 -..L- 0.00 16.0 Time (hrs) Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D0 2010 by Autodesk, Inc. v9.25 Hyd. No. 5 Predevelopment DA 1 29 Tuesday, Apr 19, 2011 1 Hydrograph type = SCS Runoff Peak discharge = 0.133 cfs Storm frequency = 10 yrs Time to peak = 12.37 hrs Time interval = 2 min Hyd. volume = 3,129 cuft Drainage area = 3.790 ac Curve number = 31* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = [(0.060 x 98) + (3.730 x 30)i / 3.790 Predevelopment DA 1 Q (cfs) Hyd. No. 5 -- 10 Year 0.50 0.45 ' 0.40 0.35 ' 0.30 ' 0.25 0.20 0.15 0.10 0.05 0.00 0 2 4 6 8 10 — Hyd No. 5 12 14 16 18 20 22 24 Q (cfs) 0.50 0.45 0.40 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0.00 26 Time (hrs) 30 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3DO 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 6 Predevelopment DA 2 Hydrograph type = SCS Runoff Peak discharge = 11.04 cfs Storm frequency = 10 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 22,068 cuft Drainage area = 2.560 ac Curve number = 60* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = 1(0.920 x 98) + (1.640 x 39)1/ 2.560 Q (cis) 12.00 - 10.00 M Mll 4.00 2.00 0.00 0 2 4 — Hyd No. 6 Predevelopment DA 2 Hyd. No. 6 -- 10 Year 6 8 10 12 14 16 18 Q (cfs) 12.00 10.00 M M PalA; ' 0.00 20 22 24 26 Time (hrs) 1 31 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 7 Predevelopment DA 3 Hydrograph type = SCS Runoff Peak discharge = 0.074 cfs Storm frequency = 10 yrs Time to peak = 12.03 hrs Time interval = 2 min Hyd. volume = 1,340 cuft Drainage area = 1.340 ac Curve number = 32* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = I(0.049 x 98) + (1293 x 30)J / 1.340 Predevelopment DA 3 Q (cfs) Hyd. No. 7 — 10 Year 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 0 2 4 6 8 10 12 14 16 1 — Hyd No. 7 w 18 20 22 24 Q (cfs) 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 26 Time (hrs) 32 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD@ Civil 305 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 8 Predevelopment DA 4 Hydrograph type = SCS Runoff Peak discharge = 1.278 cfs Storm frequency = 10 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 2,836 cuft Drainage area = 0.700 ac Curve number = 45* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.158 x 98) + (0.541 x 30)] / 0.700 Q (cfs) 2.00 1.00 0.00 0 2 4 — Hyd No. 8 Predevelopment DA 4 Hyd. No. 8 — 10 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 2.00 1.00 —1 0.00 26 Time (hrs) 33 ' Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 9 Predevelopment DA 5 ' Hydrograph type = SCS Runoff Peak discharge = 0.059 cfs Storm frequency = 10 yrs Time to peak = 12.03 hrs Time interval = 2 min Hyd. volume = 603 cuft Drainage area = 0.510 ac Curve number = 33" Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) _ 1(0.024 x 98) + (0.486 x 30)1 / 0.510 ' Predevelopment DA 5 Q (cfs) Hyd. No. 9 -- 10 Year 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 I 0.00 0 2 4 6 8 10 — Hyd No. 9 12 14 16 18 20 22 24 Q (cfs) 0.10 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.01 0.00 26 Time (hrs) 34 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D0 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 10 Predevelopment DA 6 Hydrograph type = SCS Runoff Peak discharge = 0.350 cfs Storm frequency = 10 yrs Time to peak = 12.03 hrs Time interval = 2 min Hyd. volume = 3,582 cuft Drainage area = 3.030 ac Curve number = 33' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 6.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.117 x 98) + (2.918 x 30)] / 3.030 Q (Cfs) 0.50 0.45 0.40 0.35 0.30 0.25 0.20 0.15 - 0.10 - 0.05 000 Predevelopment DA 6 Hyd. No. 10 -- 10 Year Q (Cfs) 0.50 0.45 0.40 0.35 0.30 0.25 0.20 0.10 0.05 000 0 2 4 6 8 10 12 14 16 18 20 22 24 26 — Hyd No. 10 Time (hrs) KV r Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 ■ Hyd. No. 1 ■ Drainage Area 1-Post Tuesday, Apr 19, 2011 Hydrograph type = SCS Runoff Peak discharge = 22.72 cfs Storm frequency = 25 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 68,292 cuft Drainage area = 5.470 ac Curve number = 63' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min 1 Total precip. = 8.00 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 ' - Composite (Area/CN) = [(2.270 x 98) + (3.200 x 39)]15.470 1 Q (cfs) ' 24.00 20.00 ' 16.00 12.00 8.00 - 4,00 - 000 - 0 2 4 ' — Hyd No. 1 1 Drainage Area 1-Post Hyd. No. 1 -- 25 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 24.00 swz1a1za `M- 1110 12.00 4.00 —1 0.00 26 Time (hrs) 36 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 31302010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 2 Drainage Area 2-Post Hydrograph type = SCS Runoff Peak discharge = 4.902 cfs Storm frequency = 25 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 14,732 cuft Drainage area = 1.180 ac Curve number = 63* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.480 x 98) + (0.700 x 39)] / 1.180 Q (Cfs) 5.00 4.00 3.00 2.00 1.00 0.00 ' 0 2 4 — Hyd No. 2 Drainage Area 2-Post Hyd. No. 2 — 25 Year 6 8 10 12 14 16 18 20 22 24 Q (Cfs) 5.00 4.00 3.00 2.00 here] 1 0.00 26 Time (hrs) 37 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Hyd. No. 3 Bio Cell 1 Routing Hydrograph type = Reservoir Peak discharge Storm frequency = 25 yrs Time to peak Time interval = 2 min Hyd. volume 1 Inflow hyd. No. = 1 - Drainage Area 1-Post Max. Elevation Reservoir name = Bioretention Cell 1 Max. Storage Storage Indication method used. ExFltration extracted from Outflow. i 1 Q (cfs) Bio Cell 1 Routing Hyd. No. 3 -- 25 Year Tuesday, Apr 19, 2011 = 7.311 cfs = 12.33 hrs = 23,878 cuft = 27.32 ft = 23,975 cuft f - 0.0 2.0 4.0 6.0 8.0 10.0 12.0 14.0 16.0 ' — Hyd No. 3 — Hyd No. 1 ® Total storage used = 23,975 cuft Q (cfs) 24.00 20.00 16.00 12.00 [:110b1 [K461 —I 0.00 18.0 Time (hrs) Hydrograph Report 38 Hydraflow Hydrographs Extension for AutoCAD@ Civil 3D0 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 4 Bio Cell 2 Route Hydrograph type = Reservoir Peak discharge = 2.247 cfs Storm frequency = 25 yrs Time to peak = 12.20 hrs Time interval = 2 min Hyd. volume = 4,766 cuft Inflow hyd. No. = 2 - Drainage Area 2-Post Max. Elevation = 29.14 ft Reservoir name = Bioretention Cell 2 Max. Storage = 4,615 cuft Storage Indication method used. Exfiltration extracted from Outflow Q (cfs) 5.00 4.00 3.00 2.00 1.00 0.00 ' 0.0 2.0 — Hyd No. 4 Bio Cell 2 Route Hyd. No. 4 -- 25 Year 4.0 6.0 — Hyd No. 2 8.0 10.0 12.0 14.0 ff7TF17] Total storage used = 4,615 cuff Q (cfs) 5.00 4.00 3.00 2.00 MKOV, ---1- 0.00 16.0 Time (hrs) 39 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 5 Predevelopment DA 1 Hydrograph type = SCS Runoff Peak discharge = 1.021 cfs Storm frequency = 25 yrs Time to peak = 12.00 hrs Time interval = 2 min Hyd. volume = 6,288 cuft Drainage area = 3.790 ac Curve number = 31* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = ](0.060 x 98) + (3,730 x 30)] / 3.790 Q (Cfs) 2.00 - 1.00 0.00 ' 0 2 4 Hyd No. 5 Predevelopment DA 1 Hyd. No. 5 -- 25 Year 6 8 10 12 14 16 18 20 22 24 Q (Cfs) 2.00 1.00 1 0.00 26 Time (hrs) 40 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 6 Predevelopment DA 2 Hydrograph type = SCS Runoff Peak discharge = 14.49 cfs Storm frequency = 25 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 29,040 cuft Drainage area = 2.560 ac Curve number = 60' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.920 x 98) + (1.640 x 39)] / 2.560 Q (Cfs) 15.00 W1111 a im AM] KM 0.00 ' 0 2 4 — Hyd No. 6 Predevelopment DA 2 Hyd. No. 6 -- 25 Year 6 8 10 12 14 16 18 Q (cfs) 15.00 12.00 M 3.00 0.00 20 22 24 26 Time (hrs) i Hydrograph Report Hydraflow Hydrogral Extension for AutoCAD® Civil 3130 2010 by Autodesk, Inc. v9.25 Hyd. No. 7 Predevelopment DA 3 41 Tuesday, Apr 19, 2011 'Hydrograph type = SCS Runoff Peak discharge = 0.546 cfs Storm frequency = 25 yrs Time to peak = 12.00 hrs Time interval = 2 min Hyd. volume = 2,561 cuft ' Drainage area = 1.340 ac Curve number = 32* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) _ [(0.049 x 98) + (1293 x 30)] 11.340 Predevelopment DA 3 Q (cfs) Hyd. No. 7 -- 25 Year 1.00 0.90 0.80 0.70 I 0.60 ' 0.50 0.40 0.30 0.20 ' 0.10 1 0.00 0 2 4 6 8 10 12 14 16 — Hyd No. 7 18 20 22 24 Q (Cfs) 1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 0.00 26 Time (hrs) 42 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 8 Predevelopment DA 4 Hydrograph type = SCS Runoff Peak discharge = 1.976 cfs Storm frequency = 25 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 4,136 cuft Drainage area = 0.700 ac Curve number = 45* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 * Composite (Area/CN) = [(0.158 x 98) + (0.541 x 30)110.700 Q (cfs) 2.00 1.00 0.00 ' 0 2 4 — Hyd No. 8 Predevelopment DA 4 Hyd. No. 8 -- 25 Year Q (cfs) 2.00 1.00 0.00 6 8 10 12 14 16 18 20 22 24 26 Time (hrs) 1 43 t Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 ' Hyd. No. 9 Predevelopment DA 5 Hydrograph type = SCS Runoff Peak discharge = 0.287 cfs Storm frequency = 25 yrs Time to peak = 12.00 hrs Time interval = 2 min Hyd. volume = 1,111 cult Drainage area = 0.510 ac Curve number = 33" Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) _ [(0.024 x 98) t (0.486 x 30)j / 0.510 ' Predevelopment DA 5 Q (cfs) Hyd. No. 9 — 25 Year 0.50 0.45 0.40 - 0.35 0.30 - ^ 0.25 0.20 0.15 0.10 0.05 0.00 0 2 4 6 8 10 12 14 16 ' — Hyd No. 9 1 18 20 22 24 Q (cfs) 0.50 0.45 0.40 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0.00 26 Time (hrs) Hydrograph Report 44 Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 10 Predevelopment DA 6 Hydrograph type = SCS Runoff Peak discharge = 1.704 cfs Storm frequency = 25 yrs Time to peak = 12.00 hrs Time interval = 2 min Hyd. volume = 6,599 cult Drainage area = 3.030 ac Curve number = 33" Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 8.00 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.117 x 98) + (2.918 x 30)] / 3.030 Q (Cfs) 2.00 Will Predevelopment DA 6 Hyd. No. 10 -- 25 Year Q (cfs) 2.00 1.00 0.00 0.00 0 2 4 6 8 10 12 14 16 18 20 22 24 26 — Hyd No. 10 Time (hrs) 45 ' Hydrograph Report HydraBow Hydrographs Extension for AutoCAD® Civil 3DOO 2010 by Autodesk, Inc. v9.25 ' Hyd. No. 1 Drainage Area 1-Post Hydrograph type = SCS Runoff Storm frequency = 100 yrs Time interval = 2 min Drainage area = 5.470 ac Basin Slope = 0.0 % Tc method = User Total precip. = 9.90 in Storm duration = 24 hrs Composite (Area/CN) = [(2.270 x 98) + (3.200 x 39)] / 5.470 i Q (cfs) 35-00 30.00 1 25.00 20.00 15,00 10-00 - 5.00 - 0.00 0 2 4 ' — Hyd No. 1 Peak discharge Time to peak Hyd. volume Curve number Hydraulic length Time of conc. (Tc) Distribution Shape factor Drainage Area 1-Post Hyd. No. 1 -- 100 Year Tuesday, Apr 19, 2011 = 32.48 cfs = 12.07 hrs = 97,080 cuft = 63' = Oft = 5.00 min = Type III = 484 6 8 10 12 14 16 18 20 22 24 Q (cfs) 35.00 30.00 25.00 20.00 15.00 10.00 moil] —1 0.00 26 Time (hrs) 46 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3D® 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 2 Drainage Area 2-Post Hydrograph type = SCS Runoff Peak discharge = 7.006 cfs Storm frequency = 100 yrs Time to peak = 12.07 hrs Time interval = 2 min Hyd. volume = 20,942 cuft Drainage area = 1.180 ac Curve number = 63' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 9.90 in Distribution = Type III Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.480 x 98) + (0.700 x 39)111.180 Q (cfs) 8.00 M 4.00 2.00 0.00 0 2 4 — Hyd No. 2 Drainage Area 2-Post Hyd. No. 2 -- 100 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 8.00 Kroll] 2.00 1 0.00 26 Time (hrs) 47 I Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3130 2010 by Autodesk, Inc. v9.25 Hyd. No. 3 Bio Cell 1 Routing Hydrograph type = Reservoir Peak discharge Storm frequency = 100 yrs Time to peak Time interval = 2 min Hyd. volume Inflow hyd. No. = 1 -Drainage Area 1-Post Max. Elevation Reservoir name = Bioretention Cell 1 Max. Storage Storage Indication method used. Exfiltration extracted from Outflow. Q (cfs) ' 35.00 30.00 25.00 20.00 15,00 10.00 5.00 Bio Cell 1 Routing Hyd. No. 3 -- 100 Year Tuesday, Apr 19, 2011 = 11.71 cfs = 12.30 hrs = 47,389 cuft = 27.65 ft = 31,206 cuft Q (cfs) 35.00 30.00 20.00 15.00 10.00 5.00 I of Hyd No. 3 4.0 6.0 8.0 10.0 12.0 14.0 16.0 Hyd No. 1 ® Total storage used = 31,206 cult 18.0 Time (hrs) 48 Hydrograph Report Hydrallow Hydrographs Extension for AutoCAD® Civil 3D8 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 4 Bio Cell 2 Route Hydrograph type = Reservoir Peak discharge = 5.438 cfs Storm frequency = 100 yrs Time to peak = 12.13 hrs Time interval = 2 min Hyd. volume = 9,786 cuft Inflow hyd. No. = 2 - Drainage Area 2-Post Max. Elevation = 29.27 ft Reservoir name = Bioretention Cell 2 Max. Storage = 5,243 cuft Storage Indication method used. Exfiltration extracted from Outflow Q (cfs) 8.00 . �� 4.00 0.00 0.0 2.0 — Hyd No. 4 Bio Cell 2 Route Hyd. No. 4 -- 100 Year 4.0 6.0 — Hyd No. 2 8.0 10.0 12.0 14.0 ® Total storage used = 5,243 cuft Q (cfs) 8.00 4.00 VZOU 0.00 16.0 Time (hrs) 49 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D@ 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 ' Hyd. No. 5 Predevelopment DA 1 Hydrograph type = SCS Runoff Peak discharge = 4.744 cfs Storm frequency = 100 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 13,798 cuft Drainage area = 3.790 ac Curve number = 31' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 9.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) _ [(0.060 x 98) + (3.730 x 30)1/ 3.790 Predevelopment DA 1 Q (cfs) Hyd. No. 5 -- 100 Year 5.00 4.00 3.00 2.00 1.00 0.00 0 2 4 6 8 10 12 14 16 — Hyd No. 5 18 20 Q (cfs) 5.00 4.00 3.00 2.00 1.00 " ' 0.00 22 24 26 Time (hrs) 50 Hydrograph Report Hydraflow Hydrographs Extension for AutoCADO Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 6 Predevelopment DA 2 Hydrograph type = SCS Runoff Peak discharge = 20.79 cfs Storm frequency = 100 yrs Time to peak = 11.93 hrs Time interval = 2 min Hyd. volume = 41,971 cuft Drainage area = 2.560 ac Curve number = 60* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 9.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.920 x 98) + (1.640 x 39)] / 2.560 Q (Cfs) 21.00 18.00 15.00 12.00 • M . M 3.00 0.00 0 2 4 Hyd No. 6 6 8 Predevelopment DA 2 Hyd. No. 6 -- 100 Year Q (cfs) 21.00 18.00 15.00 12.00 M M 3.00 1 1 1 1 1 0.00 10 12 14 16 18 20 22 24 26 Time (hrs) Hydrograph Report Hydraflow Hydrographs Extension for AutoCADOO Civil 3D@ 2010 by Autodesk, Inc. v9.25 Hyd. No. 7 Predevelopment DA 3 51 Tuesday, Apr 19, 2011 ' Hydrograph type = SCS Runoff Peak discharge = 2.026 cfs Storm frequency = 100 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 5,412 cuft Drainage area = 1.340 ac Curve number = 32* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min ' Total precip. = 9.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = [(0.049 x 98) + (1.293 x 30)] / 1.340 Predevelopment DA 3 Q (Cfs) Hyd. No. 7 -- 100 Year 3.00 ' 2.00 1.00 1 ' 0.00 0 2 4 — Hyd No. 7 6 8 10 12 14 16 18 20 22 24 Q (cfs) 3.00 2.00 1.00 —1- 0.00 26 Time (hrs) 52 Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 8 Predevelopment DA 4 Hydrograph type = SCS Runoff Peak discharge = 3.333 cfs Storm frequency = 100 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 6,729 cuft Drainage area = 0.700 ac Curve number = 45' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 9.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 Composite (Area/CN) = [(0.158 x 98) + (0,541 x 30)1 / 0.700 Q (cfs) 4.00 3.00 2.00 1.00 0.00 -1 0 2 4 Hyd No. 8 Predevelopment DA 4 Hyd. No. 8 -- 100 Year 6 8 10 12 14 16 18 20 22 24 Q (cfs) 4.00 3.00 I ta4 1.00 1 0.00 26 Time (hrs) 6710 ' Hydrograph Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3DO 2010 by Autodesk, Inc. v9.25 ' Hyd. No. 9 Predevelopment DA 5 Tuesday, Apr 19, 2011 ' Hydrograph type = SCS Runoff Peak discharge = 0.903 cfs Storm frequency = 100 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 2,263 cuft t Drainage area = 0.510 ac Curve number = 33* Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min ' Total precip. = 9.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 ' Composite (Area/CN) = [(0.024 x 98) + (0.486 x 30)] / 0.510 Predevelopment DA 5 ' Q (cfs) Hyd. No. 9 -- 100 Year V VV 0 2 4 6 8 10 12 14 16 — Hyd No. 9 Q (Cfs) 1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 ' 0.00 18 20 22 24 26 Time (hrs) 54 Hydrograph Report HydraFlow Hydrographs Extension for AutoCADO Civil 3D®2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Hyd. No. 10 Predevelopment DA 6 Hydrograph type = SCS Runoff Peak discharge = 5.364 cfs Storm frequency = 100 yrs Time to peak = 11.97 hrs Time interval = 2 min Hyd. volume = 13,444 cuft Drainage area = 3.030 ac Curve number = 33' Basin Slope = 0.0 % Hydraulic length = 0 ft Tc method = User Time of conc. (Tc) = 5.00 min Total precip. = 9.90 in Distribution = Type II Storm duration = 24 hrs Shape factor = 484 *Composite (Area/CN) = [(0.117 x 98) + (2.918 x 30)] / 3.030 Q (cfs) 6.00 - . 11 4.00 Km 2.00 1.00 Predevelopment DA 6 Hyd. No. 10 -- 100 Year Q (cfs) 6.00 5.00 4.00 3.00 2.00 1.00 0.00 0.00 0 2 4 6 8 10 12 14 16 18 20 22 24 26 — Hyd No. 10 Time (hrs) Hydraflow Rainfall Report Hydraflow Hydrographs Extension for AutoCAD® Civil 3DO 2010 by Autodesk, Inc. v9.25 Tuesday, Apr 19, 2011 Return Period Intensity -Duration -Frequency Equation Coefficients (FHA) (Yrs) B D E (N/A) 1 0.0000 0.0000 0.0000 - 2 0.0000 0.0000 0.0000 - 3 0.0000 0.0000 0.0000 - 5 0.0000 0.0000 0.0000 - 10 0.0000 0.0000 0.0000 - 25 0.0000 0.0000 0.0000 - 50 0.0000 0.0000 0.0000 - 100 0.0000 0.0000 0.0000 - ' File name: SampleFHA.idf Intensity = B / (Tc + D)AE Return Intensity Values (In/hr) Period (Yrs) 5 min 10 15 20 25 30 35 40 45 50 55 60 1 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 2 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 3 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 5 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 10 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 25 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 50 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 100 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ' Tc = time in minutes. Values may exceed 60. :\102\30032 Camlo Le'eune Pre -Trial Detainee Facili Calc\Stm\Onslow County De th-Duraton H dra0ow . c Storm Rainfall Precipitation Table (in) I Distribution 1-yr 2-yr Syr 5-yr 10-yr 25-yr 50-yr 100-yr SCS 24-hour 3.70 4.40 0.00 3.30 6.90 8.00 6.80 9.90 SCS 6-Hr 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Huff-tsl 0.00 0.00 0.00 2.75 0.00 0,00 6.50 0.00 Huff-2nd 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Huff-3rd 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Huff-4th 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Huff-Indy 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Custom 0.00 0.00 0.00 2.80 0.00 0.00 6.00 0.00 ' Riser Structure Anti -Floatation Calculations Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ C.A ........................................... PROJECT: .................... ......... . PROJECT NO.: DATE: ........................................... PARTICIPANTS: NOTES BY: Au-1=LoCt'RT eJ ei, ,.0 ''ri UNS RT c�6-C "IC LITa�j $raS�1�1 �IASti 'T "�P EL. ' 27• o0 TaY rf V%bvak" Z2. ocz t70—YAQL`e �ia2ct'. V. = l�X`'�� Z� - izi + h� 1�l ,i = hcF cF 5 = 4. -j,a= (1'7U 6P)( caz.4 �b/ct) t IJh, (�ks (fit 4ISo) _ 114, 100 .jbc �Ji.c iZ �t vt ga'�;D- l.Z InIPoS'1 •�•o®®Q p • Q u TIMMONS GROUP ui o YOUR VISION ACHIEVED THROUGH OURS. C 5410 Trinity Road TEL 919.866.4951 Suite 112 Fn 919.859.5663 Raleigh, NC 27607 A-sSI~we ul i r 7i 150 (L It 3 Meethig Plemop-ahiduria U DESIGN D PHONE D C.A. ....... .1 ............. ......... I ...... PROJECT: ........................ I....... PROJECT NO.: DATE ....................................... ... PARTICIPANTS .......... I ................ ......... . . . . . . . . . . 6 . . . . . . . . . . . . . . . . . . BY NOTES Q/t,genr_jn ay.3 fKC46- -rvr t vas -'a Vewvr 4 �' j -cimmotNIS (3noup 5410 Trinity Road I TEL 9 19.866.495 1 Suite 112 Fn 919.859.5603 Raleigh, NC 27607 i Meeting Memorandtim d DESIGN ❑ PHONE O C.A. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: .......................... I................... .................. I.......................... NOTES BY: '-DR>iNtbG RRE1�= '-i?0LS SF oM1 f.f0 /�c. .xµ-cv�ow+ �1�'•in� h7o7.1SF- oF' o.y3� A[., -j-0. �1Nrp�A �v.1 Z'E IJB\T �. -A.Sy,wMl rj µrt T 7. Zoo `'3"7�;_ �jw'i vrJIN� Dio' �p,mo� �.to'N�IiF-i�\J'pOhtl v '�.95 c� Q iou o.eaolLl�'i ��I{{R- 1 �, 1.1 b (col=-(p_3re c%$. ti TIMMONS GROUP .. .. E 5410 Trinity Road TEL 919.866.4951 Suite 112 rnx 919.859.5663 Raleigh, NC 27607 1. O Worksheet for Swale 1-10 Year. Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 Channel Slope 0.01100 ft/ft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 4.75 WIs Results Normal Depth 0.77 if Flow Area 1.79 ft' Wetted Perimeter 4.88 it Hydraulic Radius 0.37 ft Top Width 4.63 It Critical Depth 0.69 it Critical Slope 0.02006 ft/ft Velocity 2.66 ftis Velocity Head 0.11 it Specific Energy 0.88 it Froude Number 0.75 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 It Profile Description Profile Headloss 0.00 If Downstream Velocity Infinity f /S Upstream Velocity Infinity ft/s Normal Depth 0.77 ft Critical Depth 0.69 if Channel Slope 0.01100 ft/ft Critical Slope 0.02006 fiUft Bentley Systems, Inc. Haestad Methods SoIBEmrll*fiilervMaster V81(SELECTseries 1) [08.11.01.031 12121/2010 12:06:00 PM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1.203-755.1666 Page 1 of 1 Project Description Friction Method Solve For Input Data Roughness Coefficient Channel Slope Lef; Side Slope Righi Side Slope Discharge Results Normal Depth Flow Area Waited Perimeter Hydraulic Radius Top Width Critical Depth Critical Siope Velocity Velocity Head Specific Energy Froude Number Flow Type GVF Input Data Downstream Depth Length Number Of Steps GVF Output Da"a Upsireara Depth Profile Desrripiion Profile Headluss Downstream Velooily upsireai'I Velooiy Normal Depth r;iliiC21 Depti+ C:hanu�91 Slope Critical Slupe 9r`4907kSheet for SWEIS 1-100 Year - ------- Manning Formula Normal Depth Subcritical 0.030 0.01100 ftfft 3.00 Wit(H:V) 3.00 Wit(H:V) 6.36 fi'/s 0.86 ft ' 2.22 W 5.45 It 0A I M. 5.17 It 0, 77 fl 0,01930 Wfi 2.86 Ws 013 It 0.99 fl 0.77 0.00 a 0.00 ft 0 0.00 It 0,00 It Infli y Ws Infinity ills 0.86 It 0.77 it 0.01'100 Wit 0.01930 Rift Gentley Systems, Inc. Haesiad YlntOods So1Rka9 .Ft+awMaster V0i (SELEC7sedes i) [00.11.01.031 1 -12 H%(310 i :oss. Nrn 27 Sitimons Company Drive Sure 200 W Watertown, CT 06795 USA 11-203-755-1663 page 1 of 1 Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ C.A. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: •�+•®�� p TIMMONS GROUP ul o E YOUR VISION ACHIEVED THROUGH OURS. C 5410 Trinity Road TEL 919.866.4951 Suite 112 FA 919.859.5663 Raleigh, NC 27607 DRaa�..iP.mQ {r2. e.= 1,4e ��, / IN,�- l00 .94 �• T� P. MLQA o.9D2 Ate. �,ano.r�L GoE GF.uEicr `t" C-= oAd�o •mo9`f� 1-0.35 (. o,39oAo> = 0."13°i y1p L�iL -_ �sprS �.2J IrJJM�• �r5 ga,r"'j w� V:�va : 6.;�=CAA. ?34 (?.zo "IHc1.4d A-)' -7.87, j: z.,�r- Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ C.A. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: cN+_ cK Ha uanuC,Lf-- @ 1 D�� p�6�rJ>4E kec-,- 1.1-} At. E o00*00 • u TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. E 5410 Trinity Road TEL 919.866.4951 Suite 112 FAX 919.859.5663 Raleigh, NC 27607 �Q�oTb..�p�C_' O.ar�Co.�Z��) 3-V. 3Sla•2'73S>' 0.80� pIW ' O. BGiC�(a� �NINti�l).17>JJJ= '4.10 G� Worksheet for Swale 2-10 Year Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 Channel Slope 0.00500 Wit Left Side Slope 3.00 Poft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 7.82 Wls Results Normal Depth 1.08 ft Flow Area 3.49 ft- Wetted Perimeter 6.82 ft Hydraulic Radius 0.51 ft Top Width 6.47 ft Critical Depth 0.84 ft Critical Slope 0.01877 ft/ft Velocity 2.24 ft/s Velocity Head 0.08 ft Specific Energy 1.16 ft Froude Number 0.54 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 R Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 It Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 1.08 It Critical Depth 0.84 ft Channel Slope 0.00500 tuft Critical Slope 0.01877 ft/ft Bentley Systems, Inc. Haestad Methods Sol®6mrlEpF11ka rMaster V81 (SELECTseries 1) (08.11.01.031 3/23/2011 11:28:39 AM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA t1-203-755.1666 Page 1 of 1 Worksheet for Swale 2-100 Year Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 Channel Slope 0.00500 ft/ft Left Side Slope 3.00 tuft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 10.47 ft-Is Results Normal Depth 1.20 ft Flow Area 4.34 ft- Wetted Perimeter 7.61 ft Hydraulic Radius 0.57 ft Top Width 7.22 ft Critical Depth 0.95 ft Critical Slope 0.01806 ft/ft Velocity 2.41 fus Velocity Head 0.09 ft Specific Energy 1.29 ft Froude Number 0.55 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity fus Normal Depth 1.20 ft Critical Depth 0.95 ft Channel Slope 0.00500 ft/ft Critical Slope 0.01806 tuft Bentley Systems, Inc. Haestad Methods SolffAmal efite"aster V81(SELECTseries 1) [08.11.01.03] 3/23/2011 11:28:35 AM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1-203.755-1666 Page 1 of 1 Worksheet for Swale 2 Intermediate Section-10 Year Project Description Friction Method Solve For Input Data Roughness Coefficient Channel Slope Left Side Slope Right Side Slope Discharge Results Normal Depth Flow Area Wetted Perimeter Hydraulic Radius Top Width Critical Depth Critical Slope Velocity Velocity Head Specific Energy Froude Number Flow Type GVF Input Data Downstream Depth Length Number Of Steps GVF Output Data Upstream Depth Profile Description Profile Headloss Downstream Velocity Upstream Velocity Normal Depth Critical Depth Channel Slope Critical Slope Manning Formula Normal Depth Subcritioal 0.030 0.00500 ft/ft 3.00 fttft (H:V) 3.00 f1ft (H:V) 6.80 ft-/s 1.02 ft 3.14 ft- 6.47 ft 0.49 ft 6.14 ft 0.80 ft 0.01913 ft/ft 2.16 fills 0.07 ft 1.10 ft 0.53 0.00 It 0.00 It 0 0.00 ft 0.00 ft Infinity ft/s Infinity ftts 1.02 ft 0.80 ft 0.00500 fttft 0.01913 ft/ft Bentley Systems, Inc. Haestad Methods So1616ora 4eRbnMlasler V81 (SELECTseries 1) [08.11.01.03] 3/23/2011 11:29:58 AM 27 Slemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-7551666 Page 1 of 1 Worksheet for Swale 2 Intermediate Section-100 Year Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 Channel Slope 0.00500 ft/ft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 fUft (H:V) Discharge 9.10 ft-/s Results Normal Depth 1.14 ft Flow Area 3.91 ft' Wetted Perimeter 722 it Hydraulic Radius 0.54 ft Top Width 6.85 ft Critical Depth 0.89 ft Critical Slope 0.01840 ft/ft Velocity 2.33 ft/s Velocity Head 0.08 ft Specific Energy 1.23 ft Froude Number 0.54 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 It Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Descdption Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 1.14 ft Critical Depth 0.89 ft Channel Slope 0.00500 ft/ft Critical Slope 0.01840 ft/ft Bentley Systems, Inc. Haestad Methods So16ft0diaRlmMaster V81(SELECTserles 1) [08.11.01.03] , ' 3123/2011 11:30:21 AM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 1 Meeting Memorandum J DESIGN ❑ PHONE Q C.A. .......................................... PROJECT: ............................................. PROJECT NO. DATE: .................................. I.......... PARTICIPANTS: ............................................. ............................................. NOTES BY: sw� a q aCA- �' A IE TIMMONS GROUP 5410 Trinity Road TES 919.866.4951 Suite 112 FP 919.859.5663 Raleigh, NC 27607 z 0 -160G 2�4 = 0. d;� I C. 0 �411qco ( 0,9 e;) is .MC S M.'); 9,0410 sus Project Description Friction Method Solve For Input Data Roughness Coefficient Channel Slope Left Side Slope Right Side Slope Discharge Results Normal Depth Flow Area Wetted Perimeter Hydraulic Radius Top Width Cdtical Depth Critical Slope Velocity Velocity Head Specific Energy Froude Number Flow Type GVF Input Data Downstream Depth Length Number Of Steps GVF Output Data Upstream Depth Profile Description Profile Headloss Downstream Velocity Upstream Velocity Normal Depth Critical Depth Channel Slope Critical Slope Worksheet for Swale 4.10 Year Manning Formula Normal Depth Subcdtical 0.030 0.01420 WTI 3.00 Wit (H:V) 3.00 ft/ft (H:V) 3.60 Wls 0.66 If 1.32 fir 4.19 If 0.31 it 3.98 R 0.62 ft 0.02082 ft/ft 2.73 ftls 012 it 0.78 ft 0.84 0.00 ft 0.00 it 0 0.00 ft 0.00 it Infinity fus Infinity f/s 0.66 it 0.62 ft 0.01420 ft/ft 0.02082 ft/ft Bentley Systems, Inc. Haestad Methods Sol [a 1 4EeFibowMaster V8](SELECTseries 1) [08.11.01.03) 12/13/20'10 3:40:43 PM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203.755-1666 Page 1 of 1 Worksheet for Swale 4-100 Year Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 Channel Slope 0.01420 Rift Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 4.82 Wis Results Normal Depth 0.74 If Flow Area 1.64 ft' Wetted Perimeter 4.68 it Hydraulic Radius 0.35 h Top Width 4.44 h Critical Depth 0.69 ft Critical Slope 0.02003 ft/ft Velocity 2.94 f/s Velocity Head 0.13 it Specific Energy 0.87 If Froude Number 0.85 Flaw Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 it Profile Description Profile Headloss 0.00 it Downstream Velocity Infinity f /s Upstream Velocity Infinity ft/s Normal Depth 0.74 ft Critical Depth 0.69 it Channel Slope 0.01420 f ift Critical Slope 0.02003 ft/ft Bentley Systems, Inc. Haestad Methods Solril1 d5eRorvMaster V81 (SELECTseries 1) 108.11.01.031 12/13/2010 3:40:54 PM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 1 Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ CA. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: E fee�ol� u • TIMMONS GROUP N o YOUR VISION ACHIEVED THROUGH OURS. E 5410 Trinity Road TEL 919.866.4951 Suite 112 FAX 919.859.5663 Raleigh, INC 27607 /. :f"? D.!rq c'— �r-1 /. 6 t:>lb•=`�� F- D•:;/pAI� � .O.V°: �Si —T cj n^.� p.C�io �•,y., Fn•.�— �...\TF. F>;TY . �h-«an,��.c 7 ram, � . —r� S.o= ✓�i= '1 .Zo Iwl lli e... Ri> � ■ Worksheet for Swale 5-10 Year Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 ' Channel Slope 0.01000 fVft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) ' Discharge 7.31 ft-/s Results Normal Depth 0.92 ft Flow Area 2.56 ft' Wetted Perimeter 5.84 ft ' Hydraulic Radius 0.44 ft Top Width 5.54 ft ' Critical Depth 0.82 ft Critical Slope 0.01894 ft/ft Velocity 2.86 f /s ' Velocity Head 0.13 it Specific Energy 1.05 ft Froude Number 0.74 ' Flow Type Subcritical GVF Input Data ' Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft ' Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity fVs Upstream Velocity Infinity fVs Normal Depth 0.92 ft t Critical Depth 0.82 it Channel Slope 0.01000 ft/ft Cdfical Slope 0.01894 ft/ft 1 Bentley Systems, Inc. Hassled Methods SolBilaYQefilawMaster V81(SELECTserles 1) (08.11.01.03] ' 214/2011 9:28:16 AM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1.203-755.1666 Page 1 of 1 Worksheet for Swale 5-100 Year Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.030 Channel Slope 0.01000 tuft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 9.79 ft3/s Results Normal Depth 1.03 ft Flow Area 3.19 ft' Wetted Perimeter 6.52 ft Hydraulic Radius 0.49 ft Top Width 6.18 ft Critical Depth 0.92 ft Critical Slope 0.01822 ft/ft Velocity 3.07 f /s Velocity Head 0.15 ft Specific Energy 1.18 ft Froude Number 0.75 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headless 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity f /s Normal Depth 1.03 ft Critical Depth 0.92 ft Channel Slope 0.01000 fUft Critical Slope 0.01822 fVft Bentley Systems, Inc. Haestad Methods SoIRAM*FlewMaster V8i (SELECTseries 1) [08.11.01.03] 2/4/2011 9:28:11 AM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1.203.755-1666 Page 1 of 1 Culvert Report Hydratlow Express Extension for AutoCAtm Civil 3D®2010 by Autodesk, Inc. Culvert A-10 Year Invert Elev Dn (ft) Pipe Length (ft) Slope (%) Invert Elev Up (fit) Rise (in) Shape Span (in) No. Barrels n-Value Inlet Edge Coeff. K,M,c,Y,k Embankment Top Elevation (ft) Top Width (ft) Crest Width (ft) SL - r rt' 2," 26C..'' 27 6 = 26.00 Calculations = 70.00 Qrnin (cfs) = 0.71 Qmax (cfs) = 26.50 Tailwater Elev (ft) = 15.0 = Cir Highlighted = 15.0 Qtotal (cfs) = 1 Qpipe (Cfs) = 0.012 Qovertop (cfs) = 0 Veloc Dn (ft/s) = 0.021, 1.33, 0.0463, 0.75, 0.7 Veloc Up (ft/s) HGL Dn (ft) FIGL Up (ft) = 29.80 Hw Elev (ft) = 15.00 Hw/D (ft) = 15.00 Flow Regime Culvert 4.10 veal Wednesday, Dec 22 2010 = 4.75 = 4.75 = 0 = 4.75 = 4.75 = 0.00 = 3.87 = 4.53 = 27.25 = 27.50 = 28.13 = 1.30 = Inlet Control Ha. C'-ptl1 Ifl Culvert Report HydraFlow Express Extension for AutoCADO Civil 300 2010 by Autodesk, Inc. Culvert A-100 Yew Invert Elev Dn (ft) Pipe Length (ft) Slope (%) Invert Elev Up (ft) Rise (in) Shape Span (in) No. Barrels n-Value Inlet Edge Coeff. K,M,c,Y,k Embankment Top Elevation (ft) Top Width (ft) Crest Width (ft) 2s— Zb.0C 2 — 25_i5 = 26.00 Calculations = 70.00 Qmin (cfs) = 0.71 Qmax (cfs) = 26.50 Tailwater Elev (ft) = 15.0 = Cir Highlighted = 15.0 Qtotal(cfs) = 1 Qpipe (cfs) = 0.012 Qovertop (cfs) = 0 Veloc Dn (ft/s) = 0.021, 1.33, 0.0463, 0.75, 0.7 Veloc Up (ft/s) HGL Dn (ft) HGL Up (ft) = 29.80 Hw Elev (ft) = 15.00 Hw/D (ft) = 15.00 Flow Regime Cvlvert A-100 Year p:r :-ei:erl --- HGL -- EntbanY Wednesday, Dec 22 2010 = 6.36 = 6.36 0 = = 6.36 = 6.36 = 0.00 = 5.18 = 5.18 = 27.25 = 27.83 = 28.68 = 1.74 ' = Inlet Control n,. oeilu, gin: 2.5i nirol ' l ilea[ L5L 1.5L C 4� Relch dI' Culvert Report Hydranow Express Extension for AutoCADO Civil 3DO 2010 by Autodesk, Inc. Monday, Dec 13 2010 Culvert C Ia 1Ep Invert Elev Dn (ft) = 30.80 Calculations Pipe Length (ft) = 52.32 Qmin (cfs) = 0.97 Slope (%) = 0.76 Qmax (cfs) = 0.97 Invert Elev Up (ft) = 31.20 Tailwater Elev (ft) = 0 Rise (in) = 15.0 Shape = Cir Highlighted Span (in) = 15.0 Qtotal (cfs) = 0.97 No. Barrels = 1 Qpipe (cfs) = 0.97 n-Value = 0.012 Qovertop (cfs) = 0.00 Inlet Edge = 0 Veloc Dn (ft/s) = 1.14 Coeff. K,M,c,Y,k = 0.021, 1.33, 0.0463, 0.75, 0.7 Veloc Up (ft/s) = 2.66 HGL Dn (ft) = 31.62 Embankment HGL Up (ft) = 31.62 Top Elevation (ft) = 34.00 Hw Elev (ft) = 31.74 Top Width (ft) = 20.00 Hw!D (ft) = 0.43 Crest Width (ft) = 20.00 Flow Regime = Inlet Control =1-�� Ilt Culvert C 72: 25a:I` Il Culvert Report Hydra Flow Express Extension for AutoCAD® Civil 3D® 2010 by Autodesk, Inc. Monday, Dec 13 2010 Culvert C too, l®aw Invert Elev Dn (ft) = 30.80 Calculations Pipe Length (ft) = 52.32 Qmin (cfs) = 1.30 Slope (%) = 0.76 Qmax (cfs) = 1.30 Invert Elev Up (ft) = 31.20 Taiiwater Elev (ft) = 0 Rise (in) = 15.0 Shape = Cir Highlighted Span (in) = 15.0 Qtotal (cfs) = 1.30 No. Barrels = 1 Qpipe (cfs) = 1.30 n-Value = 0.012 Qovertop (cfs) = 0.00 Inlet Edge = 0 Veloc Dn (ft/s) = 1.46 Coeff. K,M,c,Y,k = 0.021, 1.33, 0.0463, 0.75, 0.7 Veloc Up (ft/s) = 3.22 HGL Dn (ft) = 31.65 Embankment HGL Up (ft) = 31.65 Top Elevation (ft) = 34.00 Hw Elev (ft) = 31.84 Top Width (ft) = 20.00 Hw/D (ft) = 0.51 Crest Width (ft) = 20.00 Flow Regime = Inlet Control Culvert C _ .,. S�I.•,d __ __ ill ._.__._. Emb,,M Meethig Memep'dB1dum ❑ DESIGN ❑ PHONE G CAA ............................................. PROJECT: PROJECT NO.: .... ...... . DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: V�-AFY L(.N,y,�nrrn ..� fC��-Jca�P' Cw�..c�?�'• A�ta>'.• �ii�-wWP� �(6r-oY�+'i'QF�- 'L9.0� ;& R 6.81"1 -1C. fi rZ] r � l'J u 5410 Trinity Road i TEL 919.866.4951 Suite 112 FAX 919.859.5663 Raleigh, NC 27607 S' , Z. ?J52 7-era ` -z-r,0 + z�z 5c, '`J:B. oti �o,oa2� + o s.. O.v'*4a - 1 Meeting Memorandum ❑ DESIGN ❑ PHONE ❑ C.A. ............................................. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: or°me: 9 C' T9MMONS GROUP 5410 Trinity Road T L 919.866.4951 Suite 112 FAX 919.859.5663 Raleigh. NC 27607 p z...,.-•n E�"c AQEA< ti.v;q S-r nR- o.2-7At -[: 4.: o-o' 14 5.�,�c✓<v,�. - J%aEA.'= ��9 s sF ems- o. oma Ac _ �, vk o..9gc o.2311 r O.3S`7Cy % 0.-J99 oP 0_`&' S� -y.T.- IHn. Q,o= o.sv��.zola�V�Ri�v.ti7/\cr o.9'12_cFs Meeting Memorandum 0 DESIGN ❑ PHONE Q C.A. PROJECT: ............................................. PROJECT NO.: DATE: ............................................. PARTICIPANTS: ............................................. ............................................. NOTES BY: (� _u.oc137�oO S Sg9s Ov.TG-T L-ONCR{�l.• 5410 Trinity Road TEL 919.866.4951 Suite 112 2S' Fnx 9I9.859.5663 j Raleigh, NC 27607 O,o43-�("")(,iG"-, ?31,:z1 2 5Z2 Qi — K &9 rb' L- r% p _L2 i 33 l _ 33,.60' 32fi 6j�2 QK�5agt, �5p•Z_i,l,�, p•ora)2 �"i o o: 2�' Worksheet for Swale 1-Liner Cale Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.020 Channel Slope 0.01100 ft/ft Left Side Slope 3.00 fttft (H:V) Right Side Slope 3.00 fi/ft (H:V) Discharge 4.75 W/s Results Normal Depth 0.66 ft Flow Area 1.32 fV Wetted Perimeter 4.19 ft Hydraulic Radius 0.31 ft Top Width 3.98 it Critical Depth 0.69 ft Critical Slope 0.00892 haft Velocity 3.60 fits Velocity Head 0.20 it Specific Energy 0.86 it Froude Number 1.10 Flow Type Supercritical . GVF Input Data Downstream Depth 0.00 it Length 0.00 it Number Of Steps 0 GVF Output Data Upstream Depth 0.00 fi Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity fVs Upstream Velocity Infinity ft/s Normal Depth 0.66 it , Critical Depth 0.69 it Channel Slope 0.01100 ft/ft Critical Slope 0.00892 ft/ft Bentley Systems, Inc. Haestad Methods S01612wtl47,eFEawMaster V81(SELECTseries 1) [08.11.01.031 12/22/2010 9:47:39 AM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 1 Diversion Ditch Liner Design Sheet Project: 30032 Diversion Number., Permanent Swale 1 Designed By: WZS Date: 12/22/2010 Note: This spreadsheet is only applicable to diversions with longitudinal slopes less than 10%. Channels greater than 10 h should be designed via alternate means. Flowmaster Data and Calculation Output Q= 4.75 cis Manning Roughness= 1 0.020 5= 0.011 Normal Depth= 0.66 ft. Side slopes= 3 :1 Velocity= 3.60 fps FT-emporary Lining Required Temporary Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.015 4.47 0.60 0.41 Woven Paper Net 0.022 3.35 0.69 0.47 Jule Net 0.021 3.47 0.68 0.47 Fiberglass Roving 0.033 2.47 0.80 0.55 Straw with Nei 0.035 0.00 Curled Wood Mat 0,025 1 1 0.00 Synthetic Mat Don't Use Don't Use Use Use Use Use Use Excelsior PPS-8 Extended Term TRM Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If flow depth is out of this range, adjust Roughness n values appropriately. Peronanent Channel Liner Design (10 Year Storm) Flownriasier Data and Calculation Output Q= E��4 cfs Manning Roughness= 0.030s= Normal Depth= 0.77 h Side slopes= 3 :1 Velocity= 2.BG fps Pemlarent Liner F?egvireor Perrnaneni Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.022 3.35 O.69 0.47__ Jute Net _ _ ' 3.47 0.63 0.47 Fiberglass Roving__ _0,021_ 2.47 —__0.00 0.55 Sirew With Net 2.37 0.82 0.5G Curled Wood Mai _ _0.035 0.025 _.—.—__ _ a�...,s..�....e.�_......m.. ..----- 0.00 0.00_ 0.00 __. 0.00.___. 0.U0 Syntheiio Liner V Gravel (050) 2" Gravel (050) 2 Rip -Rap (D50 1) __._..r 2" Rip -Rae (DF)0) 0.033 0.076 _,l.�.Q,.�0.sOG9 .,....�_�,,..�r..n..,.. Ilse Excelsior PP5-8 Extended Term -i Don't Use Use Use Use Use Use Ilse Use Use Note: Manning:, riouyhuess Goefflrienis are hiased on normal flow depths between O.T and 2.0'. hi floe, depin is out o4 this range, adjust roughness n values appropriately. Worksheet for Swale 2-Liner Cale Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.020 Channel Slope 0.00500 ft/ft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 7.82 ft%s Results Normal Depth 0.93 ft Flow Area 2.58 ft- WettedPerimeter 5.86 ft Hydraulic Radius 0.44 If Top Width 5.56 ft Critical Depth 0.84 It Critical Slope 0.00834 ft/ft Velocity 3.04 ft/s Velocity Head 0.14 If Specific Energy 1.07 ft Froude Number 0.79 Flow Type Subcrifical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity f1/s Upstream Velocity Infinity fVs Normal Depth 0.93 ft Critical Depth 0.84 It Channel Slope 0.00500 ft/ft Critical Slope 0.00834 f tft Bentley Systems, Inc. Haestad Methods Sol®brl41elibvMaster VSI (SELECTserles 1) [08.11.01.031 312312011 11:34:37 AM 27 Slemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Pape 1 of 1 Diversion Ditch Liner Design Sheet Project: 30032 Diversion Number., (Permanent Swale 2 Designed By: WZS Date: 3/23/2011 Note: This spreadsheet Is only applicable to diversions with longitudinal slopes less than 10%. Channels greater than 10 % should be designed via alternate means. Flowmaster Data and Calculation Output Q= 7.82 cis 5= 0.005 Side slopes= 3 :1 Temporary Liner Design Calculation Manning Roughness- 0.020 Normal Depth= 0.93 ft. Velocity-- 3.04 fps Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.015 3.77 0.83 0.26 Woven Paper Net 0.022 2.83 0.96 0.30 Jute Net 0.021 2.93 0.94 0.29 Fiberglass Roving 0.033 2.09 1.12 0.35 Straw with Net 0.035 2.00 1.14 0.36 Curled Wood Mat 0.025 1 2.57 1 1.01 1 0.32 Synthetic Mal Donl Use Use Use Use Use Use Use Excelsior CS3•R for Temporary Lining Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If flow depth Is out of this range, adjust Roughness n values appropriately. 0 Permanent Channel Liner Design (10 Year Storm) Flowmaster Data and Calculation Output Q= 7.82 cfs s= 0.(05 Side slopes= 1 3 :1 Permanent Liner Design Calculation Manning Roughness= 0.030 Normal Depth= 1.08 ft. Velocity= 2.24 fps Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.022 0.00 Jute Net 0.021 0.00 Fiberglass Roving 0.033 0.00 Straw with Net 0.035 0.00 Curled Wood Mat 0.025 0.00 Synthetic Liner 0.033 0.00 1" Gravel (D50) 0.041 0.00 2" Gravel (D50) 0.0691 1 1 0.00 6" Rip -Rap (D50) 0.078 1 1 1 0.00 12" Rip -Rap (D50) Use Use Use Use Use Use Use Use Use Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If flow depth is out of this range, adjust Roughness n values appropriately. Worksheet for Swale 2 Intermediate Section -Liner III Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.020 Channel Slope 0.00500 ft/ft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 6.80 ft3/s Results Normal Depth 0.88 ft Flow Area 2.32 ft- Wetted Perimeter 5.56 ft Hydraulic Radius 0.42 ft Top Width 5.28 ft Critical Depth 0.80 ft Critical Slope 0.00850 ft/ft Velocity 2.93 fVs Velocity Head 0.13 ft Specific Energy 1.01 ft Froude Number 0.78 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 0.88 ft Critical Depth 0.80 ft Channel Slope 0.00500 ft/ft Critical Slope 0.00850 ft/ft Bentley Systems, Inc. Haestad Methods So16llik"BeRRlewMaster Val (SELECTserles 1) [08.11.01.03] 3/2312011 11:34:30 AM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA •1-203-755-1666 Page 1 of 1 Diversion Ditch Liner Design Sheet Project: 30032 Diversion Number: Permanent Swale 2 Designed By: WZS Date: 3/23/2011 Note: This spreadsheet is only applicable to diversions with longitudinal slopes less than 10%. Channels greater than 10 % should be designed via alternate means. Flowmaster Data and Calculation Output D= cfs Manning Roughness s= i 0.005 Normal Depth= 0.88 ft. Side slopes= 3 :1 Velocity= 2.93 fps FT-6mp6mT Lining Required Temporary Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.015 3.64 0.79 0.25 Woven Paper Net 0.022 2.73 0.91 0.28 Jute Net 0.021 2.83 0.90 0.28 Fiberglass Roving 0.033 2.01 1.06 0.33 Straw with Net 0.035 0.00 Curled Wood Mat 0.025 1 1 1 0.00 Synthetic Mat Don't Use Use Use Use Use Use Use Excelsior CS3-R for Temporary Lining Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If flow depth Is out of this range, adjust Roughness n values appropriately. Permanent Channel Liner Design (10 Year Storm) Flowmaster Data and Calculation Output Q= I 6.80 cfs Manning Roughness= 1 0.030 s= 0.005 Normal Depth- 1.02 ft. i Side slopes= 3 :1 Velocity= 2.16 fps No Permanent Liner Required Permanent Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.022 0.00 Jute Net 0.021 0.00 Fiberglass Roving 0.033 0.00 Straw with Net 0.035 0.00 Curled Wood Mat 0.025 0.00 Synthetic Liner 0.033 0.00 1"Gravel (D50) 0.041 0.00 2" Gravel (D50) 0.06g 0.00 6" Rip -Rap (D50) 0.078 1 0.00 12" Rip -Rap (D50) Use Use Use Use Use Use Use Use Use Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If flow depth Is out of this range, adjust Roughness n values appropriately. Project Description Friction Method Manning Formula Solve For - Normal Depth Input Data Roughness Coefficient 0.020 Channel Slope 0.01420 ft/ft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 ft/ft (H:V) Discharge 3.60 fN/s Results Normal Depth 0.57 ft Flow Area 0.97 it' Wetted Perimeter 3.60 fl Hydraulic P,adil.ls 027 (1 Top Width 3.42 R Critical Depth 0.62 A Critical Slope 0.00925 fiJft Velocity 3.70 fVs Velocity I -lead 0.21 fi Specific Energy 0.73 0 Froude Number 1.22 Flow Type Supercritical GVF Input Data Downstream Depth 0.00 fi Length 0.00 it Number OF Steps 0 G W Output Data Upstream Depth 0.00 fit Profile Descriptiun Profile 1-1eadlo3s 0.00 it Downsireani Velocity Infinity fus Up»trearri Velocity Infinity fus Nunml Dopih 0.57 fi critical Depth 0.62 it Channel Slope Q01420 pJft Crifical Slope 0,00925 Wit eelluey Sys03ms, Inc. Hanstad Methods Vet (SELECTserlos 1) [08.11.0'1.031 12122/20 M 10:11:00 AM 27 Siemons Company Drive Suite 200 W Watertown, CT 06795 USA +1-203-755-1666 Page 1 of 1 I ' Diversion Ditch Liner Design Sheet Project: 30032 Diversion Number: IPermarent Swale 4 Designed By: WZS Dale: 12/22/2010 Note: This spreadsheet is only applicable to diversions with longitudinal slopes less than 10%. Channels greater than 10% should be designed via alternate means. Flowmaster Data and Calculation Output Q= 3.60 cfs Manning Roughness= 0.020 s= 0.0142 Normal Depth= 0.57 ft. Side slopes= 3 :1 Velocity= I 3.70 fps �.[—Temporary Lininn-9 Required Temporary Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.015 4.59 0.51 0.45 Woven Paper Net 0.022 3.44 0.59 0.52 Jule Net 0.021 3.57 0.58 0.51 Fiberglass Roving 0.033 2.54 0.69 0.61 Straw with Net 0.035 0.00 Curled Wood Mat 0.025 1 1 1 0.00 Synthetic Mal Don't Use Don't Use Use Use Use Use Use PPS-8 Extended Term TRM Note: Mannings Roughness Coefficients are based on normal flow depths between O.fi and 2.0'. If flow depth Is out of this range. adjust Roughness n values appropriately. Permanent Channel Liner Design (10 Year Storm) Flowmaster Data and Calculation Output Q= 3.60 cfs Manning Roughness-0.030 s= 0.0142 Normal Depth= 0.66 0. Side slopes= 3 :1 Velocity= 2.73 fps Permanent Liner Required Permanent Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.022 3.44 0.59 0.52 Jute Net 0.021 3.57 0.58 0.51 Fiberglass Roving 0.033 2.54 0.69 0.61 Straw with Net 0.035 2.43 0.70 0.62 Curled Wood Mat 0.025 0.00 Synthetic Liner 0.033 11' Gravel (D50) 0.041 0.00 2" Gravel (D50) 0.069 0.00 6' Rip -Rap (D50) 0.078 0.00 12" Rip -Rap (D50) Use PP5.8 Extended Term TRM 7771 Don'I Use Use Use Use Use Use Use Use Use Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If Flow depth IS out of this range, adjust Roughness n values appropriately. Worksheet for Swale 5-Liner Calc Project Description Friction Method Manning Formula Solve For Normal Depth Input Data Roughness Coefficient 0.020 Channel Slope 0.01000 tuft Left Side Slope 3.00 ft/ft (H:V) Right Side Slope 3.00 Wit (H:V) Discharge 7.31 ft-/s Results Normal Depth 0.79 ft Flow Area 1.89 ft- Wetted Perimeter 5.02 ft Hydraulic Radius 0.38 It Top Width 4.76 If Critical Depth 0.82 it Critical Slope 0.00842 fVft Velocity 3.87 ff/s Velocity Head 0.23 If Specific Energy 1.03 It Froude Number 1.08 Flow Type Supercritical GVF Input Data Downstream Depth 0.00 It Length 0.00 It Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 It Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 0.79 ft Critical Depth 0.82 It Channel Slope 0.01000 Wit Critcal Slope 0.00842 fVft Bentley Systems, Inc. Hassled Methods SoI01AcW*FAswMaster V81 (SELECTserles 1) [08.11.01.03] 2/412011 9:28:04 AM 27 Siemens Company Drive Suite 200 W Watertown, CT 06795 USA +1.203.755.1666 Page 1 of 1 I Diversion Ditch Liner Design Sheet Project: 30032 Diversion Number., IPermanent Swale 5 Designed By: WZS (Revised) Date: 2/4/2011 Note: This spreadsheet is only applicable to diversions with longitudinal slopes less than 10%. Channels greater than 10 % should be designed via alternate means. Flowmaster Data and Calculation Output Q= 7.31 cfs Manning Roughness= 0.020 s= 0.01 Normal Depth= 0.79 ft. Side slopes= 3 :1 Velocity= 3.87 fps [remporary Lining Required Temporary Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.015 4.80 0.71 0.44 Woven Paper Net 0.022 3.61 0.82 0.51 Jute Net 0.021 3.73 0.81 0.51 Fiberglass Roving 0.033 2.66 0.96 0.60 Straw with Net 0.035 2.55 0.98 0.61 Curled Wood Mat 11 0.025 1 1 1 0.00 Synthetic Mat DonY Use Don'f Use Use Use Use Use Use PP5-8 Extended Term Excelsior Matting Note: Mannings Roughness Coefficients are based on normal Flow depths between 0.5' and 2.0'. If flow depth Is out of this range, adjust Roughness n values appropriately. Permanent Channel Liner Design (10 Year Storm) Flowmaster Data and Calculation Output Q= 1 .31 lets Manning Roughness- 0 s= .01 Normal Depth= 0.92 ft. Side slopes= 3 :1 Velocity= 2.86 fps Permanent Liner Required Permanent Liner Design Calculation Manning's Roughness n Channel Velocity Normal Depth Shear Stress Liner Type 0.022 3.61 0.82 0.51 Jute Net 0.021 3.73 0.81 0.51 Fiberglass Roving 0.033 2.66 0.96 0.60 Straw with Net 0.035 2.55 0.98 0.61 Curled Wood Mat 0.025 0.00 Synthetic Liner 0.033 0.00 1" Gravel (D50) 0.041 0.00 2" Gravel (D50) 0.069 1 0.00 6" Rip -Rap (D50) 0.078 1 1 0.00 12' Rip -Rap (D50) Use PPS-8 Extended Term Excelsior Matting Don? Use Use Use Use Use Use Use Use Use Note: Mannings Roughness Coefficients are based on normal flow depths between 0.5' and 2.0'. If flow depth Is out of this range, adjust Roughness n values appropriately. IRiP R1,2 PEaaeat�r� �issi rea Ccal�cal�t6®aa� 3Do eOutlet _ W = Do r 0.4La 120 pipe i I J : diameter(Do) L"'.� I!i� O.SDo i:100 II I I I .l 90 I' I ll n I 11 l 'I lllf I I ur I 1 601 l ry m u u , I Ali 70 0C� 60 . �LI I� 50 40 i Y r��lti I t I �i �l I ti� rF a JU 2 v a O 20 l l I r I I it l y I N I I I lIIII I 1 1 /I r. I•^ry vJ U„CL Mt X ' D IIII I '' :Ill v_75. �h _ .I 'o l; I..,. 2 ,.. l r . .(/ J //5 •10 20 � 50 100 200 500 1 1000 ��" q•/, Discharge (11 Isec) ' Curves may not be extrapolated Figure 0.066 Design of ontlal proteclmn from a round pipe flowing full, maximum laifwater condition (Tw e 0.5 diameter). Q:y,74cii C, ,Vrsr A = L p= A sr� t ..,.-, Vh. '• PO to•.I�q : 1,'t` r o•� tvi =3 r.45 Du' I t0 PtPr= Yo Re,. 12/9J h7ti�- 5 �,� �r•ers-rya, use s,....� t�r,.c �.t �,11� Rf+t' �op..Cuu��j' i�, 20 10 u Appendices 3 3 7 3 5 10 20 50 100 200 500 1000 Discharge (ft3/sec) Curves may not be extrapolated. Figure 0.06a Design of outlet protection protection from a round pipe flowing full, minimum tailwater condition (T. < 0.5 diameter). Z: Iva g�„a D,sc HwP�n = 3.secFS L= tot w,=3t3=3�t.zS�= 3�5� Rev. 12/93 8.06.3 F f" 1 I � � �*4 w'r. a� ,r t i � r �,r +; j �. , � {' ]' � ... i , i ' �;,�; a I � p � � ' � �' I. ' � � . ., s� � " {; I i;,d � � � i t r� ; 1.��� x { �, ,�' ' ;' �� i � t � � T ', r i`, � � . � � �',t f . �' �. . { � 1 � 1, i.. I �. ,. x > .' .� �� � { 1 _ � � � d � I .I F �, � ,. 1 �� + , , � �. `� i` , Ir; �. � � �4a<{; �� � t � ' . :, { � �Yt � � <� � � �, • � � � . ; ' � � � a�.�, ' a ,'r> ,� � � � i , �; �� �. ��� _ (' : r:.r ��� 1 � a � �` � � �� � �, �, ,� � i � �. r } v Pn' � "- � i E 1. �,j1, t h a. ^: �' qi � f _ It r � � k � , .� , � � ni>k. { �,, ix ! i ;• � � �` � , � , � : � I ��,�: �j � , t � , r.�;. 7 �, c � ,� I � � ;� a, � ,�� ! � ;�,�� a ,a. t� ,;._� � a ��; ., � , , � � . � , , ;. � +,r � � �12 �r ., j �� ,��� �::��a a : _ ,i . �1, � "a i f ,J � s � i � � �' "�= �n ': � �' � , �,.�< ' ;1 � 1 j � ; .r I ? ,t �� � V � � 1�T � � I � �' 1 1, ��,� '. i ��.3: � , �, � t� I� �, , ; ,. j i i,�' {V[[ � `" I w .,� � i t 1 " � � � a-' " SS �' E n� :�''l� �iR'�„�, , u .i ♦i I ~ t ♦ l Y a I a \ , J 1 } \ t { , I `�` .. ♦�. is \ I ' ` Y , \ I t \ ^ .\♦ i I ♦ a b � \ ...... ... r` . rye. , r t 4 ` �f a R I + r R _I TIMMONS GROUP .•••••� YOUR VISION ACHIEVED THROUGH OURS. • e 5410 Trinity Road, Suite 112, Raleigh, NC 27607 To: NCDENR Wilmington Regional Office Attn: Ms. Kelly Johnson 127 Cardinal Drive Extension Wilmington, NC 28405 From: Zak Shipman, PE Project: Stormwater Permit -Pre -Trial Confinement Facility Enclosed Please Find: DATE 2 4-20-11 Revised Stormwater Drawings 2 Revised Supplement Forms 1 Revised Calculation Packa e 1 Response To Comment Letter 1 Architectural Roof Plan Comments: Ms.Johnson, Please let me know if you have any questions. Thanks, SIGNED: k Shipman, PE APR 2 1 2011 TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. April 19, 2011 NCDENR Wilmington Regional Office Division of Water Quality 127 Cardinal Drive Extension Wilmington, NC 28405 Attn: Ms. Kelly Johnson Re: Request for Additional Information, Project SW8 110326 Pre -Trial Confinement Facility Camp Lejeune, NC Dear Ms. Johnson, APR 2 1 2011 We are in receipt of your April 14 letter for the reference project requesting additional information. We have made revisions to the permit application package in accordance with your comments, which are summarized as follows: 1. Drainage Easement: Please provide a drainage easement for each BMP and show the dimensions of the easement on the plan. Timmons Response: Per our email conversation on 4/14, drainage easements are not required on this site as the property is owned by the federal government and has access to the ponds for maintenance. 2. Inverts: Please show all inverts including the swales and underdrains. Timmons Response: Inverts have been shown on the swale centerlines and on the underdrains on the detail sheets. 3. Roof Drainage: Please show the roof drainage pipes on the plan in combination with enough information to describe how the drainage area on the roof will be split into the two drainage areas. ✓ Timmons Response: I have included a roof plan from the architect showing the direction of slope, as well as gutter and downspout locations. 4. Dimensions: Please fully dimension the buildings, parking, and sidewalks. Timmons Response: A site layout plan is included, showing building dimensions, as well as other site layout data for impervious calculation. 5. Trash Rack: Please show that the trash rack openings will be no larger than 6"X6". immons Response: Sheets C-507 and C-508 have been modified to require the 6"X6" ✓T spacing. 6. Elevations: Please check BMP elevations. For instance, for cell #1 the supplement shows the temporary/ponding pool to be at 27.00, but the plans show it at 26.74 msl. n/ The SHWT also differs. Timmons Response: I have double checked the BMP elevations and made adjustments accordingly. For Cell 1, we have shown the temporary pool to be the top P F 4, TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. of the riser (El. 27.00) and have also shown the DENR water quality volume stage (El. 26.74) on the section view on sheet C-507. I have made a note on each supplement form to clarify so that they are consistent through the plans and supplement forms. I have also adjusted the SHWT elevation on the supplement to match the plans. 7. Grass: Please specify sod as opposed to seed and indicate the type of grass to be planted. No mulch is required for grassed cells. Please remove the 2" mulch from the supplement. Timmons Response: Sheets C-507 anclC-508 have been modified to require sod on the basin bottom and slope. The 2" mulch layer has been removed as requested. 8. Surface Area: Please show the dimensions and radii of lines/arcs formed by the planting elevations (the surface area of the cells) on the plans. Timmons Response: Dimensions and radii have been added to the detail sheets as 'needed. 9. Project area: Please indicate the area that will be covered by the permit on the plan. Timmons Response: The project site is represented on the grading drawing C-108 as a ✓ gray dashed line. I have put a leader indicating it is the project limits. 10. Wetlands: Please delineate wetlands or include a note that none exist onsite. Timmons Response: A note has been added to C-108 indicating there are no jurisdictional wetlands on site. 11. Stamped: Please submit a stamped cover page. It appears that this was inadvertently left off of the copy previously submitted. Timmons Response: A sealed cover sheet has been included. 12. Surface Areas: The supplement forms are set up to show only one surface area, though the surface area at the planting elevation and the surface area at the temporary pool are slightly different due to the slope of the cell sides between the two elevations. It appears that you have identified both surface areas for both cells, or perhaps there are some typos. Please clarify the surface areas at both the planting elevation and the temporary pool elevation for each cell (if you are using both of them). Then, please also ensure that you are using the surface are at the planting elevation when calculating the draw through rate. For Cell #1, the supplement shows that the surface area is 24,223 sf and the calculations shown that it is 14,920 sf. For Cell #2, the supplement shows that the surface area is 4,564 sf and the calculations show that it is 3,213 sf. If the surface areas change, please also check the resulting Q values and the underdrain pipe sizing. Timmons Response: The supplements have been modified to represent the surface area of the basin at the planting elevation. I had originally shown the surface areas of the basins at the top of berm. The calculations have been double checked to ensure the draw through rate is calculated based on the planting elevation surface area. If you have any questions, please don't hesitate to give me a call at your convenience. Best Regards, APR 2 ). 2011 I akShipman, PE Timmons Group E 0 0 M P m P P �c® NR North Carolina Department of Environment and Natural Resources Division of Water Quality. Beverly Eaves Perdue Coleen H. Sullins Governor Director April 14, 2011 Mr. Carl Baker, PE, Deputy Public Works Officer USMC, Camp Lejeune 1005 Michael Road Camp Lejeune, NC 28547 Subject: Request for Additional Information Stormwater Project No. SW8 110326 Pre -Trial Confinement Center. Onslow County Dee Freeman Secretary Dear Mr. Baker: The Wilmington Regional Office received and accepted a State Stormwater Management Permit Application for the subject project on March 24, 2011. A preliminary in-depth review of that information has determined that the application is not complete. The following information is needed to continue the stormwater review: Plans: a. Drainage Easement: Please provide. a drainage easement for each BMP and show the dimensions of the easement on the plan. b. Inverts: Please show all inverts including swales and underdrains. c. Roof Drainage: Please show the roof drainage pipes on the plan in combination with enough information to describe how the drainage area on the roof will be split into the two drainage areas. d. Dimensions: Please fully dimension the buildings, parking, and sidewalks. e. Trash Rack: Please show that the trash rack openings will be no larger than 6"x6". Elevations: Please check the BMP elevations. For instance, for cell #1 the supplement shows the temporary/ponding pool to be at 27.0 but the plans show it to be 26.74msl. The SHWT also differs. g- Grass: Please specify sod as opposed to seed and indicate the type of grass to be planted. No mulch is required for grassed cells. Please remove the 2" mulch from the supplement. h. Surface Area: Please show the dimensions and radii of lines/arcs formed by the planting elevations (the surface areas of the cells) on the plans. Project Area: Please indicate the area that will be covered by the permit on the plan. Wetlands: Please delineate wetlands or include a note that none exist onsite Wilmington Regional Office 127 Cardinal Drive Extension, Wilmington, North Carolina 28405 One Phone: 910-796.72151 FAX: 910-350-20041 Customer service: 1-877-623-6748 North Carol l ll<1 Internet: w .ncvvaterquality.orgI An Equal Opportunity 1 Affirmative Action Employer Aa mra �tl SW8 110326 April 14, 2011 2. Design Calculations: a. Stamped: Please submit a stamped cover page. It appears that this was inadvertently left off of the copy previously submitted. b. Surface Areas: The supplement forms are set up to show only one surface area, though the surface area at the planting elevation and the surface area at the temporary pool will be slightly different due to the slope of the cell sides between the two elevations. It appears that you have identified both surface areas for both cells, or perhaps there are some typos. Please clarify the surface areas at both the planting elevation and the temporary pool elevation for each cell (if you are using both of them). Then, please also ensure that you are using the surface area at the planting elevation when calculating the draw through rate. For cell #1, the supplement shows that the surface area is 24,223sf and the calculations show that it is 14,920sf. For cell #2, the supplement shows that the surface area is 4,564 and the calculations show that it is 3,213. If the surface areas change, please also check the resulting Q values and the underdrain pipe sizing. Please remember that a change to one number may have a domino effect on other numbers. Please check all plans, calculations and forms and make changes as needed. Please note that this request for additional information is in response to a preliminary review. The requested information should be received in this Office prior to May 13, 2011, 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, email 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. 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. Please reference the State assigned project number on all correspondence. Any original documents that need to be revised have been sent to the engineer or agent. All original documents must be returned or new originals must be provided. Copies are not acceptable. If you have any questions concerning this matter please feel free to call me at (910) 796-7215 or email me at kelly.p.johnson@ncdenr.gov. Sincerely, eellyJ nson Environmental Engineer GDS/kpj: S:\WQS\Stormwater\Permits & Projects\2011\110326 HD\2011 04 addinfo 110326 cc: Zak Shipman, PE, Timmons Group Wilmington Regional Office Stormwater File Page 2 o f 2 ectName: Yv�•T�At (A�;Mp""� I Revweraf �^r�r�srs'1 Date'a3_j��p_`P11 ect Received Date:.}U (�r.QfU ii �I t ffent /Rai tari /rirrin nnol Rule(s) Subject (check all that app�lly):�� i Symbols for completing form: '✓'= Yes/OK: ' x '= No/Deficiot:'nia' or T or'/' ❑ 1995 Coastal Wi 8 Coastal ❑ Phase II ❑ Universal Paperwork: ❑ Check for $505 (must be no older than 6 months) ❑ Application form with correct/original signatures (original plus 1 copy). If Corporation or LLC also: o Print the info from the NCSOS o . Either,-1.) The applicant; is listed on the N SOSSwith"his/her correct title or, 2.).A notarizedletter of authorization has been provided � �� 1 ❑—Supplementsr(1,onginalperiBMP). BMP,type(s): �' in'�;tFj�}—((�n,`f_��V ❑ O&M with-correctloriginal signatures (1-original per BMP, except level'spreaders/filter strips'and'swales) ❑ Deed restrictions(if outparcel cr-subdividing) (original plus 1 copy) o' Deed restriction template (signed and notarized) or 0-Proposed Declaration of Covenants and Restricticns_(signed and notaprized)� ❑ oils report identifying the-SHWT ❑ 'Su pportingg�calculatlons,signed,& sealed_(ifnecessary)�A� ❑ Receivin stream classificational If SA or ORW also: [_' o --SA: �USGS topol,map'with.the-site,4he receiving waters and the mile radius shown to scale. `o ORW: 575 It of MHWL for Area of Environmental Concern and max BUA per rule. ❑ Modifications: 1.) If built: Designer's Cert., 2.) If partially built: Partial Cert., 3.) If not built: No Cart, needed. Development Type (check all that apply): D Residential or ❑ Commercial r:❑ Deed,restrictions match? ❑ Subdivision �V or) ❑ Single Lot //� O Deed restrictions match? ❑ High Densityor t ❑Low Density I O Deed restrictions match? ❑ Offsite project U ❑ Redevelopment �❑ Modification ❑ Exempt ❑ NCG02 (bulkhead) D NCG03 (clear/grade) ❑ NCG04 (linear) Density: ❑ BOA:calculations include common areas, clubhouse, sidewalks, etc. ✓ ❑ BUA C \ -Matches high/low density requirement for rule and receiving stre. class ❑ No -obvious mathlerrorsvI ��; �l i �/ ��� ❑ If High D� �Aensity: Design storm -correct for rule and receiving stream class. Plans, signed and sealed`(2 sets):y' f I ❑ Two sets received ❑ Layout (with proposed BUA dimensions) ❑ Grading ❑ Drainage area map (all HD systems & curb outlet swales) D Vicinity map ❑ Project Boundaries (� � ❑ Legend ❑ �N/etlands: �� f l// /\ Deli neated�onplans� (\10 No�wetlandsonsite on -plans D vDetails:' \i l�� V_t�u , c�/ o i o Roads o Cul-de-sacs o Curbing / o Sidewalk o BMPs! Level spreaders/ Filter strips/ Curb outlet swales/ o Buildings (Apts or Condos) Offsite Projects: ❑ Designer's Certification has been submitted for the Offsite BMP receiving the runoff from the project. ❑ Deed restrictions have been recorded and a copy submitted for the Offsite BMP permit. ❑ Lot size has not changed from what was approved under the Master Plan. Correct lot number is referenced on the supplement form. _ ❑ Offsite system is in compliance with its permit, if known. Infiltration Projects: ❑ Soils report: SHWT, soil type, and expected infiltration rate are provided. ❑ DWO has conducted a site visit? Date: Wet Ponds: Permanent Pool Meets One of the Following: D Is located no lower than 6" below the estimated SHWT. ❑ Incoming groundwater is quantified and evaluated, AND Storage volume verified, AND Outlet evaluated for free drainage to the receiving waters under SHWT conditions. Decision (check one): D Complete: Return file to admin (Jo Casmer) to log in. (Stamped in received date = BIMS date) ❑ Shr htly incomplete: E-mail consultant, request inrermation to be returned within one business day (24 hours after request. Info requests on Friday, allow a return on the following business day). If info not returned. issue an applicatinn return letter and give e/eryfhing to admin. (.Add info received date = Blnne d7fe) ❑ Substantially incomplete: Issue an application return letter and give evervthing to admin. 17' Storm water Design Narrative MAR 2. Pre -Trial Confinement Facility -Camp Lejeune, NC Project Overview The Pre -Trial Confinement Facility is a new project that proposes to construct a two story brig facility which will be used to house detainees prior to their processing by the military justice system. The facility will have a total of 75 beds and will be constructed to accommodate a future expansion up to 135 beds. The building will feature pre -cast tilt wall construction and steel framing with a brick veneer exterior. The site is approximately 8 acres in size and is currently vacant. Existing Site Conditions and Demolition: The site selected for the Pre -Trial Confinement Facility is located adjacent to the intersection of Duncan Street and Snead's Ferry Road inside the cantonment area of Camp Lejeune. The site is heavily wooded, except for a small cleared area located along the southwestern border of the project site. An existing barracks building and associated parking lot are located along the western border of the site. The existing base brig is located southwest of this barracks facility. Existing basketball and volleyball courts are located in the cleared area on the west of the site, along with a small picnic shelter and several small storage buildings. Additionally, the site is bounded to the east by a dirt tank trail and a small intermittent stream. This stream is an unnamed tributary to Cogdels Creek and is classified by North Carolina Department of Environment and Natural Resources (NCDENR) as SC -NSW. Topography on the parcel is generally flat with some areas of moderate grade located in the vicinity of the adjacent stream. Soils on site are classified as Baymeade fine sand by the local soils survey. No wetlands have been documented on the parcel as indicated by the RFP provided by the government. Several existing features are currently located on the site that will require removal or demolition. These include exercise equipment, a volleyball court, basketball court, and covered picnic shelter. Drainage and Stormwater Considerations: Stormwater will be managed on site by carefully grading area to direct runoff into a network of vegetated swales and treatment basins. Curb and gutter has been minimized as much as possible to encourage sheet flow. Additionally, a minimal amount of hard piping is proposed which will require runoff to travel long distances in vegetated swales prior to entering BMP facilities. NCDENR regulations require the treatment of the first inch and a half of runoff for the removal of Total Suspended Solids (TSS). This project seeks to meet these requirements by directing all runoff into one of three stormwater Best Management Practices (BMP) basins. Two bioretention basins will be installed to treat surface runoff per the regulations. Bioretention basins 1 and 2 will be constructed in accordance with NCDENR BMP manual. Runoff will enter these basins via combinations of sheet flow as well as from vegetated swales. Runoff from the swales will flow over energy dissipating rip rap pads to slow velocity and promote sediment removal and filtration. The basins will feature a thick layer of soil media which will filter the runoff and remove pollutants and other contaminants. Perforated underdrains are to be installed in the basins per the construction drawings to allow for more efficient water removal from the soil media. While the maximum ponding depth is limited to 12 inches, the basins are sized accordingly to prevent discharge from the 1 and 2 year storms. Both basins have very small discharges in the 10, 25, and 100 year storms as indicated on the plan sheets. These extended detention capacities have eliminated the need for a complicated bypass system to parse out runoff in excess of the design control volume. r1utip"ns;;nEc! Geotechnirol-F.nvironmentnl • Tesfbq REPORT OF SUBSURFACE INVESTIGATION AND GEOTECHNICAL ENGINEERING SERVICES P-1310 Pre -Trail Detainee Facility MCB Camp Lejeune, North Carolina G E T PROJECT NO: JX10-113G November 24, 2010 IfW Prepared for . Kahn Construction Company, Inc. P.O. Box 1179 Columbia, South Carolina 29202 ATTN: Mr. Barret Boozer Prepared by GET Solutions, Inc. 415 A Western Boulevard, Jacksonville, NC 28546 ♦ Phone 910-478-9915 ♦ Fax 910-418-9917 info@getsolutionsinc.com -- -- --- -- -- -—III-__--- Solutions„Inca November 24, 2010 Gmmimirn! • Enm"n ... etlnl. rwmg TO: M.B. Kahn Construction Company, Inc. P.O. Box 1179 Columbia, SC 29202 Attn: Mr. Barret Boozer RE: Report of Subsurface Investigation and Geotechnical Engineering P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Dear Mr. Boozer: In compliance with your instructions, we have completed our Subsurface Investigation and Geotechnical Engineering Services for the above referenced project. The results of this study, together with our recommendations, are presented in this report. Often, because of design and construction details that occur on a project, questions arise concerning subsurface conditions. G E T Solutions, Inc. would be pleased to continue its role as Geotechnical Engineer during the project implementation. Thank you for the opportunity to work with you on this project. We trust that the information contained herein meets your immediate need, and should you have any questions or if we could be of further assistance, please do not hesitate to contact us. Respectfully Submitted, ,,•`"' CAg 1, G E T Solutions, Inc. r4O oFEssfo'�4y'•,, ✓� n Q y s PE No. r 033629 Glenn W. Hohmeier, P.E. �NGIN" V Senior Project Engineer w„� ty, Ho �+ �� NC Reg. # 033529 ARO Camille A. Kattan, P.E. - ? srnt Principal Engineer 014103 = NC Reg. # 014103 `VC INC .-"Z1 Copies: (1) Client 415-A Western Boulevard • Jacksonville, NC 28546 • Phone: (910) 478-9915 Fax: (910) 478-9917 info@getsolutionsinc.com_ A TABLE OF CONTENTS EXECUTIVE SUMMARY.............................................................................................i 1.0 PROJECT INFORMATION..............................................................................1 1.1 Project Authorization..............................................................................1 1.2 Project Description.................................................................................1 1.3 Purpose and Scope of Services.............................................................1 2.0 FIELD AND LABORATORY PROCEDURES..................................................2 2.1 Field Exploration....................................................................................2 2.2 Laboratory Testing.................................................................................3 3.0 SITE AND SUBSURFACE CONDITIONS........................................................4 3.1 Site Location and Description................................................................4 3.2 Subsurface Soil Conditions....................................................................5 3.3 Groundwater Information.......................................................................6 4.0 EVALUATION AND RECOMMENDATIONS...................................................7 4.1 Subsurface Voids...................................................................................7 4.2 Clearing and Grading.............................................................................8 4.3 Subgrade Preparation............................................................................9 4.4 Structural Fill and Placement...............................................................10 4.5 Shallow Foundation Design Recommendations...................................11 4.6 Settlements..........................................................................................11 4.7 Foundation Excavations.......................................................................11 4.8 Floor Slabs...........................................................................................12 4.9 Seismic Design Recommendations.....................................................13 4.10 Soil Permeability..................................................................................13 5.0 CONSTRUCTION CONSIDERATIONS.........................................................14 5.1 Drainage and Groundwater Concerns.................................................14 5.2 Site Utility Installation...........................................................................14 5.3 Excavations.........................................................................................15 6.0 REPORT LIMITATIONS.................................................................................15 APPENDIX I BORING LOCATION PLAN APPENDIX II BORING LOGS APPENDIX III GENERALIZED SOIL PROFILE APPENDIX IV ADDENDUM NO.1 TOTHE ORIGINAL FEASIBILITY STUDY REPORTED ON THE DATE OF FEBRUARY 19, 2010 (GET Project No. EC09-106G) APPENDIX V HYDRAULIC CONDUCTIVITY WORKSHEETS APPENDIX VI CLASSIFICATION SYSTEM FOR SOIL EXPLORATION GET Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G EXECUTIVE SUMMARY November 24, 2010 The project site is located on the west side of Sneads Ferry Road within the Camp LeJeune military installation in North Carolina. The development at this site is planned to consist of constructing a single story pre-trial detainee facility with a mezzanine having a total plan area of approximately 25,000 square feet. The maximum wall and column foundation loads associated with the structure were not known at the time of this report. However, based on our experience with similar projects the maximum wall loads associated with the building are not expected to exceed 5 kips per linear foot, and the column loads are not expected to exceed 100 kips. The structure's first floor will be supported on -grade with the distributed loads estimated at 150 pounds per square foot. The construction at this site is also planned to consist of paved driveways and parking areas, infiltration/bioretention basins and installation of associated infrastructure components. Our field exploration program included four (4) recently completed 30-foot deep Standard Penetration Test (SPT) borings drilled by G E T Solutions, Inc. within the footprint of the proposed structure, and four (4) 15-foot deep SPT boring (designated as BMP-1 through BMP-4) drilled within the proposed infiltration/bioretention basins. A total of four (4) 75-foot deep previously completed SPT borings identified as B-5 through B-8 and four (4) CPT soundings (CPT-1 through CPT-4) were performed during the project's initial feasibility study and were included in our evaluations for foundation design recommendations for the proposed building. Additionally, boring INF-1 is included herein but was limited to evaluating the soil conditions in the vicinity of the proposed southeastern infiltration/bioretention basin. A brief description of the natural subsurface soil conditions is tabulated below: RANGES OF AVERAGE STRATUM DESCRIPTION SPTI'I N- DEPTH (Feet) VALUES 0 to 0.17-1.2 2 to 14 inches of Topsoil 0.17-1.2 SAND with varying amounts of silt and/or clay to I WOH to 100 (SP, SP-SM, SM, SC-SM, SC) 15-75 4 to 6 IA Lean CLAY (CL); Boring B-5 & B-11 only 5 to 8 7 to 7.5 & N/A @ B-6; IB Fat CLAY (CH); Boring B-6 & B-9 only 23 to 28 1 @ B-9 28 to 32 Void; Borings B-7 and B-8 only N/A MARLSTONE; at varying depths between 30 and 30 to 58 IC 58 feet below the existing site grades at 32 to 77 Borings B-6, B-7, and B-8 Note (1) SPT = Standard Penetration Test, N-Values in Blows -per -foot WOH — Weight of Hammer GET Report of Subsurface Investigation and Geotechnical Engineering Services November 24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G The groundwater level was recorded at the boring locations and as observed through the wetness of the recovered soil samples during the drilling operations. The initial groundwater table was measured to occur at depths ranging from 8 to 10 feet below current grades at the B-9 through B-12 boring locations, which corresponds to an elevation of about 20.0 feet (MSL). In addition, four (4) temporary piezometers were installed at the boring BMP-1 through BMP-4 locations at the time of drilling and 24 hour groundwater readings were measured to occur at depths ranging from 4.8 to 5.29 feet below current grades (boring locations BMP-1 and BMP-2) which corresponds to an approximate elevation of 27.0 feet MSL and at depths of 9.875 to 9.92 feet below current grades (boring locations BMP-3 and BMP-4) which corresponds to an approximate elevation of 20.0 feet MSL. The soil sample colors were used to aid in identifying the estimated normal SHWT at the location of borings BMP-1 through BMP-4. It is noted that soil morphology is not a reliable indicator of the SHWT in drained soils. However, slight color distinctions were observed within the soil samples collected at the location of borings BMP-1 through BMP-4. As such, the normal SHWT depth was estimated to occur at approximately 4 feet below the existing site grade elevation at boring locations BMP-1 and BMP-2 and at approximately 6 feet below the existing site grade elevation at boring locations BMP-3 and BMP-4. The current groundwater levels encountered at the project site and the estimated normal SHWT depths are anticipated to be contributed to the varying site topography and possible perched groundwater conditions specifically at boring BMP-1 and BMP-2 locations. The following evaluations and recommendations were developed based on our field exploration and laboratory -testing program: • Field testing program during construction to include, subgrade proofrolling, compaction testing, and foundation excavation observations for bearing capacity verification. All other applicable testing, inspections, and evaluations should be performed as indicated in the North Carolina State Building Code (2006 International Building Code with North Carolina Amendments). A cut of up to 14 inches will be required to remove the topsoil material from the construction area. • Some subgrade improvements should be anticipated within the construction areas (undercutting and backfilling with select fill) as a result of potentially very loose subgrade soils containing appreciable amounts of fines (silt and clay) and organics (vicinity of boring locations B-9 and B-10). ;; GET Report of Subsurface Investigation and Geotechnical Engineering Services November 24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G • Subsurface voids approximately 2-feet deep were encountered at the location of the initially completed borings B-7 and B-8 at depths of 28 to 30 feet, respectively below the existing site grade elevations. Subsequently, a supplemental subsurface investigation (Addendum No. 1 to the original feasibility study) was completed to further explore the subsurface soil conditions at the location of the new building site (shifted to the east). Four (4) Cone Penetrometer Test (CPT) soundings were performed as part of Addendum No. 1 within the newly established building footprint which did not encounter these voids. Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G) is included in Appendix IV of this report. The building was again relocated to the west since the time Addendum 1 was completed. The initially drilled borings were plotted onto the new site plan provided by the client. One boring (B-8) was determined to be located within the northwest portion of the newly positioned building footprint. It should be noted that no voids were encountered within the recently completed borings B-9 through B-12 and previously completed borings B-5, B-6 and CPT soundings CPT-1 through CPT-4 to depths of 30 to 36 feet. The subsurface voids, where encountered, can be addressed by means of pressure grout placement (injection) to fill the voids and prevent the potential for subsidence from occurring and resulting in foundation and/or slab -on -grade settlement. It is recommended that a grout injection specialty contractor develop the number, depths, and locations of the injection points. Other options would include shifting the building easterly away from boring B-8; supporting that portion of the building on deep foundations (such as auger cast piles) or assuming some risk associated with the subsurface voids and leave the building at the present location. In any case, additional void delineation efforts may be warranted, by means of advancing several CPT probes within the western building area. • Shallow foundations designed using a net allowable bearing capacity of 2,000 psf (24-inch embedment, 24-inch width) in combination with void stabilization, if deemed necessary. • Estimated post -construction total and differential settlements up to 1-inch and''/z inch, respectively, as contributed by the foundation bearing soils. • Based on our experience with similar construction in the general area of the project site and in accordance with the previously completed Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G included in Appendix IV of this report) and the NC Building Code; Chapter 16, this site would be classified as a site Class C. GET Report of Subsurface Investigation and Geotechnical Engineering Services November 24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G This summary briefly discusses some of the major topics mentioned in the attached report. Accordingly, this report should be read in its entirety to thoroughly evaluate the contents. iv GET Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 1.0 PROJECT INFORMATION 1.1 Project Authorization G E T Solutions, Inc. has completed our subsurface investigation and geotechnical engineering services for the proposed P-1310 Pre -Tail Detainee Facility located within the Camp LeJeune military installation in North Carolina. The Geotechnical Engineering Services were conducted in general accordance with G E T Solutions, Inc. Proposal No. PJX10-120G, dated October 6, 2010. Furthermore, these services were provided in conjunction with our previously completed feasibility study reported on the date of April 17, 2009 (GET Project No. EC09-106G) and Addendum No. 1 dated February 19, 2010. Authorization to proceed with the Geotechnical Engineering Services was received from Mr. Barret Boozer of M.B. Kahn Construction Company, Inc. 1.2 Project Description The development at this site is planned to consist of constructing a single story pre-trial detainee facility with a mezzanine having a total plan area of approximately 25,000 square feet. It is expected that the structure will be of steel frame and CMU wall design. The maximum wall and column foundation loads associated with the structure were not known at the time of this report. However, based on our experience with similar projects the maximum wall loads associated with the building are not expected to exceed 5 kips per linear foot, and the column loads are not expected to exceed 100 kips. The structure's first floor will be supported on -grade with the distributed loads estimated at 150 pounds per square foot. The structure's first floor elevation (FFE=35.0 MSL) is expected to be located slightly above existing site grade elevations, which range from approximately 27 feet to 31 feet (MSL) within the building footprint. Therefore, it is anticipated that 4 to 7 feet of structural fill will be required to establish the design grade elevations. The construction at this site is also planned to consist of paved driveways and parking areas, infiltration/bioretention basins and installation of associated infrastructure components. If any of the noted information is incorrect or has changed, please inform G E T Solutions, Inc. so that we may amend the recommendations presented in this report, if appropriate. 1.3 Purpose and Scope of Services The purpose of this study was to obtain information on the general subsurface conditions at the proposed project site. The subsurface conditions encountered were then evaluated with respect to the available project characteristics. In this regard, engineering assessments for the following items were formulated: General assessment of the soils revealed by the borings performed at the proposed development. 1 GET Report of Subsurface Investigation and Geolechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 2. General location and description of potentially deleterious material encountered in the borings that may interfere with construction progress or structure performance, including existing fills or surficial/subsurface organics. 3. Soil subgrade preparation, including stripping, grading and compaction. Engineering criteria for placement and compaction of approved structural fill material. 4. Construction considerations for fill placement, subgrade preparation, and foundation excavations. 5. Feasibility of utilizing a shallow foundation system for support of the proposed structure. Design parameters required for the foundation system, including foundation sizes, allowable bearing pressures, foundation levels and expected total and differential settlements. Permeability (infiltration) values are provided based on the results of in -situ Saturated Hydraulic Conductivity Testing conducted within the proposed infiltration/bioretention basins as well as our experience with similar soil conditions. Normal seasonal high groundwater table (SHWT) was also estimated. The scope of services did not include an environmental assessment for determining the presence or absence of wetlands or hazardous or toxic material in the soil, bedrock, surface water, groundwater or air, on or below or around this site. Prior to development of this site, an environmental assessment is advisable. 2.0 FIELD AND LABORATORY PROCEDURES 2.1 Field Exploration In order to explore the general subsurface soil types and to aid in developing associated foundation parameters, four (4) 30-foot deep SPT borings (designated as B-9 through B- 12) were drilled within the proposed structure's footprint. To aid in developing associated storm water management parameters, four (4) 15-foot deep SPT boring (designated as BMP-1 through BMP-4) were drilled within the proposed infiltration/bioretention basins. In -situ soil permeability testing was performed at each of these boring locations. Four (4) temporary piezometers were also installed (one at each of the boring locations). Solutlonslricl� ,`='is�:. Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G The SPT borings were performed with the use of rotary wash "mud" drilling procedures in general accordance with ASTM D 1586. The tests were performed continuously from the existing ground surface to a depth of 12-feet, and at 5-foot intervals thereafter. The soil samples were obtained with a standard 1.4" I.D., 2" O.D., 30" long split -spoon sampler. The sampler was driven with blows of a 140 lb. hammer falling 30 inches, using an automatic hammer. The number of blows required to drive the sampler each 6-inch increment of penetration was recorded and is shown on the boring logs. The sum of the second and third penetration increments is termed the SPT N-value (uncorrected for automatic hammer). A representative portion of each disturbed split -spoon sample was collected with each SPT, placed in a glass jar, sealed, labeled, and returned to our laboratory for review. Following the exploration procedures, the borings were backfilled with a neat cement grout mix in accordance with NCDENR requirements, excluding the four (4) infiltration/bioretention boring locations (Boring BMP-1 through BMP-4) where piezometers were installed. The recently completed borings were performed in conjunction with, and labeled consecutively with the previously completed borings associated with the project's feasibility study reported on the date of April 17, 2009 (GET Project No. EC09-106G). Accordingly, the four (4) 75-foot deep SPT borings identified as B-5 through B-8 performed during our initial feasibility study for the proposed project, which are located in the vicinity of the proposed reconfigured building footprint, are included herein and in our evaluations for foundation design recommendations for the proposed building. Additionally, boring INF-1 is included herein but was limited to evaluating the soil conditions in the vicinity of the proposed southeastern infiltration/bioretention basin. Whereas, the remaining borings performed during the initial feasibility study identified as B-1 through B-4 are not included in this report as they were located outside the limits of the proposed building. Boring locations B-9 through B-12 were established and staked in the field by a representative of G E T Solutions, Inc. with the use of a Global Positions System unit as well as the "State Plane" coordinates provided by the client. Boring locations BMP-1 through BMP-4 were surveyed in the field by the client. The approximate boring locations are shown on the attached "Boring Location Plan" (Appendix 1), which was reproduced based on the site plan provided by the client. 2.2 Laboratory Testing Representative portions of all soil samples collected during drilling were sealed in glass jars and zip lock bags, labeled and transferred to our laboratory for classification and analysis. The soil classification was performed by a Geotechnical Engineer in accordance with ASTM D2488. Seventeen (17) representative soil samples were selected and subjected to laboratory testing, which included natural moisture, 4200 sieve wash and Atterberg Limit testing and analysis, in order to corroborate the visual classification. These test results are provided in Table 1 on the following page and are presented on the "Boring Log" sheets (Appendix II), included with this report. Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Table I - Laboratory Test Results Boring No. Depth (Feet) Natural Moisture 0 Passing #200 Atterberg Limits LL/PL/PI USCS Classification B-9 4-6 22.0 32.9 Not Tested SC-SM B-9 8-10 26.7 25.1 Not Tested SP-SM B-9 23-25 69.2 90.6 70/25/45 CH B-10 6-8 21.5 34.9 32/22/10 Sc B-12 2-4 14.4 23.0 Not Tested SM BMP-1 1.5-2 15.2 31.1 Not Tested SM BMP-2 1.5-2 10.4 21.2 Not Tested SM BMP-3 3.5-4 15.7 24.0 Not Tested SM BMP-3 4-6 22.0 Not Tested Not Tested SM . BMP-3 6-8 18.0 Not Tested Not Tested SP-SM BMP-3 8-10 21.7 Not Tested Not Tested SP-SM BMP-3 10-12 25.4 Not Tested Not Tested SP-SM BMP-4 4.5-5 12.6 17.5 Not Tested SM BMP-4 4-6 9.2 Not Tested Not Tested SM BMP-4 6-8 16.6 Not Tested Not Tested SM BMP-4 8-10 19.6 Not Tested Not Tested SM BMP-4 10-12 21.0 Not Tested Not Tested SP-SM 3.0 SITE AND SUBSURFACE CONDITIONS 3.1 Site Location and Description The project site is located on the west side of Sneads Ferry Road within the Camp LeJeune military installation in North Carolina. This site consists predominantly of a heavily wooded parcel. The existing grades of the project site range from approximately 25 feet to 31 feet (MSL). The proposed construction areas are bordered to the north by Duncan Street, to the south by a wooded area, to the east by an existing dirt path followed by a heavily wooded area and to the west by a combination of an existing parking lot and an existing structure (Building 1042). An areal image of the general construction area is provided below and was obtained from Google Earth. GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 3.2 Subsurface Soil Conditions The results of our recently and previously completed soil test borings indicated the presence of approximately 2 to 14 inches of topsoil at the boring locations. Underlying the topsoil and extending to the boring termination depths of 15, 30, and 75 feet below existing site grades, the natural subsurface soils generally consisted of very loose to very dense SAND (SP, SP-SM, SM, SC-SM, SC) with varying amounts of silt, clay, marine shell fragments, and cemented sands. Trace amounts of organics were observed within these granular soils at depths ranging from 0 to 4 feet below existing grades at the location of borings B-9 and B-10. A shallow subsurface deposit of Lean CLAY (CL) was encountered at the location of borings B-5 and B-11 at a depth ranging from 4 to 6 feet below existing grades. Additionally, a deposit of Fat CLAY (CH) was encountered at the location of boring B-6 at a depth ranging from about 7 to 7.5 feet and at B-9 at a depth ranging from about 23 to 28 feet below the existing grades. 5 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Deposits of Marlstone, which appear to be of a limestone formation, with varying thicknesses were encountered at the location of borings B-6, B-7, and B-8 at depths ranging from 30 feet to 53 feet below existing grades and were noted to extend to depths ranging from 38 feet to 58 feet. Finally, during our previous subsurface investigation, 1.5- foot to 2-foot voids were encountered at the location of borings B-7 and B-8 at depths ranging from 28 to 32 feet below the existing site grade elevations. It should be noted that a supplemental subsurface investigation (Addendum No. 1) was completed to further delineate the presence of these subsurface voids encountered in these borings. Four (4) Cone Penetrometer Test (CPT) soundings were performed as part of Addendum No. 1 within a newly established building footprint which did not encounter these voids. Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G) is included in Appendix IV of this report. The subsurface description is of a generalized nature provided to highlight the major soil strata encountered. The records of the subsurface exploration are included on the "Boring Log" sheets (Appendix II) and in the "Generalized Soil Profile" (Appendix III), which should be reviewed for specific information as to the individual borings. The stratifications shown on the records of the subsurface exploration represent the conditions only at the actual boring locations. Variations may occur and should be expected between boring locations. The stratifications represent the approximate boundary between subsurface materials and the transition may be gradual or occur between sample intervals. It is noted that the topsoil designation references the presence of surficial organic laden soil, and does not represent any particular quality specification. This material is to be tested for approval prior to use. 3.3 Groundwater Information The groundwater level was recorded at the location of borings B-9 through B-12 and as observed through the wetness of the recovered soil samples during the drilling operations. The initial groundwater table encountered at these boring locations was measured to occur at depths ranging from 8 to 10 feet below current grades, which corresponds to an elevation of about 20.0 feet (MSL). In addition, four (4) temporary piezometers were installed at the boring BMP-1 through BMP-4 locations at the time of drilling and 24 hour groundwater readings were measured to occur at depths ranging from 4.8 to 5.29 feet below current grades (boring locations BMP-1 and BMP-2) which corresponds to an approximate elevation of 27.0 feet MSL and at depths of 9.875 to 9.92 feet below current grades (boring locations BMP-3 and BMP-4) which corresponds to an approximate elevation of 20.0 feet MSL. The piezometers were removed following the 24-hour readings and the boreholes were backfilled. The soils recovered from the location of borings B-9 through B-12 and BMP-1 through BMP-4 were classified in general accordance with ASTM D 2487 test method. Based on the soil texture classifications located throughout the site, the shallow subsurface soils appeared to be relatively homogenous consisting predominantly of SAND (SC, SC-SM, SM, SP-SM, SP). 6 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G The soil sample colors were used to aid in identifying the estimated normal SHWT at the location of borings BMP-1 through BMP-4. It is noted that soil morphology is not a reliable indicator of the SHWT in drained soils. However, slight color distinctions were observed within the soil samples collected at the location of borings BMP-1 through BMP-4. As such, the normal SHWT depth was estimated to occur at approximately 4 feet below the existing site grade elevation at boring locations BMP-1 and BMP-2 and at approximately 6 feet below the existing site grade elevation at boring locations BMP-3 and BMP-4. The current groundwater levels encountered at the project site and the estimated normal SHWT depths are anticipated to be contributed to the varying site topography and possible perched groundwater conditions specifically at boring BMP-1 and BMP-2 locations. Groundwater conditions will vary with environmental variations and seasonal conditions, such as the frequency and magnitude of rainfall patterns, as well as man-made influences, such as existing swales, drainage ponds, underdrains and areas of covered soil (paved parking lots, sidewalks, etc.). Seasonal groundwater fluctuations of±2 feet are common in the project's area; however, greater fluctuations have been documented. We recommend that the contractor determine the actual groundwater levels at the time of the construction to determine groundwater impact on the construction procedures. 4.0 EVALUATIONS AND RECOMMENDATIONS Our recommendations are based on the previously discussed project information, our interpretation of the soil test borings and laboratory data, and our observations during our site reconnaissance. If the proposed construction should vary from what was described, we request the opportunity to review our recommendations and make any necessary changes. 4.1 Subsurface Voids Subsurface voids approximately 2-feet deep were encountered at the location of the initially completed borings B-7 and B-8 at depths of 28 to 30 feet, respectively below the existing site grade elevations. Subsequently, a supplemental subsurface investigation (Addendum No. 1 to the original feasibility study) was completed to further explore the subsurface soil conditions at the location of the new building site (shifted to the east). Four (4) Cone Penetrometer Test (CPT) soundings were performed as part of Addendum No. 1 within the newly established building footprint which did not encounter these voids. Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G) is included in Appendix IV of this report. The building was again relocated to the west since the time Addendum 1 was completed. The initially drilled borings were plotted onto the new site plan provided by the client. One boring (B-8) was determined to be located within the northwest portion of the newly positioned building footprint. It should be noted that no voids were encountered within the recently completed borings B-9 through B-12 and previously completed borings B-5, B-6 and CPT soundings CPT-1 through CPT-4 to depths of 30 to 36 feet. 7 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G The subsurface voids, where encountered, can be addressed by means of pressure grout placement (injection) to fill the voids and prevent the potential for subsidence from occurring and resulting in foundation and/or slab -on -grade settlement. It is recommended that a grout injection specialty contractor develop the number, depths, and locations of the injection points. Other options would include shifting the building easterly away from boring B-8; supporting that portion of the building on deep foundations (such as auger cast piles) or assuming some risk associated with the subsurface voids and leave the building at the present location. In any case, additional void delineation efforts may be warranted, by means of advancing several CPT probes within the western building area. 4.2 Clearing and Grading The proposed construction area should be cleared by means of removing the topsoil, trees, and associated root mat. It is estimated that a cut of up to 14 inches in depth will be required to remove the topsoil. This cut is expected to extend deeper in isolated areas to remove deeper deposits of organic soils, or unsuitable soils, which become evident during the clearing. It is recommended that the clearing operations extend laterally at least 5 feet beyond the perimeter of the proposed construction areas. In addition, varying amounts of organics were encountered generally in the upper 4.0 feet of the very loose granular soils at the location of borings B-9 and B-10. Based on our experience with similar heavily wooded areas within the Camp Lejeune military installation, subsurface organics which may include roots, tree limbs and stumps may be present below the current grades. Therefore, an estimated cut depth of up to about 2.0 to 4.0 feet may be required in order to remove surficial and/or subsurface deposits of organic soils, which may become evident during the clearing operation. Accordingly, the subgrade preparations procedures performed during construction, as indicated in Section 4.3 of this report, should include a series of test pit excavations to further evaluate the suitability of these soils to remain in -place for foundation, slab, and/or pavement support. As stated above, the subsurface soils in isolated areas (generally the upper 4.0 feet) recovered at the location of borings B-9 and B-10 contained varying amounts of organics. Accordingly, following the initial clearing, the resulting exposed subgrade will generally be comprised of SAND (SM, SC-SM, and SC) containing an appreciable amount of fines (silt and clay). Accordingly, combinations of excess surface moisture from precipitation ponding on the site and the construction traffic, including heavy compaction equipment, may create pumping and general deterioration of the bearing capabilities of the surface soils. Therefore, undercutting to remove unstable soils and/or soils containing organics may be required. The extent of the undercut will be determined in the field during construction, based on the outcome of the field testing procedures (subgrade proofroll and/or possible test pits). Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Furthermore, inherently wet subgrade soils combined with potential poor site drainage make this site particularly susceptible to subgrade deterioration. Thus, grading should be performed during a dry season if at all possible. This should minimize these potential problems, although they may not be eliminated. The project's budget should include an allowance for subgrade improvements (undercut and backfill with structural fill or Aggregate Base Course material). Control of surface water is very important to the successful completion of the proposed construction. The contractor should plan his grading activities to control surface water and minimize erosion of exposed cut or fill material. This may include constructing temporary berms, ditches, flumes and/or slope drains to intercept runoff and discharge it in a controlled fashion, while complying with state and local regulations. 4.3 Subgrade Preparation Following the clearing operation, the exposed subgrade soils should be densified with a large static drum roller. After the subgrade soils have been densified, they should be evaluated by G E T Solutions, Inc. for stability. Accordingly, the subgrade soils should be proofrolled to check for pockets of loose material hidden beneath a crust of better soil. Several passes should be made by a large rubber -tired roller or loaded dump truck over the construction areas, with the successive passes aligned perpendicularly. The number of passes will be determined in the field by the Geotechnical Engineer depending on the soils conditions. Any pumping and unstable areas observed during proofrolling (beyond the initial cut) should be undercut and/or stabilized at the directions of the Geotechnical Engineer. The prepared subgrade should be sloped to prevent the accumulation and/or ponding of surface water. If the exposed subgrade becomes wet or frozen, the geotechnical engineer should be consulted. Following the proofroll and approval by the engineer, it is recommended that the newly exposed subgrade soils be compacted to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D1557), as tested to a depth of at least 12 inches. The suitability of compacting the natural subgrade soils should be more accurately determined in the field by the G E T Solutions, Inc. representative at the time of construction as the compaction operations could deteriorate the subgrade soil conditions. Accordingly, it is anticipated that this site will require monitoring of the clearing, subgrade preparation, and fill placement procedures by a G E T Solutions, Inc. representative in order to minimize potential deterioration of the natural subgrade soils. The compaction testing of the natural subgrade soils may be waived by the Geotechnical Engineer, where firm and stable bearing conditions are observed during the proofroll. 9 GET Report of Subsurface Investigation and Geolechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 4.4 Structural Fill and Placement Following the approval of the natural subgrade soils by the Geotechnical Engineer, the placement of the fill required to establish the design grades may begin. Any material to be used for structural fill should be evaluated and tested by G E T Solutions, Inc. prior to placement to determine if they are suitable for the intended use. Suitable structural fill material should consist of sand or gravel containing less than 20% by weight of fines (SP, SM, SW, GP, GW), having a liquid limit less than 20 and plastic limit less than 6, and should be free of rubble, organics, clay, debris and other unsuitable material. The Silty SAND (SM) and SAND (SP-SM, SP) subsurface soils encountered at the boring locations appear to meet the criteria recommended in this report for reuse as structural fill. Additionally, it is anticipated that any soils excavated on -site and proposed to be re -used as backfill, will require stockpiling and air drying in order to establish a moisture content suitable for placement and compaction. Soil deposits excavated at the site and noted to contain significant amounts of organics should not be used as fill and/or backfill within the proposed construction areas. Further classification testing (natural moisture content, gradation analysis, and Proctor testing) should be performed in the field during construction to evaluate the suitability of excavated soils for reuse as fill within building and pavement areas. The remaining on -site excavated soils (Topsoil, SANDS with organics, Clayey SAND, and CLAY) are not anticipated to be suitable for re -use as structural fill but may be used as fill within green areas. All structural fill should be compacted to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D1557). In general, the compaction should be accomplished by placing the fill in maximum 10-inch loose lifts and mechanically compacting each lift to at least the specified minimum dry density. A representative of G E T Solutions, Inc. should perform field density tests on each lift as necessary to assure that adequate compaction is achieved. Backfill material in utility trenches within the construction areas should consist of structural fill (as previously indicated above), and should be compacted to at least 95 percent of ASTM D1557. This fill should be placed in 4 to 6 inch loose lifts when hand compaction equipment is used. Care should be used when operating the compactors near existing structures to avoid transmission of the vibrations that could cause settlement damage or disturb occupants. In this regard, it is recommended that the vibratory roller remain at least 25 feet away from existing structures; these areas should be compacted with small, hand -operated compaction equipment. ----- ----- ----- GET _ Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: Al0-113G 4.5 Shallow Foundation Design Recommendations Provided that the subsurface void issues are addressed as described in Section 4.1 and previously stated construction procedures are properly performed, the proposed structure can be supported by shallow spread footings bearing upon firm natural soil or well compacted structural fill material. The footings can be designed using a net allowable soil pressure of 2,000 pounds per square foot (psf). In using net pressures, the weight of the footings and backfill over the footings, including the weight of the floor slab, need not be considered. Hence, only loads applied at or above the finished floor need to be used for dimensioning the footings. In order to develop the recommended bearing capacity of 2,000 pounds per square foot (psf), the base of the footings should have an embedment of at least 24 inches beneath finished grades and wall footings should have a minimum width of 24 inches. In addition, isolated square column footings are recommended to be a minimum of 3 feet by 3 feet in area for bearing capacity consideration. The recommended 24-inch footing embedment is considered sufficient to provide adequate cover against frost penetration to the bearing soils. 4.6 Settlements It is estimated that, with proper site preparation including the subsurface improvements noted above (where required), the maximum resulting post construction total settlement of the proposed building foundations should be up to 1 inch, as contributed by the foundation bearing soils. The maximum differential settlement magnitude is expected to be less than -inch between adjacent footings (wall footings and column footings of widely varying loading conditions), as contributed by the foundation bearing soils. The settlements were estimated on the basis of the results of the SPT borings. Careful field control will contribute substantially towards minimizing the settlements. 4.7 Foundation Excavations In preparation for shallow foundation support, the footing excavations should extend into firm natural soil or well compacted structural fill. Some foundation improvements (undercut) may be necessary to remove unsuitable organic laden soils particularly within the vicinity of borings B-9 and B-10 where up to 4.0 feet of Silty SAND (SM) with organics were encountered. All foundation excavations should be observed by G E T Solutions, Inc. At that time, the Geotechnical Engineer should also explore the extent of excessively loose, soft, or otherwise unsuitable material within the exposed excavations. Also, at the time of footing observations, the Geotechnical Engineer may find it necessary to make hand auger borings or use a hand penetration device in the bases of the foundation excavations. If pockets of unsuitable soils requiring undercut are encountered in the footing excavations, the proposed footing elevation should be re-established by means of backfilling with "flowable fill", an open graded washed stone (such as No. 57 stone), or a suitable structural „ GET Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G fill material compacted to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D 1557), as described in Section 4.4 of this report, prior to concrete placement. This construction procedure will provide for a net allowable bearing capacity of 2,000 psf. Immediately prior to reinforcing steel placement, it is suggested that the bearing surfaces of all footings be compacted using hand operated mechanical tampers, to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D 1557) as tested to a depth of 12 inches, for bearing capacity considerations. In this manner, any localized areas, which have been loosened by excavation operations, should be adequately recompacted. The compaction testing in the base of the footings may be waived by the Geotechnical Engineer, where firm bearing soils are observed during the footing inspections. Soils exposed in the bases of all satisfactory foundation excavations should be protected against any detrimental change in condition such as from physical disturbance, rain or frost. Surface run-off water should be drained away from the excavations and not be allowed to pond. If possible, all footing concrete should be placed the same day the excavation is made. If this is not possible, the footing excavations should be adequately protected. 4.8 Floor Slabs The floor slab may be constructed as a slab -on -grade member provided the previously recommended earthwork activities and evaluations are carried out properly. It is recommended that the ground floor slab be directly supported by at least a 4-inch layer of relatively clean, compacted, poorly graded sand (SP) or gravel (GP) with less than 5% passing the No. 200 Sieve (0.074 mm). The purpose of the 4-inch layer is to act as a capillary barrier and equalize moisture conditions beneath the slab. It is recommended that all ground floor slabs be "floating". That is, generally ground supported and not rigidly connected to walls or foundations. This is to minimize the possibility of cracking and displacement of the floor slabs because of differential movements between the slab and the foundation. Slab -on -grade post construction settlements should be limited to''/z-inch or less. The slabs can be designed with the use of a subgrade modulus on the order of about 150 psi/in. It is also recommended that the floor slab bearing soils be covered by a vapor barrier or retarder in order to minimize the potential for floor dampness, which can affect the performance of glued tile and carpet. Generally, use a vapor retarder for minimal vapor resistance protection below the slab on grade. When floor finishes, site conditions or other considerations require greater vapor resistance protection; consideration should be given to using a vapor barrier. Selection of a vapor retarder or barrier should be made by the Architect based on project requirements. 12 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: All 0-113G 4.9 Seismic Design Recommendations: Based on our experience with similar construction projects in the general area of the project site, and in accordance with the previously completed Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G included in Appendix IV of this report) and the NC Building Code; Chapter 16, this site would be classified as a site Class C, based on which seismic designs should be incorporated. This recommendation is based on the data obtained from the 75-foot deep SPT borings, our experience with 100-foot deep CPT soundings and SPT borings performed within the vicinity of the project site, as well as the requirements indicated in the North Carolina State Building Code (2006 International Building Code). 4.10 Soil Permeability Four (4) infiltration tests were performed at boring locations BMP-1 through BMP-4 (one test at each boring location). The tests were performed at depths ranging from 2 to 5 feet below existing site grade elevations. The borehole was prepared utilizing an auger to remove soil clippings from the base. Infiltration testing was then conducted within the vadose zone utilizing a Precision Permeameter and the following testing procedures. A support stand was assembled and placed adjacent to the borehole. This stand holds a calibrated reservoir (2000 ml) and a cable used to raise and lower the water control unit (WCU). The WCU establishes a constant water head within the borehole during testing by use of a precision valve and float assembly. The WCU was attached to the flow reservoir with a 2-meter (6.6 foot) braided PVC hose and then lowered by cable into the borehole to the test depth elevation. As required by the Glover solution, the WCU was suspended above the bottom of the borehole at an elevation of approximately 5 times the borehole diameter. The shut-off valve was then opened allowing water to pass through the WCU to fill the borehole to the constant water level elevation. The absorption rate slowed as the soil voids became filled and an equilibrium developed as a wetting bulb developed around the borehole. Water was continuously added until the flow rate stabilized. The reservoir was then re -filled in order to begin testing. During testing, as the water drained into the borehole and surrounding soils, the water level within the calibrated reservoir was recorded as well as the elapsed time during each interval. The test was continued until relatively consistent flow rates were documented. During testing the quick release connections and shutoff valve were monitored to ensure that no leakage occurred. The flow rate (C ), height of the constant water level (H), and borehole diameter (D) were used to calculate KS utilizing the Glover Solution. 13 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Based on the field testing and corroborated with laboratory testing results (published values compared to classification results), the hydraulic conductivity of the shallow soils is tabulated below (Table III) and is presented on the "Hydraulic Conductivity Worksheet" (Appendix V), included with this report. Table III - Infiltration Test Results Boring Boring depth ft * Water depth ft* Percent Silt and/or Clay Ksat Value cm/sec Ksat Value in/hr Ksat Class BMP-1 2.0 4.8 31.1 T23 x 10" 0.102 Moderate/ Low BMP-2 2.0 5.29 21.2 8.94 x 10 1.267 Moderate/ High BMP-3 4.0 9.875 24.0 2.27 x 10 0.321 Moderate/ High BMP-4 5.0 9.92 17.5 6.33 x 10 0.898 Moderately High The boring test and water depths noted above are referenced from below the existing site grade elevations. 5.0 CONSTRUCTION CONSIDERATIONS 5.1 Drainage and Groundwater Concerns It is expected that dewatering may be required for excavations that extend near or below the existing groundwater table. Dewatering above the groundwater level could probably be accomplished by pumping from sumps. Dewatering at depths below the groundwater level may require well pointing. It would be advantageous to construct all fills early in the construction. If this is not accomplished, disturbance of the existing site drainage could result in collection of surface water in some areas, thus rendering these areas wet and very loose. Temporary drainage ditches should be employed by the contractor to accentuate drainage during construction. If water collects in foundation excavations, it will be necessary to remove water from the excavations, remove saturated soils, and re -test the adequacy of the bearing surface soils to support the design bearing pressure prior to concrete placement. 5.2 Site Utility Installation The base of the utility trenches should be observed by a qualified inspector prior to the pip and structure placements to verify the suitability of the bearing soils. If unstable bearing soils are encountered during installation some form of stabilization may be required to provide suitable bedding. This stabilization is typically accomplished by providing additional bedding materials (NCDOT No. 57 stone). In addition, depending on the depth of the utility trench excavation, some means of dewatering may be required to facilitate the utility installation and associated backfilling. All utility excavations should be backfilled with structural fill, as described in Section 4.4 of this report. 4 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 5.3 Excavations In Federal Register, Volume 54, No. 209 (October, 1989), the United States Department of Labor, Occupational Safety and Health Administration (OSHA) amended its "Construction Standards for Excavations, 29 CFR, part 1926, Subpart P". This document was issued to better insure the safety of workmen entering trenches or excavations. It is mandated by this federal regulation that all excavations, whether they be utility trenches, basement excavation or footing excavations, be constructed in accordance with the new (OSHA) guidelines. It is our understanding that these regulations are being strictly enforced and if they are not closely followed, the owner and the contractor could be liable for substantial penalties. The contractor is solely responsible for designing and constructing stable, temporary excavations and should shore, slope, or bench the sides of the excavations as required to maintain stability of both the excavation sides and bottom. The contractor's responsible person, as defined in 29 CFR Part 1926, should evaluate the soil exposed in the excavations as part of the contractor's safety procedures. In no case should slope height, slope inclination, or excavation depth, including utility trench excavation depth, exceed those specified in local, state, and federal safety regulations. We are providing this information solely as a service to our client. G E T Solutions, Inc. is not assuming responsibility for construction site safety or the contractor's activities; such responsibility is not being implied and should not be inferred. 6.0 REPORT LIMITATIONS The recommendations submitted are based on the available soil information obtained by G E T Solutions, Inc. and the information supplied by the client and their consultants for the proposed project. If there are any revisions to the plans for this project or if deviations from the subsurface conditions noted in this report are encountered during construction, G E T Solutions, Inc. should be notified immediately to determine if changes in the foundation recommendations are required. If G E T Solutions, Inc. is not retained to perform these functions, G E T Solutions, Inc. can not be responsible for the impact of those conditions on the geotechnical recommendations for the project. The Geotechnical Engineer warrants that the findings, recommendations, specifications or professional advice contained herein have been made in accordance with generally accepted professional geotechnical engineering practices in the local area. No other warranties are implied or expressed. 15 GET Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G After the plans and specifications are more complete the Geotechnical Engineer should be provided the opportunity to review the final design plans and specifications to assure our engineering recommendations have been properly incorporated into the design documents, in order that the earthwork and foundation recommendations may be properly interpreted and implemented. At that time, it may be necessary to submit supplementary recommendations. This report has been prepared for the exclusive use of M.B. Kahn Construction Company, Inc. and their consultants for the specific application to the proposed P-1310 Pre -Trial Detainee Facility project located within the Camp LeJeune military installation in North Carolina. 16 GET APPENDICES BORING LOCATION PLAN f I l• Zi7 � I� [e7 �iZe�9 III GENERALIZED SOIL PROFILE IV ADDENDUM NO. 1 TO THE ORIGINAL FEASIBILITY STUDY REPORTED ON THE DATE OF FEBRUARY 19, 2010 (GET Project No. EC09-106G) V HYDRAULIC CONDUCTIVITY WORKSHEET VI CLASSIFICATION SYSTEM FOR SOIL EXPLORATION 0 GET BORING LOG B-5 PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MS' DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-30-09 DEPTH TO WATER - INITIAL': S 9' AFTER 24 HOURS: - CAVING> .0 c > > W n m y v a Eo o, v m �, Description o, w o E Z in o- > E$ co d E N 3 12 o y> m n Z o N yt v TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value 10 20 30 40 50 60 70 0 0 3 6 8 10 12 7 7 7 7 4 6 3.1• 14 inches of TOPSOIL ', 1 24 SS 1 ? 2 1.2 Tan, moist, Silty fine SAND (SM), very loose 2 3 4 24 24 20 SS SS ss 2 3 4 n 4 4 s 5 s �5 Gray, moist, Silty, Clayey SAND (SC-SM), loose 4. Mottled Gray -Reddish Tan, moist, Lean CLAY (CL), medium stiff 6 Mottled Tan -Reddish Tan, moist to wet, Silty fine SAND (SM), very loose to loose Light Gray and with clay from 8 to 15 feel Wet from 9 feet Light Tan from 10 feet Reddish Tan from 13 feel With clay from 23 to 28 feet Dark Gray from 28 feel 38 Dark Gray, wet, poorly graded fine to medium SAND (SP-SM) with 2 5 20 5 is SS 4 s 5 3 - 4 io 6 24 SS 3 J 4 7 Zl SS a 4 15 5 5 8 14 SS 3 c 3 10 20 25 9 16 SS 3 3 4 5 10 E 10 18 SS Z 2 0 39 5 11 20 SS 2 3 4 35 .'... -'%Iw S f 2 4 — Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample - - — — -- — ---- — '— -HA, Hand Auger Sample' BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM 0 1586 ai GET �a r•,..w,.a...,:.m..„,...,,,,,. BORING LOG B-5 PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-30-09 DEPTH TO WATER - INITIAL': LR 9' AFTER 24 HOURS: S CAVING> -L .0 4 > w «D.c n v m v Eo n d„ Description n a w o. o E Z wvw n> E$ of n m E rn w: 3 T o y> m n o = ,,, z o o u \ TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value- �® 10 20 30 40 50 60 70 -10 12 40 silt, medium dense Gray, wet, Silty fine SAND ISM) with trace Cemented Sand, dense 53 Gray, wet, Silty fine SAND ISM) mixed with Cemented Sand and trace Marine Shell Fragments, dense :: l:C i!. f .': VI at: aiEi ,Ln: 11. ci[c1. I' li Y 1 1 12 19 SS a 12 12 19 36 33 38 46 63 48 . . ... ..... ... .. .. I.. f.. -- 13 18 SS 5 11 13 141 -15 45 14 19 SS 3 17 19 24 — 20 16 50 15 2a SS z 16 ,7 3 -z 55 to 58 Gray, wet, Silty, Clayey SAND (SC-SM), dense 16 20 SS 9 1s 23 26 30 60 20 63 Gray, wet, Silty fine SAND (SM), dense to very dense .. 17 17 SS 14 19 P7 32 — 35 — 65 — -- 40 ws 18 24 SS 21 34 50 22 70 75 : 19 20 55 17 23 31 45 Boring terminated at 75 ft. TO Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = split Spoon Sample ST = Shelby Tube Sample HA'='Hand 'Auger Sample" BS = Bulk Sample *The initial oroundwafer readmo may not be indicative of the static oroundwiner leyeL WOH = We aht of Hammer PAGE 2 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1566. GET PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. -�- - - - BORING LOG B-B PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29' MSI DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-30-09 DEPTH TO WATER -INITIAL': S 11' AFTER 24 HOURS: CAVING> .0 c 0 m w ¢ a? p E n v m e p Description E 2 0 w n o E Z rn a E$ N m �- c, E H _ 3 �O o v m n m Z\ o TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value - 10 20 30 40 50 60 70 p 2 6 14 11 10 9 8 6 6 25 32 17. 18.1 10 inches of TOPSOIL 1 24 as 1 1 .: ........ :. :...:.. p :. .: .. :...: Tan, moist, Silty fine SAND (SM), very loose to loose Perched water encountered at 3.5 feet — 2 18 ss 2 3 5 25 2 _ 5 41 Reddish Tan, moist, Silty fine SAND (SM) with clay to Silty, Clayey SAND (SC-SM), loose to medium dense 6-inch Fat CLAY (CH) lense from 7 to 7.5 feel 0. Tan, moist to wet, Silty fine SAND (SM), loose Wet from 11 feet Reddish Tan from 13 feet Dark Gray and With clay from 23 feet '. 3 24 ss 3 8 s — 4 20 ss 4 6 5 6 zo 5 6 20 21 ss ss 4 s 4 5 4 4 10 ° -- 15 7 15 ss aI a 4 15 6 0 8 16 as 2 3 5 20 5 9 9 20 ss 2 3 3 25 5 28 Light Gray, wet, Silty fine SAND (SM) mixed with Marlstone, medium dense 33 Light Gray, wet, MARLSTONE, dense :: ` 10 11 16 22 ss ss s 13 12 16 12 1s 1v 16 23 30 10 35 ; ; _10 38 Gray, wet, Silty fine SAND (SM) with Cemented Sand, dense to very Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample --_HA=Hand Auger Sample_ BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, a: c GET PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. G,...,o-.�. n,.�...-�.,.�,...�.. BORING LOG B-G PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-30-09 DEPTH TO WATER - INITIAL`: $ 1 V AFTER 24 HOURS: S CAVING> -C c 0 `0 N 1w a 0 E 5 �' 01 0 �' Description U � m Z rn m w E rn � d v N I- u, - o m m c, 0 > z o o o TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - s N-Value- 10 20 30 40 50 60 70 1z 40 dense With trace Marlstone from 53 to 59 feet 12 24 as 26 3 51 43 47 47 45 77 85 100 ..... ... ...... ... .. .. 5 100 -15 14 13 22 as 12 24 26 45 -20 14 20 Ss 8 26 33 16 50 zs 15 24 ss 14 25 P2 34 55 15 - 16 24 as 12 2e 25 60 20 -35 3so Gray, wet, poorly graded fine to medium SAND (SP-SM) with sill to Silty fine SAND ISM). very dense 17 22 as 16 41 36 32 65 rp 18 24 as 21 4B 50. 22 70 — 45- — 19 — 10 — as 50 50, 75 Boring terminated at 75 ft. El Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample -_—_. HA-=-Hand-AugerSample- BS = Bulk Sample *The initial orouridwater rearlino may not he indicative of the static aroundwater level VVOH - Weicht of Hammer PAGE 2 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM 0 1585, GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: JMT, Inc. --`-- cN,.:x..,•r•:,,,.,,,.. rmr.. BORING LOG B-% PROJECT LOCATION: Camp LeJeune North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MS' DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 DEPTH TO WATER - INITIAL': 12' AFTER 24 HOURS: 'S CAVING> -C. o�= N w L n ^y Description o N n m o n > 8 v a E N= 3 1O m y -' Z oo �' -\> TEST RESULTS Plastic Limit H Liquid uid Limitci Moisture Content- •W N-Value - 10 20 30 40 50 60 70 — 0 0 4 6 12 11 9f: 8 6 7 9 0 77 7. 15. 12 inches of TOPSOIL T Tan, moist, poorly graded fine to medium SAND (SP-SM) with silt, very loose Tan, moist, Silty, Clayey SAND (SC-SM) to Clayey SAND (SC) with silt, loose to medium dense Perched water encountered at 4 feel Mottled Light Tan -Reddish Tan from 4 feel Reddish Tan from 8 feet Reddish Tan, moist to wet, Silty fine SAND ISM), loose - Wet from 12 feet 13 Reddish Tan, wet, Silty, Clayey SAND (SC-SM), loose t8 Reddish Tan, wet, Silty fine SAND ISM) with day, loose Gray from 23 feet 28 Soil Void Extending from 28 to 29.5 feet 29.5 1Y1: °! 1 24 ss 1 2 2 T-1 I' I: .l. - ..: .: .:...:. :.. .. ........ . . �' ✓:':' ..... . "" 2 2a ss 3 i ' — 25 5 3 24 ss 4 6 s — 4 24 ss 5 5 20 5 6 24 24 ss as 3 s 5 4 4 0 4 15 . .. 7 -- 15 as a 3 3 1s 8 21 SS 34 3 4 6 — 10 20 6 9 20 ss 3 s 5 5 25 ..... 10 10 ss wOH woH woH 0 30 Light Gray, wet, MARLSTONE with Silty Sand, Cemented Sand, and Marine Shell Fragments, very dense 38 Light Gray, wet, Silty fine SAND ISM) with Cemented Sand, very — — — 9 5 10 11 18 — ss 1s 45 26 12 20 as — Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample -- - -- — - - --HA'='Hand 'Auger Sampte- BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. c GET ` BORING LOG B-% PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary(wash) DATE: 3-31-09 DEPTH TO WATER -INITIAL*: 8 12' AFTER 24 HOURS: -T- _ CAVING> L c r o w > w ��L c v 06 o E n m m �, o Description o n m a o Z m4�vv a> E$ c E w1 3'O o y m c v m z o o u v TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value- 10 20 30 40 50 60 70 -10 12 40 dense 43 Light Gray, wet, MARLSTONE, dense 48 Gray, wet, Silty fine SAND (SM) with Cemented Sand, dense 53 Light Gray, wet, MARLSTONE, very dense 12 22 ss 33 26 53 43 37 57 31 80 65 100 13 24 as y 17 P6 29 14 15 45 14 16 ss 16 22 15 12 . — PO 16 50 15 20 ss 14 26 31 39 25 55 18 58 Light Gray, wet, Silty fine SAND (SM) with Cemented Sand, dense E 16 24 as 14 15 16 25 30 60 20 63 Light Gray, wet, Silty fine SAND (SM), very dense Gray from 68 feet 17 24 ss 9 3s 44 50� — -35 — ss 18 24 ss 17 37 as ro 7022 5 — 19 — 14 -- ss 0450 50 50 <5 Boring terminated at 75 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample ----------- '- -- ---- -HA '= Hand Auger Sample-- BS = Bulk Sample PAGE 2 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30' MSL BORING LOG DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 B-8 DEPTH TO WATER - INITIAL`: 12' AFTER 24 HOURS: "- CAVING> L `o _ o m w oo TEST RESULTS Plastic Limit H Liquid Limit i d m a w Description a M o' o E Z a E$ a °' E 3 tO o y m u W 1 p E w �, p 0 to N w H m n Z\ Moisture Content -• N-Value - �® 10 20 30 40 50 60 70 30 0 0 12 inches of TOPSOIL 1 1 1 24 ss 2 3 Tan -Brown, moist, Silty fine SAND (SM), very loose to loose 3 — 2 2 24 ss 3 6 4 4 25 5 Light Gray, moist, Silly, Clayey SAND (SC-SM), loose 3 24 ss y 5 9 17.1• 7 2 _XX Light Gray, moist, Silty fine SAND (SM), loose to medium dense Perched water encountered at 6feet 4 24 ss e 5 t1 6 4 5 24 ss s 7 10 3 10-..... Light Gray, moist to wet, Silly fine SAND (SM) with trace clay, loose 3 6 24 ss 4 7 -- Wet from 12 feet 4 . . .... . :.. — — 4 Reddish Tan from 13 feel Xa 7 24 66 3 6 - 8 Light Gray, wet, poorly graded fine to medium SAND (SP-SM) with silt to Silly fine SAND (SM), very loose to loose 4 7 B 20 ss 3 4 3 _ 0 20 5 3 9 21 ss t 8 5 25 5 e 1 — 10 19 ss Y 4 Soil Void extending from 30 to 32 feet ..... :. ..: :...: :_ :. — 32 Mottled Dark Gray -Tan, wet, Silty fine SAND (SM), very loose 10 33 fii?: 19 Light Gray, wet, Silty f ne SAND (SM) with Cemented Sand and Marine Shell Fragments, very dense t t 24 ss 31 a6 77 -5 35 50' 36 Dark Gray, wet, Silty fine SAND (SM), dense to very dense ' 3 2i Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample — —HA _ Hand Auger amp a- BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. 4i GET G� BORING LOG B-8 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 DEPTH TO WATER - INITIAL': $ 12' AFTER 24 HOURS: CAVING> -C c wo n m E u m o Description n n c z �- > w �- °' N 3 tO m a z oo ` TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value- 10 20 30 40 50 60 70 .10 +2 40 Light Gray from 43 feet Mixed with Cemented Sand from 43 to 45 feet Gray, wet, poorly graded fine to medium SAND (SP-SM) with silt to Silty fine SAND ISM), dense to very dense 12 24 ss zs 36 47 39 45 63 33 63 58 92 2 14 13 20 ss 15 22 31 -15 45 14 15 ss 12 24 22 -z0 16 50 15 14 ss 16 36 32 -25 55 18 -30 16 16 ss 12 16 20 60 20 17 17 ss 16 25 46 -35 65 — 18 24 ss 19 28 37 10 22 70 _ — _ 19 — 24 ss 36 50 50• — 45 75 Boring terminated at 75 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample --HA = Hand Auger Sample- BS = Bulk Sample PAGE 2 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GET PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. .,�.*.rc..•,-..-.:.:,..,. BORING LOG N F-1 PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 DEPTH TO WATER - INITIAL': s 9' AFTER 24 HOURS: CAVING> _L c > -� a I 41 p -yn y u1 p Description u m m n o E Z m n w'o E o y a °' E in f- 3 tO ow- m a N Z\ oo ` TEST RESULTS PlasticLimil H LiquidLimit Moisture Content -• N-Value - 10 20 30 40 50 60 70 0 0 4 10 11 9 6.' 8 6 35. 39. it, 10 inches of TOPSOIL .. 1 24 ss 2 2 2 .. ... .. .. __ ... ... .. ...... .. 1; .. ) a :1 T j.: :... i...i :. :...:. :.. :. 2s — Tan -Gray, moist, poor) graded fine to medium SAND SP-SM with Y. Y9 ( ) silt, very loose ��/ 2 24 ss 4 5 4 2 Tan, moist, Clayey SAND (SC) with sill, loose to medium dense Perched water encountered at feet Mottled Light Gray -Reddish Tan from 4 feet ;I` " " " ...... :..r.. 5 3 16 ss s 6 4 Reddish Tan, moist to wet, Silty fine SAND (SM) with clay, loose V Wet from 9feet ! 4 18 ss s 4 20 Ei 5 15 ss 2 2 3 3 10 10, Mottled Gray -Reddish Tan, wet, Clayey SAND (SC) with silt, loose zi =^'. t i ;,: ,,1; 6 7 16 — 12 ss _— ss 3 s 4 4 4 6 s — Reddish Tan, wet, poorly graded fine to medium SAND (SP-SM) with: silt, loose, — 15 Boring terminated at 15 ft. 6 10 20 5 6 25 0 .5 10 10 Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample - - "-----'------------- --__HA=Hand Auger Sample_.. BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the Field in general accordance with ASTM D 1586. 6 GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. r—^^7 PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-9 DEPTH TO WATER - INITIAL`: S 9 AFTER 24 HOURS: F CAVING> t u °' o TEST RESULTS Plastic Limit H Liquid Limit "'8 a m n v Description n o- o n> a 3 tO m wo E o n z N m n z" Moisture Content - o N-value - 10 20 30 40 50 60 70 0 0 4 inches of Topsoil WEH 1 11 SS WOO WOH O .3 Brown, moist, Silty fine to medium SAND (SM) with organics, Very Loose woH woH 2 11 ss w2 2 25 5 4 Light gray, moist, Silty Clayey fine to medium SAND (SC-SM), Loos :: 3 22 SS 2 3 4 7 2. 2 7 Tan, moist, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose Iai ti !�:l l: �.rr} 4 18 SS 3 4 Tan, wet, Silty fine to medium SAND (SM) , Very Loose 8 - 5 24 SS i z 4 5.1 ` . 11 `:...: 20 0 10 Tan and orangish brown, wet, Silty fine to medium SAND (SM) with trace Clay, Very Loose 1.... 6 22 SS 3 z 2 4 :\ : \ 4 1 l..rf !'t ti: ii. 2 \ \. Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Sllt, Loose z 15 .i a: c r 1:I;Li 7 18 SS 3 6 G :\ 15 full: i a:fl 1 is r1. Ix C r 4 1';Ial of il. 10 I:I:ii 8 20 SS 6 \ 5 fltll: I :I:[I I:X Lr \ \ 23 N 1 1 \: 5 Gray, wet, Fat CLAY (CH) with trace SAND, Very Soft 9 23 SS 1 1 0 I 6 25 28 3 0 Dark gray, wet, Poorly Graded fine to coarse SAND (SP-SM) with trace Silt, Very Loose I?� e i r� 10 23 SS 1 1 2 10 0 Boring terminated at 30 ft. -5 5 T-10r] Notes: SS = Split Spoon Sample ST = Shelby Tube Sample —HA -Hand Auger Sample BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Leleune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-1 U DEPTH TO WATER - INITIAL': H 8 AFTER 24 HOURS: T CAVING> L. c- C L1.2 U y m 3 o TEST RESULTS Plastic Limit FH Liquid Limit m n m o. v Description n E o z 6 j o f °' 0 `D m V Wo E o d c� m rn ~ m o. z o Moisture Content - • t� N-Value - 10 20 30 40 50 60 70 0 8 inches of Topsoil 1 1 23 SS p 3 .6 Brown, moist, Silty fine to medium SAND (SM) with trace organics, Very Loose 2 2 2-5 2 21 SS 3 5 Light gray and orangish brown, moist, Silty fine to medium SAND ISM) with trace Clay, Loose 3 z 3 21 SS 3 5 2 2 7 % j : 0--- Light gray and orangish brown, moist, Clayey fine to medium SAND..-. (SC), Loose 4 24 SS 3 < zo Tan and orangish brown, wet, Silly fine to medium SAND (SM) with' trace Clay, Loose ' S 21 SS a 3 3 6 / v 1 0 3 3 Tan and orangish brown, wet, Clayey fine to medium SAND (SC), Very Loose 6 24 SS 2 2 4 1 3 Orangish brown, wet, Silty fine to medium SAND (SM), Very Loose 15 4 7 18 SS z 4 1 18 2 16 Oran Ish brown, wet, PoorlyGraded fine to medium SAND SP-SM 9 with trace Silt, VeryLoose ( ) Sin. <?F! t 8 16 SS 2 6 2 rl a: 1 is i. i dCt� itl 5 l i l l• 9 18 SS 2 25 yti .i bitr :rtf t L9E i'r.L r 28 Gray, wet, Poorly Graded fine to coarse SAND (SP-SM) with trace Silt, Very Loose ! CX(r ' ^� i i �?�� 10 is ss OH WWOH woH 0 10 10 woH Boring terminated at 30 ft. -5 35 io Notes: SS = Split Spoon Sample SS = Shelby Tube Sample __HA-= Hand' Auger Sample . BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G ' COMEM3fto c,-....; .r.-.�....•.w. rK.•, BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-11 DEPTH TO WATER -INITIAL*: S 9 AFTER 24 HOURS: a _ CAVING> f- o E 0 N 2> w w oo TEST RESULTS Plastic Limit H Liquid Limit > y` d v m a m Description o. m n o E E I a m E cD o v m w o E a, o c� Z rn N N m n Z\ Moisture Content-o N-Value - 10 20 30 40 50 60 7 0 0 4 inches of Topsail 2 i 1 24 SS p 4 .3 Brown, moist, Silty fine to medium SAND (SM), Very Loose 2 Orangish brown, moist, Silty fine to medium SAND (SM), Very Loosc 1 2 22 SS 2 3 25 2 5 5 Light gray, moist, Sandy Lean CLAY (CL), Medium Stiff 3 23 SS z 3 2 2 7 ry ? Light gray, moist to wet, Silty fine to medium SAND (SM) with trace to little Clay, Very Loose to Loose ': ' 4 24 SS 4 5 2 20 . 5 20 SS 2 4 _ 3 3 6 24 SS 2 4 4 3 ws 2 i•epi 15 Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Very Loose to Loose ri:tt: i;r r } 7 22 SS z 2 4 A rf.f i 2 i r1:L1: tYt1. rr. t i 2 t0rr.i! 8 21 SS 2 5 6 20 r�.r1. 1 CFt1 ':rt 19:r L :r•ti 3 5 t3fff 9 18 SS 3 zs 9:rt •1° i ). B 1a rt rXC1: i:f r l 1:C[r 1 0 'I is i:i 10 19 5S 1 2 30 i:f t' t 40 Boring terminated at 30 ft. 5 35 -10 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample ------ - ---- - ---- — --HA = Hand Auger Sample— BS = Bulk Sample PAGE 1 of l Standard Penetration Tests were performedin the field in general accordance with ASTM D 1586. GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. "® PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G cR,.,.-�a.o-..•.,-a. x„,r BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-12 DEPTH TO WATER -INITIAL': 8 10 AFTER 24 HOURS: T CAVING> L c ' y `` L -' -' o t W o > a °' `O m —' oo `" TEST RESULTS > d w v w in Description m F E Z n E$ E o v j Plastic Limit H Liquid Limit g o E o N rn rn I- m n Z\ Moisture Content -• w N-Value- 10 20 30 40 50 60 70 4 Inches of Topsoil 2 1 24 SS 3 6 .3 Brown, moist, Silty fine to medium SAND (SM), Loose 3 j 2 Light gray and orangish brown, moist, Silty fine to medium SAND a% (SM), Loose 2 20 SS 4 7 23 : • 4 Light gray, moist, Silty fine to medium SAND (SM) with little Clay, Very Loose ` 3 22 SS 3 z 2 a 25 2 3 8 Tan, moist, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose r7ss. .uccr 4 23 SS 2 4 .11 r1: f u: il. rlrrr 7 ' 5 19 SS 2 3 4 20 1 10 Tan and orangish brown, moist to wet, Poorly Graded fine to mediurr1 SAND (SP-SM) with trace Silt, Very Loose to Loose :I H ir. E i n, r 1: 6 24 SS 3 3 3 6 ;y 2 ;r 4 [1 2 1;rrr 7 20 SS 2 4 15 1 1i.f1. rl(r r u:ol 2 j 1:L1! 1'41. iteriV t 2 1':lirf 8 19 SS 2 4 to 20 2 rXr1 CJ:LC 23 ... Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM)'I:: with trace Silt, VeryLoose f f ra:r1: 9 23 SS 2 1 3 u:ri. 4sn 5 I+ii i:F f j I;C t l 2 10 24 SS 1 1 0 0 ? 41 1 10 Boring terminated at 30 ft. -s Notes: SS = Split Spoon Sample ST = Shelby Tube Sample ----' —"'--------------- —�------HA'= Hand Auger Sample BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GET N,,....r.r.w.....,a. r,..m,. BORING LOG BMP-1 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28 MSL DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER - INITIAL`: S 8 AFTER 24 HOURS: aS 4.8 CAVING> L m 1w n d p E n m v o Description o. E o Z cn n o E rn E °' rn �' tO v m a m Z o a \ TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - o N-Value - 10 20 30 40 50 60 70 0 9 8 8 1 1 1 2 inches of Topsoil i 1 2 24 za SS SS 3 ° 4 4B 4 4 r,. [s? o - S u�;t .1 Dark brown, moist, Silty fine to medium SAND (SM), Loose Grayish brown, moist, Silty fine to medium SAND (SM), Loose Estimated SHWT @ 4-feet below site grade 2 2 s 3 23 SS 4 3 3 Light gray and orangish brown,. moist, Silty fine to medium SAND (SM) with trace Clay, Loose 1aEEl rr.u: 4 24 SS 3 n Tan, moist, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose 20 Gray, moist, Silty fine to medium SAND (SM) with some Clay, Very Loose 10 Gray, moist, Silty fine to medium SAND (SM), Very Loose 12 Gray, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Very Loose 9: Fi. 1a;rr !y(1: ixri 5 6 24 24 SS SS 1 o t p 2 Ip 4 1s 7 20 SS 1 1 1 Boring terminated at 15 ft. 10 20 5 z 0 1 -5 10 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample ------- ----- --'--- '-—"--HA='Hand Auger Sample BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GETPROJECT: ` • • " BORING LOG BM P-2 P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Baring Location Plan SURFACE ELEVATION: 28 MSL DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER - INITIAL': $ 8 AFTER 24 HOURS: 8 5.29 CAVING> L o= WE J o Description c w E Z ti E$ N w E w m a m > z oo u e TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - • N-Value - 10 20 30 40 50 60 70 0 0 7 8 6 7 4 16/f 7 4 inches of Topsoil 1 24 SS 3 3 311.2 6 l %s j is % .3 Brown, moist, Silty fine to medium SAND (SM), Loose Estimated SHWT @ 4-feel below site grade 4 Light gray and orangish brown, moist to wet, Silty fine to medium - SAND (SM) with trace Clay, Very Loose to Loose 1 Light gray to tan, moist, Poorly Graded fine to medium SAND ($P- SM) with trace Silt, Loose to Medium Dense 25 " 2 3 23 SS SS 3 ° 4 3 3 3 2 5 - 4 23 SS 3 4 4 20 r �: i is iir It a. it15 . t1 la tt : ipa 5 8 24 24 SS SS 3 3 5 5 y 10 4 7 24 SS 3 4 4 t5 Boring terminated at 15 ft. s 1 20 5 25 3 1 5 35 -10 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample ---"---------- - --- -- -- — HA: = Hand Auger Sample— BS = Bulk Sample I *The initial aroundwater readino may not be indicative of the static oroundwntpr In vni WOH - Weinht or Hammer PAGE 1 of 1 Standard Penetration Tests were performed in the held in general accordance with ASTM D 1586. GET �.,,,•-,..r..-.,_,,.,r.:s, BORING LOG BMP-3 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Go., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30 MSL DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER -INITIAL*: V 13 AFTER 24 HOURS: T 9.875 CAVING> L P �, w L d w m o E S m �, o Description o. 2 l7 n o E z rn o- > E$ n w E N I- 3 tD o v m n Z\ o TEST RESULTS Plastic Limit - H Liquid Limit Moisture Content- o N-Value- 10 20 30 40 50 60 70 3 5 6 7 4 6 4 4 2 inches of Topsoil 1 20 SS 1 z 2 4: f ' t J 1 s. .1 Brown, moist, Silty fine to medium SAND (SM), Very Loose Brown and tan, moist, Silty fine to medium SAND (SM) with trace Clay, Loose Estimated SHWT @ 6-feet below site grade Light gray and orangish brown, moist, Silty fine to medium SAND (SM), Loose Oaangish brown, moist, Poorly Graded fine to medium SAND (SP 8 SM), Very Loose to Loose _ 2 19 ss Z 3 3 2 5 1? i f rz,r1� l'1f i1.` aY(f 1}ti i ffj of i1. I Sa i '!T i itlL' i r 3 4 5 20 22 24 SS SS SS 3 3 a 3 z 2 20 10 4 6 24 SS 3 3 7 24 SS 1 q 2 15 15 Boring terminated at 15 ft. 6 10 2 s z 3 10 35 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample --- -- - ----- —" HA -='Hand Auger Sample— BS = Bulk Sample PAGE 1 of l Standard Penetration Tests were performed in the field in general accordance with ASTM D 1566. GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. - BORING LOG BMP-4 PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30 MSL DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER - INITIAL': 4 13.5 AFTER 24 HOURS: 9.92 CAVING> - c 0 wo E o Description u n m o a o E Z rn y n' E$ m o' °' E I- 2 `O o v m o. m m z o u \ TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - • N-Value - 10 20 30 40 50 60 70 0 0 0 4 5 6 11 7 7 7 17. 2 inches of Topsoil i 1 23 SS 7 z 2 " % I: a t / I a - �! .1 Brown, moist, Silty fine to medium SAND (SM), Very Loose 2 Brown and tan, moist, Silty fine to medium SAND (SM) with trace Clay, Loose 4 Tan, moist, Silty fine to medium SAND (SM), Loose Estimated SHWT @ 6-feet below site grade 2 3 21 19 SS SS z s 23 3 °\\ z s 25 4 20 SS e s Light gray and orangish brown, moist, Silty fine to medium SAND (SM) with trace Clay, Loose to Medium Dense 10 Light gray and orangish brown, moist to wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose Z.l:r.tl .j: rt: 'i:e i t r l i titi:+.l,1 .'xtv 5 6 21 24 SS SS 4 j 2 3 4 4 20 10 4 3 7 24 SS 3 3 4 5 5 Boring terminated at 15 ft. 6 10 20 s 25 30 10 .5 35 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample _----.__--_-.HA-='Hand AugerSample_ BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, EIEVATIONINFUT d' N LU J_ w W LLL o O cJ L s d LL N rr J � � cG C7 p I. N m J N � o °z w z ZLLJ r C� u............. .... ......... .� u. ......... ......... .�•�•J mUuj 3 Z rvry rvn �n nv ry r,ry n ry n I V z� U U v 3 2 Q2gQp pp$pJ pSppp 5533 35ry nv n nn n n � _ n mm>.. )... .. ............. - 1Y` N N a v N or U a ELEVATIONI,NFf:L']' W m — LLJ W J < _ O ro a a> v m a_ O Q a C O W � W Q < p �ffi a O z w o U LU � W z z z z p rvm ry vw an nv 'a 'e N N 0' s 2 s z 2 Z E Z i a N U i. U � 0 � N N � a p o N U t(n U N lA:yy NI NO/1YA{ly APPENDIX IV ADDENDUM NO. 1 TO THE ORIGINAL FEASIBILITY STUDY REPORTED ON THE DATE OF FEBRUARY 19, 2010 (GET Project No. EC09-106G) GET C. 0,l a •Fnoim,nvrn>rt•Rstinc TO: JMT, Inc. 272 Bendix Road Suite 260 Virginia Beach, VA 23452 Attn: Mr. Timothy Gaffney, P.E. February 19, 2010 RE: Report of Subsurface Investigation and Geotechnical Engineering P-1310 Pre -Trial Detainee Facility MCB, Camp Lejeune, North Carolina GET Project No: EC09-106G Addendum No.1 Dear Mr. Gaffney: Pursuant to your request, G E T Solutions, Inc. has completed our supplemental subsurface investigation and Geotechnical Engineering analysis for above noted project. The purpose of our supplemental subsurface investigation was to further delineate the presence of subsurface voids encountered during our original Standard Penetration Test (SPT) boring program and noted in our "Report of Subsurface Investigation and Geotechnical Engineering" issued on the date of April 17, 2009. Additionally, our supplemental services included a seismic site classification analysis. This report is provided to serve as a summation of our supplemental field exploration services as well as the results of our Geotechnical Engineering analysis. The supplemental subsurface investigation and geotechnical engineering services for this project in accordance with G E T Solutions, Inc. Proposal No. PEC09-179G, dated May 19, 2009 and subsequently revised on the date of May 29, 2009. Authorization to proceed with the services was provided in the form of subcontract agreement (contract N40085-08- D-1412, TO #1) authorized by Mr. Timothy Gaffney, P.E. with JMT, Inc. on January 12, 2010. Project and Site Discussion As indicated in our above referenced report, subsurface voids were encountered at the location of our previously completed SPT borings designated as B-7 and B-8. These borings were performed at the locations established by JMT, Inc. and were generally positioned slightly west of the west building wall line. Additionally, the results of the remaining previously completed borings performed within the vicinity of the original building limits (designated as B-5 and B-6 which were performed east of the east wall line) did not indicate the presence of subsurface voids. Subsequently, it was our understanding that the building location was shifted slightly to the east in an effort to locate the building outside the limits of the encountered subsurface voids. 504 East Elizabeth Street Elizabeth City, NC 27909 • Phone: (252)335-9765 • Fax: (252)335-9766 --- - --- ---- ------ info@getsolutionsinc.com— -- -- - —-------- -- Report of Subsurface Investigation and Laboratory Analysis P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: EC09-106G Addendum No. 1 Field Exploration 2/19/10 In order to explore the presence of potential subsurface voids along the western portion of the newly established building limits, a total of three (3) 30-foot deep Cone Penetrometer Test (CPT) soundings (designated as CPT-2 through CPT-4) were performed at the locations designated by representatives of NAVFAC. Additionally, in order to perform a seismic site evaluation, one (1) 36-foot deep CPT sounding (designated as CPT-1) was performed within the approximate center of the newly established building limits. This CPT sounding was limited to a depth of 36 feet below existing grades as penetration refusal was encountered at the termination depth. Shear wave velocity testing was performed at the location of CPT-1 from the existing surface grade elevations to the termination depth of 36 feet. The results of the CPT soundings are provided on the attached CPT Sounding and/or Shear Wave Velocity sheets. The CPT sounding locations were established by representatives of NAVFAC and subsequently identified in the field by G E T Solutions Inc. personnel with the use of a Global Positions System unit based on the coordinates and dimensions indicated on the project site plan provided by The Spectra Group. More specific information regarding boring locations and depths is provided in the following table (Table I — Sounding Schedule). Table I — Sounding Schedule Boring Boring Depth � ) Boring Location(l) Number (feet) CPT-1 36 Approximate Center Building CPT-2 30 Approximate Southwest Building Corner CPT-3 30 West Wing; Approximate Center of West Wall CPT-4 30 Northwest Wing; Approximate Northwest Corner Note (1): The boring locations noted above are considered to be approximate and are referenced from the newly established building limits. Subsurface Conditions Based on the results of CPT soundings (CPT-1 through CPT-4) performed to depths ranging from 30 to 36 feet, subsurface voids were not encountered at the newly explored locations. Accordingly, the subsurface improvements, as indicated in Section 4.7 of our "Report of Subsurface Investigation and Geotechnical Engineering" (dated April 17, 2009; GET Project No. EC09-106G), do not appear to be warranted at this time. GET Report of Subsurface Investigation and Laboratory Analysis 2/19/10 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: EC09-106G Addendum No. 1 Furthermore, the CPT soundings indicated that the subsurface soils at the recently tested locations are generally consistent with those encountered during our SPT exploration procedures. Accordingly, it is our professional opinion that the remaining recommendations, excluding the subsurface grouting improvements, presented in our above referenced report remain valid. Additional subsurface exploration and Geotechnical Engineering services, as indicated in Section 5.3 of our "Report of Subsurface Investigation and Geotechnical Engineering" (dated April 17, 2009; GET Project No. EC09-106G), are recommended to be completed once the Design/Build team has been selected in order to substantiate the recommendations presented herein and/or in our previously referenced report. Seismic Design Recommendations: The results of our field exploration indicate that the average shear wave velocity recorded in the upper 36 feet (refusal depth) was about 1,330 ft/sec. As such, the project site is within a site class'C' in accordance with Table 1613.5.5 of the 2006 International Building Code. The comprehensive results of the CPT soundings are provided on the attached CPT Sounding and/or Shear Wave Velocity sheets. We trust that the information contained herein meets your immediate need, and we would ask that you call this office with any questions that you may have. Respectfully Submitted, G E T Solutions, Inc. Gerald W. Stalls Jr., P.E. �0�o CARO���.,�� Senior Project Engineer �,.'pFESs/Oy • q NC Reg. # 034336 a� SEAL v� ` 03433SA Camille A. Kattan, P.E. ; • t.\ CAR() SEAL 014103 4_1 i�/e...k `F1 Principal Engineer INC Reg. # 14103 Attachments: CPT Sounding and Shear Wave Velocity test sheets (CPT-1) CPT Sounding test sheets (CPT-2 through CPT-4) Copies: (3) Client Solutions; lnc. CAROLINA DRILLING Bridger Drilling Enterprises Inc. dba Carolina Drilling 114 Chimney Lane Wilmington, NC 28409 910.799.0493 w 910.799.5945 f 910.512.4600 m carolinadrilling@gmail.com — — CAW ,N CPT Analysis Results All information obtained utilizing Geoprobe® 6625 CPT, GeoTech Cones, and CPT Pro by Geosoft. Data interpretation to be exclusively determined by the client's engineering staff. e2 Classification by Robertson 199D Clean sands to silly sands (6) — Silty sand to sandy sill (5) < i p Clean sands to silty sands (6) G Clayey sill to silty clay (4) Clean sands to silty sands (6) _Silly send to sandy sill (5) _Clean sands to silly sands (6) Silty sand to sandy silt (5) _Clean sands to sily santls (6) Silly send to sand sill (5) L— .Clean sands to silty sands (6) Remand to sand iatAId11 Ctieaa sands to M y saria5 (6) Silly sand to sandy silt (5) Clean sands to silty sands (6) Silty sand to sandy silt (5) Clayey silt to silty clay (4) 'Silty sand to sandy silt (5) Clayey sill to silty clay (4) Clays; clay to silty day (3) ` Organic soilsyeats (2) Clayey silt to silty clay (4) I LClean sands to silty sands (6) CAROLINA DRILLING LI L IJ U LI Lllll U LI III U LI'LDlIJY'dlt IVTITrn In n TITn n nTIT n n rITIT n r I' It I IJ ULI L IlU U LI III U ULI11J Ut ITITII In n LIT ll n n TIT n rI rl I In r uu IJIIII I11111 rJiinnTrtnnnr'iTnnrlmnr uuLluul i......l.... .. TI Tn n n TlTn n nTIT Ii rl rlTli n r NUJuvavuuv114 It, 11 v1 T.TII r. TI TI"Lir.. I ..lr ICI IIIIII 11111~~III~ IIII~I lTlili it T17 lj_____ FI -iiil ITi .hit N N«I,NIII i-I TIT 111+1,NI n111u111U1 I I III Illnulll -IT)er____ _ _IinT....... 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JII IIIIIJIIiIII TI -IIII III1II111 V111U V LI 111 U UlJ1U 11 I Iiiii I.n U.....UIIIII I n T1Y n T17 n F rl T I,NIT n f I LLLU UU Ill 'I U Ir L11111 LI Ut IIIIII ...........................1 I II 111 n n T lT n n rl T 11 n nrIT lY nr LI LIJ U U III.J U U III U U L:I:lIJ lull I II rl In n Ill n n rl TIT n n LIIIJ nr LIIUULIIV ULI I ULII 1 nT17 111117''1 T.Tn 1IITnnr ILILIJ U LI LI11J a LI111 u ULIIIJ u4 IIIIIIIIIIIIIII It'',I, It 1111111111 I TITII n n TITn n !IIII Il n !IIII n! I LIIIJU LI L111J ULI L11u LI Lllllul Co.,, Nu 42211 Proled: T'Iaereatcmxl; 10 Sleeve area Icmz): IN J_1_L J_L_1_J_L J_1_L 1 l-r-1-1 1--1-71-7-r -- T-I-I-r-I-i-rT T-r -I- J ___ I L_____ H-a-LJ _I J I J _I_T __I_ i__ -___1_ I II I I I - r- _1 _1_1_I_1 _1 I 1 _ 1_ L J_ L_I_ J_ L J_ 1_L n- T-ri-f-I-1 -f -IT-r J_1_LJ_L_I_J_L _I_1_L __T-ri-r-I-I -r --r L 1 1I 1-1-r i-r-i 1-r-1-7-1 I r 7-ri-i-ri-r �-i-r JI 111 I_ -_I___F_ I 1 _L J_ L_I_ J_ LJ_ I I 1-T-r'1'T l'I-fYT'f i'rl f I f T-f J_1_L J_L_I_J_LJ_1_L i -r 1 1 -r-ri1 -r -1-11 11 I-T-Y i'T -ri -r i-TT 1 I IL I I I -I T11 -ri-r-(i-r-1--r _____ I_ 1_ 11 J_ L J_J_ L J_1_ _1 Jr J_II J_II l_L 1_ L J_ L_I_ J_ L __ 1 _L - I' II _1 r 1 I IL 7_1l_T-I-I_r 1-1_1 _J _I _L_l_J _I _L l J _I L L J _I_ 1 I I _T_i__I- _r_r_i__i__r I _ 1__I__T_ r_ I _i____ I_i_ J ____ _T_I _I _r_T_I _I _r J I L J I I I I I I I I I it I _I ______I __ _ lz J__l__ L _ I_J__I__L jt _ 1J J__L_ L_ 1_ J__I__L I L_1_J__I__L =J�1'J_i____r_ r_ 1__1__1 I�I _T�i__I__r_T_i__r_r _T _(i__i__T_T_i__i _r _y1__II__f_f_ 1 _J, _= _ 1 _J__I__ L_ 1_J_J__L T l 1 _JI_-L - T-l -r-T -i -r 1_ J__I__ L_ 1_ J__I__L - T-n- -r -T -n r -i-l--i-'r-T-'1"i T I I I I -T—i--r-r-T--r -r-r I I 1 1 1 1 1= L_1_J_L I _r _1_J _ _L_1_J _I _L I I -I r-T-I -I r _1_J__I _L _1 _J__I__L _L_1_J__I__L _T_i ..._r_T_i _i _r trail detainee site 2.CPT Classification by 0 0.9578544 1.9157088 2.8735632 3.8314176 4.7892720 5.7471264 6.7049808 7.6628352 8,6206897 9.57 R.booteal 1990 Clean sands to silty sands (6) a 1_ __.__ _____L___�-L_____1_____J_____J_____J_____J_____J_ _Silty santl to sandy sill (5) _ 6 2: ____=r_r_____r_________________ ______-_____--- ____ I__-___ _ L _1 _1 _1 J J _ I V Clean sends to city sands (6) ❑ q - _Clayeysilttosillyclay(4) - i_i_i i_____i_____ I______I____________ - _ r_____r_____ T___ —r. T_____ -I_____ --___-__ �______�______ _____L__ Clean sands to silty sands (6) 7 L_____ J ____ J______1___________--- _____ _= - - - - - -I --- c_".__- i_____�-- Silty sand to sandy silt(5)___________a_____ Clean sands to silty sands (fi) -Silty sand to sand silt (5) 1 - _�=- I I 1 ____________I______ _ ' � I -� '� � �----- - - - -- i. _- - _I _ - --Silty Clean sands to silly sands (fi) sand to sandsilt(5) Clean sandsto silly sands (fi) 1 ` _ 1 _ __ 1 _ —_� _-_______J_____J______'______ __ _____ _____ ______—__t-- _____ __________________ __ _' ♦ ♦ ____J`s�___y illysantlto to a' silt eansantlstosysad (6) 14- - ; --_-- � � ---'�-'--v- ---------------- I_= _ 1 1 - n-.......--may__ ____ _____--- ____--- _____ _________t____________________ Silty send to sandy sill (5) 1 ` 1 -_ ;- r __ _________________________ Clean sands to sit sands 1 _ — _ _____r___y._--L___________-I_____--- ____--- _____ Silty and to Sandy silt(5) 22- _____L_____L____-1=_—_yy.,_=_W. J.__a._J_____ J______I____ ____ 2 : 1__�---r-- _ _ _ 24 _____Ls._--i—__L_____J_____J_____ J_____J_____ J______I______ Clayey silt to sit clay 4 Yv N Y 2 - .-�—_._L_____ 2 _____L_____-_____,_____. 4_____ -______I______I______ _i,�_ — :Silty sand to sandy sill (5) _-� Clayey silt to silty clay(4) 2 . 2 _____ I i 1 --.. - Clays, clay to silty clay (3) Organic soilsyeats (2) 3 31 _______I______1______ _______r___________T________1______1__________________ 1 L, ' ' ' 3 3 - _______________________ ________________'______ I 1 1 Clayey sill to silty clay (4) _____.___v_"r_______________________y_____y______1______I______ Clean sands to silty sends (6) 3 __________________ _ _ _ _ _ ___'_.. 1 r _____♦_____,_____♦_____y_____y____ y_____.,r______I________.___._ _-=. ______J_____ i______� __-_____ _______ 3 __._--- ____--- _____ 1 41 _L _L _L _J _J _J _J _ i _ 1 42- q _L _L __1 _1 __J _J _J_____I _I______ I I 44 . -T -T -i -T -1 -1 l 'I q _L _L _J _J ___ J J _ _L-__ _a_____J_____ J_____ J_____ J______I______I____ 4 - I 4 1 1 1 � 1 1 - - - - - - -I 5 _______ __________________ _________--- ___________ ____________________________--- _____ 1 5 _ 1 1 1_____!_____!_ ___J_ ____________________ _______ _ _________ 1 1 1 1 ___ 1____ ___ ____J____ ___ __ ____ 6 __ __L _L _1 _J _J _J _J _ __ _ 61: _r _r _r _, _, _� _1 6 _L _L _l _J _J _J _ I _ I _1______ 1 1 1 1 1 1 1 1 6: _--- _____ 64 _L _L _l _J _J _J _- _ _____L_____L_____L__________J_____J_____J______1______1______ 1 1 1 8 - 0 _____L_____L_____L_____i_____J_____�_____�_____ I 10 20 30 40 50 60 70 80 90 11 qc 117V21 Location: Position: Gourd level: Test no: to X: 0.00 ft. V: 0.00 ft 0.00 001 i Project ID: Client: Date: Scale: zna(2o10 1 :100 CAROLINA GRILLING Tune 27 iip 10 Protect: Page: Fig: 1/1 areaa Icm21: Sleeve area tcn¢p ISO File. ore trail detainee site 2.CPT X ) N X ) N N tI N tK/1 N N N N V) d d d HHHIIIHHHIII LLLLLLLLLLLL r I r P I i � � r p I i i I li I I I I i 1 r 1 1 I _1 _ r r 1 E 1 - I , r r , • ' i I I, vi rd n m m c^ •- •- (w) 41daC) m ) m ry W A A IJ A A A W A A M A A N N T O) T W W A W M A M m m m m m n A WA, (P 0 Co rT m m 0 0 0 0 M. 0 O 0 0 0 0 0————— — — — — — —— M C) M M M M M M M M LLLLLLLLLLLLLLLLLLLLLLLLLLLLI 0 0 0 O n (w) y}dap LL L a C. qc We] fs IT/ft^21 .21T/ft^21 Su(gI,WL) [ a] Classification by 0 on` i _- . ,. IlnnnliIl1IllllIl11(1W I,'rIlI�fiIIII1IIIIIII1I1II1 I1ni1IInnnIlnlInn111lUI1ll1l1In1I1lnI1 .n1In1lIullllln11ul111lHIlHll1l»In1I1lnI1 3-1 2 OO---.W0 EM--_---_-- 9- 41IlII1IIIIIIIIIIIl'IIIII'IIII�rIII 2'--1h---3m'--- 1IIIIrI1IIIIIIIIIIIIIIIII1IlIl pJJJJ";r--J8I1III1l1IIIIIIIIIIIIIIIIIII 4,r�!,',Y,1,11IlIIllllllIIIlIIlIIIlIIlII1lIIlI 1lII�IIllllIIIIIPlI1llIIlIIIlIIIIlII 5I1lllIIIl11llLIILlIl1I1IrIrIrl-II'rlrIr �1 MInlu1nnIlf1lllln1111lI11l1l1In1I1lnI1 1nl1IlInlIllIll111IlHI1l11l1Il1I1lI llIllIlllln1I111lII1nlIIllI1llI1 I11III1lrl11IIIIIIIIIIIIIIIIIIlII'IIIIIIIIl ml nl1IllIlnIl111ul4.1 nllllIllllill1l1111lulnn riTL1ilIltrlllulIllIi111lII 11IaulInllllu1l11ll11Ill1lI1I1lI1 niiIuL1trinlIllIlllIH111lIIlIlIIi1lI1 _-'_--__----:: _---JJ-�-----6 _- 1III�rIIlllIIIIIIlIIllIIIIIIlIl'IIIIIIIl'III IIIIrIllIIIl1IllIIIIIlIl'IIIIIIIIIIIII --�"�-1_-0jI --!J-_------'3 --___-'-- Il II1Ii11jllIIII1iIlI1I'IlII)'II1IIIIlIIII IlrtHIrlIllllll111Il1IlI -_--_IJ--2 --_- Km(InlIIn4llrnIlHHH iiJJrI11IIllIlllI1l11lIIll1lI1I1lI1 JIjl IIIIIIIlIllIIII1lI1lI _-- _-_--_----1 - -- -_-__------ ---_ tii`�llInllIrlIIII1I1Il rrIIrIr�rIIlllIIIlI-IlIIllLIIIILlIl'IIrIYIlIrIr --_---_---r9 -_-_---_-5M lIIII1I1lIlLI1III1y lIIII1I1lIsII1lI11I1 _- J,Y1l1IuulInlnnulIl111 J,I1l1IIIllII111lI1l11lI1I1lI1 1IlInI1I1lI1 )Ill11lI1I1lI1 irrnriL)lllil1InInInn111lIiIi(1I1lI1 Ill1l1In1Il1lnI1 IHl11In1I1lnI1 IllII1I1I1 I11In)I1lnI1 I1lIlI1lI1 Iry;.illlllllluI1I1l1Il111IliIIlIl 11I1I1lI1 lI1lI111 III1I1y IIIIIIIII ---7 ,l1ll1lIllllllll1l1111lI1ll ,,llll1ll1Ilt(n ,Lul1llIlllnlll1lln1111lI111I1I1lI1 ,'.rIu1Il1nlIlll11l111lIlll1lI1I1lI1 --_----__ --®- �t�ni,iIllllIlnlL1n1InIII1llIn.n 1I1 r(urlll11IiIinu4. 11n1 - 1 its IMPaj is lT/fi^21 u2 IT/R^21 Su(gLWI-)1MP.1 Classification by _ - Oc — 41 1IIrIlI 3-1 0 H_.--.11n'--pp---0.ffi-9- llll1l lnl1ln1111111u In1111lI111ll1 nlll1llIllu1lurl1llnll1lllul1l i�Il(1l n1111lu s1(lI1ll - --------'---2rIIIlII ------7 ----21rIrrlI -- -- ----51rrlrII -I--31IIlIII -'-T4T1lII -l--61IlIII lnu1rIll1n rrIIIn TT,7It11I -5A'-®----7M1-rIIIII - lnl11lI1111l 1l1l1llnll1llllul1unlnnll1I1l11ll nnLIl11.Ill11lnIr1nnl1 -'---- - - -00 —0 --3U--4IIIIIII f�• qc IMPa1 fs IT/ft^21 u2 ITW2I Su(gt,WL) IMPa1 Classification by p Robertson 1986 Sandy sill to clayey sill (6) —_ Silly send to sandy sill (7) c c Sandy sill to dayey silt (6) Silly sand to sandy sill (7) Sally silt l0 dayey all (6) Silly to sand sandy sill (7) Sand to silty send (8) 1 Silty sand to sandy sill (7) Sand to silly sand (8) 1 Silty sand to sandy sill (7) 1 Sand to silty sand (8) 1 Silly sand to sandy sill (7) 1 Sall to silty and (8) Clay (3) — Silly send to sandy silt (7) Sandy silt l0 clayey silt (6) Silly sand to sandy silt (7) Sand to silty sand (8)3. 0 0 1 2 3-1 0 1 2 3 9 5 6 7 qc 1,1'7V21 fs IT/fl^21 u2 ITW21 Location: Position: Ground level: Test no'. Jacksonville, NC X: 0.00 ft, Y: 0.00 it 0.00 001 Project ID: Client'. Date: Scale: {I 41 GE75ouuions v25/2o10 1:50 CpNOLIN0. 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M C W _ W W E A L c N o 0 0 0 0 0 0 0 0 0 0 0 0 0 N u W W W W W W W W W W W W W W w (A L Yl L U N N r N N CO N N (O O N Q Q M r Y ` 1 E o m o u, in M Q Q m rn m co c0 M p I u r co r co co co co co ui Iri vi ui ui � Z ` N O (n N U } O O O O O O O O O O O O O O F n E 0 0 0 0 0 0 0 0 0 0 0 0 0 O f Y O = y z z M O M O O O V dd Q N N � R Z N M M M N A C R i U c) LL R E U ELL E E E 7 0- W 10 r 10 O O M N N of a0 O M M _ Q J O Cl! N R a lY.l E � O Ifi I[i o r r r c0 m m m m ca aD rn rn rn Q p a C_ W O r u W U oN w E ~ U x E w m t fA 2 Q Q Q Q Q N Q Q N� to 10 u� 0 0 0 0 0 0 0 0 0 0 0 0 0 Q _= A a 0 0 0 0 0 0 0 0 0 0 0 0 0 (n W N O O O O O O O O O O O O O a R H 3 3 E o O O Z m n_ o O J y 7 U 7 U ^ t Lq o u 3 3 ci > z D m o. CL a a a a a a a a a a a $ .. R O N (O Q N N M O M O (O N N •• U LU O Q M O N Q M N 0 9 0 10 Lll U V O O N M M Q 10 t0 I� N m Ol O m C C Ul N H C I 'y N J C a o 0 ❑ O O O O O O O O 0 0 0 0 0 y b M l0 co z H Q J O N a t6 � ° E o E M i x W 0 o 0 0 0 0 0 0 0 0 0 0 0 0 0l 0 o 0 0 0 0 0 0 0 0 0 0 ti m r m �n Q M N � o m rn w r ' �i E p a ; R v N O R Ii z z° o, N o > a` m 00 m m Z M N GET Virginia Beach Office 204 Grayson Road Virginia Reach, VA 23462 (757)518-1703 Williamsburg Office 1592 Penniman Rd. Suite E Williamsburg, Virginia 23185 (757)564-6452 CLASSIFICATION SYSTEM FOR SOIL EXPLORATION Eiizabeth City Office 504 East Elizabeth St. Suite 2 Elizabeth City, NC 27909 (252)335-9765 Standard Penetration Test (SPT). N-value Standard Penetration "rests (SPT) were performed in the field in general accordance with ASTM D 1586. The soil samples were obtained with a standard 1.4" LD., Y' O.D., 30" long split -spoon sampler. The sampler was driven with blows of a 140 lb. hammer falling 30 inches. The number of blows required to drive the sampler each 6-inch increment (4 increments for each soil sample) of penetration was recorded and is shown on the boring logs. The sum of the second and third penetration increments is termed the SPT N-value. NON COHESIVE SOILS (SILT, SAND, GRAVEL and Combinations) Relative Density Very Loose 4 blows/R, or less Loose 5 to 10 blows/ft. Medium Dense 1 I to 30 blows/ft. Dense 31 to 50 blows/ft. Very Dense 51 blows/ft. or more Particle Size Identification Boulders 8 inch diameter or more Cobbles 3 to 8 inch diameter Gravel Coarse I to 3 inch diameter Medium 1/l to I inch diameter Fine 1/r to % inch diameter Sand Coarse 2.00 man to 1/. inch (diameter of pencil lead) Medium 0.42 to 2.00 man (diameter of broom straw) Fine 0.074 to 0.42 mm (diameter of human hair) Silt 0.002 to 0.074 man (cannot see particles) CLASSIFICATION SYMBOLS (ASTM D 2487 and D 2488) Coarse Grained Soils More than 50% retained on No. 200 sieve GW - Well -graded Gravel GP- Poorly graded Gravel GW-GM - Well -graded Gravel w/Silt GW-GC - Well -graded Gravel w/Clay GP -GM - Poorly graded Gravel w/Silt GP -GC - Poorly graded Gravel w/Clay GM - Silty Gravel GC - Clayey Gravel GC -GM - Silty, Clayey Gravel SW - Well -graded Sand SP - Poorly graded Sand SW-SM - Well -graded Sand w/Silt SW -SC - Well -graded Sand w/Clay SP-SM - Poorly graded Sand w/Silt SP-SC - Poorly graded Sand w/Clay SM - Silty Sand SC - Clayey Sand SC-SM - Silty, Clayey Sand Fine -Grained Soils 50%or more passes the No. 200 sieve CL - Lean Clay CL-ML - Silty Clay ML - Silt OL - Organic Clay/Sih Liquid Limit 5Ws, or greater CH - Fat Clay MH - Elastic Silt OH - Organic Clay/Silt Highly Organic Soils PT - Peat - gage 1 off t GET Revision 12112107 COHESIVE SOILS (CLAY, SILT and Combinations) Consistency Very Soft 2 blows/ft. or less Soft 3 to 4 blows/ft. Medium Stiff 5 to 8 blows/E. Stiff 9 to 15 blows/ft. Very Stiff 16 to 30 blows/ft. Hard 31 blows/ft. or more Relative Proportions De Q rve Term Percent Trace 0-5 Few 5-10 Little 15-25 Some 30-45 Mostly 50-100 Strata Changes In the column "Description" on the boring log, the horizontal lines represent approximate strata changes. Groundwater Readings Groundwater conditions will vary with environmental variations and seasonal conditions, such as the frequency and magnitude of rainfall patterns, as well as tidal influences and man-made influences, such as existing swales, drainage ponds, underi rains and areas of covered soil (paved parking lots, side walks, etc.). Depending on percentage of fines (fraction smaller than No 200 sieve size), coarse -grained soils are classified as follows: Less than 5 percent GW, GP, SW,SP More than 12 percent GM, GC, SM, SC 5 to 12 percent Borderline cases requiring dual symbols G� a 0 Plasticity Chart MENNEN on ■■■■■■®„■ ■■■■■, ■ ■■■®.EM■■ ■■■.,■■■■■ MOSOMEMMEN :1 1. _J bd LIQUID LIMIT (LL) (%) TIMMONS GROUP .•••••0 YOUR VISION ACHIEVED THROUGH OURS. 0 • 5410 Trinity Road, Suite 112, Raleigh, NC 27607 To: NCDENR Wilmington Regional Office Attn: Ms. Kelly Johnson 127 Cardinal Drive Extension Wilmington, NC 28405 From: Zak Shipman, PE Project: Stormwater Permit -Pre -Trial Confinement Facility Enclosed Please Find: DATE 2 3-23-11 Stormwater Construction Drawings 2 Application Form 1 O&M Forms BMP Supplements, USGS Quad Map, and Fee Check 1 Calculation Package 1 Geotech Report 1 Project Narrative 1 Response to Comments Letter Comments: Ms.Johnson, Please let me know if you have any questions. Thanks, T:ECEIVED MAR 2 4 2011 BY: SIGNED: _ Z k Shipman, PE �v0000 .O °O TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. Zak Ship PE I project Engineer TEL 919.866.4937 5410 Trinity Road, Suite 112 FAX 919.859.5663 Raleigh, NC 27607 zak.shipman@timmons.com �0000.® TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. March 23, 2011 NCDENR Wilmington Regional Office Division of Water Quality 127 Cardinal Drive Extension Wilmington, NC 28405 Attn: Ms. Kelly Johnson Re: Pre -Trial Confinement Facility (P-1310) Dear Ms. Johnson, MAR 2, 4 2011 Attached please find revised construction documents, drawings, calculations, and application materials to enable the review of the reference project. We are in receipt of your letter dated March 8 regarding the previous submittal of the application package which was rejected. We have addressed your comments contained in that letter as outlined below: 1. Design Storm: This project was designed with a 1.0" design storm. Please design it for the 1.5" design storm. Timmons Response: The project has been redesigned using the 1.5" storm. 2. Seasonal High Water Table (SHWT): A soils report was submitted for this project, but it does not contain all of the information we need. Please provide the SHWT and infiltration rate for a boring for each BMP location. Timmons Response: The soils report contains the SHWT information on the individual boring logs. Borings BMP-1, BMP-3, and BMP-4 were performed in the areas of the stormwater facilities, and each have SHWT depths shown on the individual boring logs. Additionally, page 14 of the report contains information on infiltration rates at those borings. 3. DWQ Staff Visit: Please contact Vince Lewis, our Soil Scientist, to schedule a site visit. A site visit is required prior to submitting any infiltration project to the Wilmington office. Timmons Response: We contacted Vince Lewis and he met the project geotechnical engineer on site Thursday, March 17. His findings for the SHWT at the infiltration basin differed slightly from that obtained by GET Solutions, which has resulted in the removal of the infiltration basin from the project. The drainage area associated with that basin will now be treated by large bioretention cell in the back of the project. 4. Simple Method: Please use the simple method to calculate the required volume for each BMP as is required by regulation. Timmons Response: The simple method has been used as requested. TIMMONS GROUP YOUR VISION ACHIEVED THROUGH OURS. 5. Other: Please see the design checklist which is available on our website under "miscellaneous forms" for guidance on the items that must appear on the plans, http://portal.ncdenr.org\web/wq/ws/su/statesw/form docs. Timmons Response: We have reviewed this checklist and included the items indicated as needed. We hope these revisions to the project satisfy these comments. If you have any questions or further comments, please don't hesitate to give me a call at (919) 866-4937. Best Regards, Zak Shipman, PE Project Engineer P m P F E 0 0 0 E E ". - Johnson, Kelly From: Zak Shipman [Zak.Shipman@timmons.com] Sent: Friday, March 18, 2011 11:38 AM To: Johnson, Kelly Subject: RE: Pre -Trial Confinement Facility Thanks for the information! This drains to SC-HQW, so I don't believe we are subject to the SA rules. I'll design for the 1.5" storm accordingly. I just wanted to make sure I didn't send you another package which would get rejected again. Thanks! Zak Shipman, PE Project Engineer 111 TIMMONS GROUP I www.timmons.com 5410 Trinity Road, Suite 112 1 Raleigh, NC 27607 Office: 919.866.49371 Fax: 919.859.5663 Mobile: 919.210.8608 1 zak.shipmanCcDtimmons.com Your Vision Achieved Through Ours From: Johnson, Kelly [mailto:kelly.p.johnson(cbncdenr.govl Sent: Friday, March 18, 2011 11:32 AM To: Zak Shipman Subject: RE: Pre -Trial Confinement Facility Zak, If I remember correctly this was a new project at Camp Lejeune, and so it would be subject to the "2008 Coastal Rule" (SL2008-211), attached. So, if you are subject to SA requirements (if you are within a half mile and draining to SA) you have to do either the 1.5" storm or the 1yr 24hr pre/post storm (-3.8") volume, whichever is greater. If you are not subject to SA, then you have to do 1.5". 1 have highlighted the applicable portions of the rule in yellow, attached. The first highlighted part will sound like it is only for ORW waters, but there is a requirement later that SA has to meet most of those requirements including the volume requirement. The second highlighted section is for "other' areas meaning non-ORW and non -SA areas. I have also attached a general sheet containing answers to common questions for USMC projects. Have a good weekend, KJ From: Zak Shipman [mailto:Zak.Shipman(d)timmons.com] Sent: Friday, March 18, 2011 10:46 AM To: Johnson, Kelly Subject: Pre -Trial Confinement Facility Ms. Johnson, I just left you a voicemail but thought I would follow up with an email as well. I am in receipt of your March 8 letter regarding the reference project at Camp Lejeune. Comment 1 mentions for us to design the system for the 1.5" runoff event, which we are in the process of doing. In looking at the BMP manual, Chapter 3 mentions that the designer is to consider two forms of runoff in determining the treatment volume: either the 1.5" runoff event or the difference in volume for the pre and post development scenario generated by the 1 year, 24 hour storm. Obviously the 1 year 24 hour storm event generates significantly more treatment volume than the 1.5" storm. The BMP manual is a little vague (maybe I'm not looking in the right spot) on if the 1 year storm volume calculation is in play on this particular project due to the sites water classification. Since this site does not drain to SA waters, is the 1 year volume applicable? Should we design solely for the 1.5" storm and ignore the 1 year storm? This would seem to concur with Comment 1 on your letter. If you could let me know your thoughts, it would be much appreciated. Thanks! Zak Shipman, PE Project Engineer III TIMMONS GROUP I www.timmons.com 5410 Trinity Road, Suite 112 1 Raleigh, NC 27607 Office: 919.866.49371 Fax: 919.859.5663 Mobile: 919.210,8608 1 zak.shioman(d).timmons.com Your Vision Achieved Through Ours Nrf 517311NJtlVA31350W ^ 133H5 H3A0� ` 9 G q�■ Yr w'^•^"^^^Allll�tlA 1WW3NIAN03 ltlltll'3Ld q TWO1.. 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Sa134 ! iA § AeL ! 3 4S5 "R 1 1 9P F ggY4{{iQ z yyroyr 1a�Avc�9tyi S33 111 w 0 u 0 Q dnoun sNowwu IL M1 z 0 Z 0 IN ry tgP Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G�,� 4.9 Seismic Design Recommendations: Based on our experience with similar construction projects in the general area of the project site, and in accordance with the previously completed Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G included in Appendix IV of this report) and the NC Building Code; Chapter 16, this site would be classified as a site Class C, based on which seismic designs should be incorporated. This recommendation is based on the data obtained from the 75-foot deep SPT borings, our experience with 100-foot deep CPT soundings and SPT borings performed within the vicinity of the project site, as well as the requirements indicated in the North Carolina State Building Code (2006 International Building Code). 4.10 Soil Permeability Four (4) infiltration tests were performed at boring locations BMP-1 through BMP-4 (one test at each boring location). The tests were performed at depths ranging from 2 to 5 feet below existing site grade elevations. The borehole was prepared utilizing an auger to remove soil clippings from the base. Infiltration testing was then conducted within the vadose zone utilizing a Precision Permeameter and the following testing procedures. A support stand was assembled and placed adjacent to the borehole. This stand holds a calibrated reservoir (2000 ml) and a cable used to raise and lower the water control unit (WCU). The WCU establishes a constant water head within the borehole during testing by use of a precision valve and float assembly. The WCU was attached to the flow reservoir with a 2-meter (6.6 foot) braided PVC hose and then lowered by cable into the borehole to the test depth elevation. As required by the Glover solution, the WCU was suspended above the bottom of the borehole at an elevation of approximately 5 times the borehole diameter. The shut-off valve was then opened allowing water to pass through the WCU to fill the borehole to the constant water level elevation. The absorption rate slowed as the soil voids became filled and an equilibrium developed as a wetting bulb developed around the borehole. Water was continuously added until the flow rate stabilized. The reservoir was then re -filled in order to begin testing. During testing, as the water drained into the borehole and surrounding soils, the water level within the calibrated reservoir was recorded as well as the elapsed time during each interval. The test was continued until relatively consistent flow rates were documented. During testing the quick release connections and shutoff valve were monitored to ensure that no leakage occurred. The flow rate (C), height of the constant water level (H), and borehole diameter (D) were used to calculate KS utilizing the Glover Solution. 4, 13 GET Report of Subsurface Investigation and Geolechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility -x MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Based on the field testing and corroborated with laboratory testing results (published values compared to classification results), the hydraulic conductivity of the shallow soils is tabulated below (Table III) and is presented on the "Hydraulic Conductivity Worksheet" (Appendix V), included with this report. a Table III - Infiltration Test Results t Boring , I . `Boi•Ing ' ;depth =' Water.. " '' l depth ;. PercenfSilY and/or Clay Ksat '. Value` Ksat Value ,.,. . Ksat Class r-; 9MP-1 2.0 4.8 31.1 7.23 x 10' 0.102 Moderately Low BMP-2 2.0 5.29 21.2 8.94 x 10 1.267 Moderatel High BMP-3 4.0 9.875 24.0 2.27 x 10' 0.321 Moderately High BMP-4 5.0 9.92 17.5 6.33 x 104 0.898 Moderately High The boring test and water depths noted above are referenced from below the existing site grade elevations. 5.0 CONSTRUCTION CONSIDERATIONS 5.1 Drainage and Groundwater Concerns It is expected that dewatering may be required for excavations that extend near or below the existing groundwater table. Dewatering above the groundwater level could probably be accomplished by pumping from sumps. Dewatering at depths below the groundwater level may require well pointing. It would be advantageous to construct all fills early in the construction. If this is not accomplished, disturbance of the existing site drainage could result in collection of surface water in some areas, thus rendering these areas wet and very loose. Temporary drainage ditches should be employed by the contractor to accentuate drainage during construction. If water collects in foundation excavations, it will be necessary to remove water from the excavations, remove saturated soils, and re -test the adequacy of the bearing surface soils to support the design bearing pressure prior to concrete placement. 5.2 Site Utility Installation The base of the utility trenches should be observed by a qualified inspector prior to the pip and structure placements to verify the suitability of the bearing soils. If unstable bearing soils are encountered during installation some form of stabilization may be required to provide suitable bedding. This stabilization is typically accomplished by providing additional bedding materials (NCDOT No. 57 stone). In addition, depending on the depth of the utility trench excavation, some means of dewatering may be required to facilitate the utility installation and associated backflling. 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W'', W O W O W W O W O w N >.� d �,� — Y d Y N O O N vMIN O ( Um.—� N �O N N N m Z O d C •! N N W mim W W,..m m m Q Q m Q P Q M F- II E o 0 0 0 016 6 0; o 6 6 6 6 6 Y O 2 Y d U Z Z M M M O __-I_ o 1 o _� M, IO', Q M P M O O O P P N N a •• Z d R• M M O M M M m N In) N� O N N N N N. M M n O n O Y d O O R J C 3 E I w a « E E E O O O O OIO O O O O O W« E o b F m d 6 ` E a a M , OO o v — --_ I M -- _—_—_�_---_ M P m m I = F- t N 2 N n P Q P Q P Q P( In in In In LP Q •• d W O 0 O 0 O 0 O m O Q O 01 OI 0 0 O 0 c7 0 O 0 O 0 O 0 2= 2 O O O Oy O O O O O O o N N 3 E N Z m rn J L_ I e p" LL 3 3 ci � I> z _ o0 y a a a a a a a aka a a a a a d 0 U) m vp N N ! O M m O m N � W VI N E E t o e In ZC m o 0 0 0 0 0 0 0' �i� o 0 0 0 o m rn o F7 Q O N a w N E o Y E Liz 0 0 m u 0 o N m m � w m 0 n 0 m— 0 0 o I o '-I 0 0 0 0 o d 6 V ... O N LL z z° o, o ow D 0 0 0 a m= _r NC®ENR North Carolina Department of Environment and Natural Resources Division of Water Quality Beverly Eaves Perdue Coleen H. Sullins Governor Director March 8, 2011 Mr. Carl Baker, PE, Deputy Public Works Officer Marine Corps Base Camp Lejeune 1005 Michael Road Camp Lejeune, NC 27547 Subject: APPLICATION RETURN Pre -Trial Confinement Center (P-1310) Onslow County Dear Mr. Baker: On March 4, 2011, the Division received an incomplete State Stormwater Management Application for the project listed above. The application and check number 010228, in the amount of $505 are being returned because the application package lacked the necessary elements to accept it for review. Please provide the following information upon the next submittal of this application package: Dee Freeman Secretary 1. Design Storm: This project was designed with a 1.0" inch design storm. Please design it for the 1.5" design storm. 2. Seasonal High Water Table (SHWT): A soils report was submitted for this project, but it does not contain all of the information we will need. Please provide the SHWT and infiltration rate for a boring for each BMP location. 3. DWQ Staff Visit: Please contact Vince Lewis, our Soil Scientist, to schedule a site visit. A site visit isrequired prior to submitting any infiltration project to the Wilmington office. 4. Simple Method: Please use the Simple Method to calculate the required volume for each BMP as is required by regulation. 5. Other: Please see the design checklist which is available on our website under "miscellaneous forms" for guidance on the items that must appear on the plans, http://portal.ncdenr.org/web/wq/ws/su/statesw/forms docs. Please visit DWQ's website at http://h2o.enr.state.nc,us/su/bmp forms htm to download the latest available forms. Please provide the requested information and return the package to the address below. Note that the 90-day statutory permit review time begins upon receipt of a complete application. Wilmington Regional Office 127 Cardinal Drive Extension, Wilmington, North Carolina 28405 Phone: 910-796-72151 FAX: 910-350-20041 Customer Service: 1-877-623-6748 Inlemet. vv w.ncwatenluality,org Ore NorthCarolina Natin-ally An Equal Opportunity 1 Affinnalive Actbn Employer Pre -Trial Confinement Facility (P-1310) March 8, 2011 If you have any questions, please do not hesitate to call me at (910) 796-7331 or email me at kelly.p.johnson@ncdenr.gov. Sinc rely, elly J nson Environmental Engineer S:\WQS\StormWater\Permits & Projects\Application Returns\2011 03 Pre Trial Confinement cc: Zak Shipman, PE, Timmons Group Wilmington Regional Office File Page 2 of 2 Rule(s) Subject (check all that apply): ❑ 1995 Coastal f9'2008 Coastal ❑ Phase II ❑ Universal Paperwork: Check for $505 (must be no older than 6 months) CYlpplication form with correct/original signatures (original plus 1 copy). If Corporation or LLC also: o Print the info from the NCSOS X o Either, 1.) The applicant is listed on the NCSOS with his/her correct title or, 2.) A notarized letter of authorization has been provided: Q�'Supplements (1 original per BMP). BMP type(s): �� vrf , toQ IEn) Cto� CEO&M with correct/original signatures (1 original per BMP, except le'vepreaderslfilter strips and swales) .a'Deed restrictions (if outparcel or subdividing) (original pJuscopy)\\ o Deed restriction template (signed and or 1 o Proposed Declaration of Covenants and Restrictions (sig ed and notarized) ❑ Soils report identifying the SHWT &(by •. r I� g�E\3 NO CSrnn? Ciao Locc un Wt 1 M? Supporting calculations, signed & sealed (if necessary)Receiving stream classification: 5C1r� S `N , If SAW also: o SA: USGS topo map with the it thet`ceivi g waters and the''/2 mile radius shown to scale. o O 575 ft of MHWL for Area onvirQ�me�tal Concern and max BUA per rule. �Modifica6ons: If built: Designer's Cert., 2. �If part a lly built: Partial Cert., 3.) If not built: No Cart. needed. Development T�pe (che k all that apply ❑ Residential or C9 Commerciaili ❑ Deed restrictions match? ❑ Subdivision or mingle Lot ❑ Deed restrictions match? (2/ High Density or Okow Density ❑ Deed restrictions match? locc,) cCvo) x,A ❑ Offsite project ❑ RedevelopAent ❑ Modification ❑ Exempt, �jq❑ NCGQ2 (bulkhead) ❑ NCG03v(bTear/grade) ❑ NCG04 (linear) Density: I � ❑ BUA calculations inc •somnwn{areas, clubhouse, sidewalks, etc. ❑ BUA %��ip.?, i , Matches high/low density requirement for rule and receiving stream class: P No obvious math errors ❑ If High Density: Design storm correct for rule and receiving stream class.p@ \' ? ()�pQ Plans, signed and%ealed (2 sets): SvmP�O o me ❑ Two sets recei d ❑ Layout (with proposed BUA dimensions) �� f aS�3m s ❑ Grading ❑ Drainage area map (all HD systems & curb outlet swales) ❑ Vicinity map ❑ Project Boundaries ❑ Legend ❑ Wetlands: o Delineated on plans o "No wetlands onsite" on plans ❑ Details: o Roads o Cul-de-sacs o Curbing o Sidewalk o BMPs/ Level spreaders/ Filter strips/ Curb outlet swales o Buildings (Apts or Condos) Offsite Projects: ❑ Des' er's Certification has been submitted for the Offsite BMP receiving the runoff from the project. Zed restrictions have been recorded and a copy submitted for the Offsite BMP permit. ot size has not changed from what was approved under the Master Plan. orrect lot number is referenced on the supplement form. ffsite system is in compliance with its permit, if known. Infiltration Projects: ❑ Soils report: SHWT, soil type, and expected infiltration rate are provided. ❑ DWQ has conducted a site visit? Date: Wet Pond Permanent Pool Meets One of the Following: Is located no lower than 6" below the estimated SHWT. ❑ Incoming groundwater is quantified and evaluated, AND Storage volume verified, AND Outlet evaluated for free drainage to the receiving waters under SHWT conditions. Decision (check one): ❑ Complete: Return file to admin (Jo Casmer) to log in. (Stamped in received date = BIMS date) ❑ Slightly incomplete: E-mail consultant, request information to be returned within one business day (24 hours after request. Info requests on Friday, allow a return on the following business day). If info not returned, issue an application return letter and give everything to admin. (Add info received date = BIMS date) ❑ Substantially incomplete: Issue an application return letter and give everything to admin. 16No Cell Ale 3 fro Ce�� #Z YNS,� Ius h # \ $M91) lcakN Ei �S GMQ y 6awNoi.,A a �rcNsx-J p.(0 75rtw� VOq-) TIMMONS GROUP o•••••0 YOUR VISION ACHIEVED THROUGH OURS. * • 0 5410 Trinity Road, Suite 112, Raleigh, NC 27607 To: NCDENR Wilmington Regional Office Erosion Control Express Review 127 Cardinal Drive Extension Wilmington, NC 28405 From: Zak Shipman, PE Project: Stormwater Permit -Pre -Trial Confinement Facility Enclosed Please Find: DATE 2 3-2-11 Stormwater Construction Drawings 2 Application Form 1 O&M Forms BMP Supplements, USGS Quad Map, and Fee Check 1 Calculation Package 1 Geotech Report 1 Project Narrative Comments: Please call with questions. E-CEIVED MAR 44 2011 BY:�_ SIGNED Z Shipman, PE -J%�``,�`-e, ;1d/�,'l; •n: � j � m � iy Cr �. S � \moo ��l(��J% /� neau 71 �` ��� ���\ '��� e a r .� �� �' � I�—emu 'q 7 ' 25� ( � - oea' �♦ � 1� 0 O ( 3. 5P, A 1. —Y �l L_ il��ai�♦ b I ♦ � � � , .n��' /i�..:�25 ,'� O , sy5 ��; � i' �`/'� �.r, ,\ y.t * . o ✓��i ice— f , A ���F�. .'" V Tankgw�! it Ir l Y ay n 2 1 //77 Ruins +�j_��✓*/e'�y "'�. Ira 1 _ 1° 7' d;\.1r,. ,. /, 25'�� f', '�/ Copynoht (C) 1997. Maptech. Inc. / VED MAR 0 4 2011 Stormwater Design Narrative Pre -Trial Confinement Facility -Camp Lejeune, NC Project Overview The Pre -Trial Confinement Facility is a new project that proposes to construct a two story brig facility which will be used to house detainees prior to their processing by the military justice system. The facility will have a total of 75 beds and will be constructed to accommodate a future expansion up to 135 beds. The building will feature pre -cast tilt wall construction and steel framing with a brick veneer exterior. The site is approximately 8 acres in size and is currently vacant. Existing Site Conditions and Demolition: The site selected for the Pre -Trial Confinement Facility is located adjacent to the intersection of Duncan Street and Snead's Ferry Road inside the cantonment area of Camp Lejeune. The site is heavily wooded, except for a small cleared area located along the southwestern border of the project site. An existing barracks building and associated parking lot are located along the western border of the site. The existing base brig is located southwest of this barracks facility. Existing basketball and volleyball courts are located in the cleared area on the west of the site, along with a small picnic shelter and several small storage buildings. Additionally, the site is bounded to the east by a dirt tank trail and a small intermittent stream. This stream is an unnamed tributary to Cogdels Creek and is classified by North Carolina Department of Environment and Natural Resources (NCDENR) as SC -NSW. Topography on the parcel is generally flat with some areas of moderate grade located in the vicinity of the adjacent stream. Soils on site are classified as Baymeade fine sand by the local soils survey. No wetlands have been documented on the parcel as indicated by the RFP provided by the government. Several existing features are currently located on the site that will require removal or demolition. These include exercise equipment, a volleyball court, basketball court, and covered picnic shelter. Drainage and Stormwater Considerations: Stormwater will be managed on site by carefully grading area to direct runoff into a network of vegetated swales and treatment basins. Curb and gutter has been minimized as much as possible to. encourage sheet flow. Additionally, a minimal amount of hard piping is proposed which will require runoff to travel long distances in vegetated swales prior to entering BMP facilities. NCDENR regulations require the treatment of the first inch of runoff for the removal of Total Suspended Solids (TSS). Additionally, pre and post volume control for the 1 year, 24 hour storm is required. This project seeks to meet these requirements by directing all runoff into one of three stormwater Best Management Practices (BMP) basins. Two bioretention basins will be installed in conjunction with an infiltration basin. Bioretention basins 2 and 3 will be constructed in accordance with NCDENR BMP manual. Runoff will enter these basins via combinations of sheet flow as well as from vegetated swales. Runoff from the swales will flow over energy dissipating rip rap pads to slow velocity and promote sediment removal and filtration. The basins will feature a thick layer of soil media which will filter the runoff and remove pollutants and other contaminants. Perforated underdrains are to be installed in the basins per the construction drawings to allow for more efficient water removal from the soil media. While the maximum ponding depth is limited to 12 inches, the basins are sized accordingly to prevent discharge from the 1 and 2 year storms. Basin 3 has a very small discharge in the 10 year storm, however basin 2 does not have any discharges until the 25 year storm. These extended detention capacities have eliminated the need for a complicated bypass system to parse out runoff in excess of the design control volume. Infiltration basin 1 will also be constructed in accordance with NCDENR BMP manual requirements. Extensive soils testing has been performed in the area to be occupied by the device. Stormwater hydrograph modeling indicates that the basin can contain all the water from the 10 year storm without discharging, and can drawdown this volume in the specified time period at half the determined permeability rate. This additional performance eliminates the need for a hydraulically inefficient bypass mechanism to divert additional runoff around the device. GET X Geotechnicnl • Environmental • Testing REPORT OF SUBSURFACE INVESTIGATION AND GEOTECHNICAL ENGINEERING SERVICES P-1310 Pre -Trail Detainee Facility MCB Camp Lejeune, North Carolina G E T PROJECT NO: JX10-113G November 24, 2010 Prepared for M.B. Kahn Construction Company, Inc. P.O. Box 1179 Columbia, South Carolina 29202 ATTN: Mr. Barret Boozer Prepared by MAR � 4 2011 GET Solutions, Inc. 415 A Western Boulevard, Jacksonville, NC 28546 ♦ Phone 910-478-9915 ♦ Fax 910-418-9917 info@getsolutionsinc.com I GET GeoinM,nimf .&,ni.onmrn�uf • intiny TO: M.B. Kahn Construction Company, Inc. P.O. Box 1179 Columbia, SC 29202 Attn: Mr. Barret Boozer November 24, 2010 RE: Report of Subsurface Investigation and Geotechnical Engineering P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G Dear Mr. Boozer: In compliance with your instructions, we have completed our Subsurface Investigation and Geotechnical Engineering Services for the above referenced project. The results of this study, together with our recommendations, are presented in this report. Often, because of design and construction details that occur on a project, questions arise concerning subsurface conditions. G E T Solutions, Inc. would be pleased to continue its role as Geotechnical Engineer during the project implementation. Thank you for the opportunity to work with you on this project. We trust that the information contained herein meets your immediate need, and should you have any questions or if we could be of further assistance, please do not hesitate to contact us. Respectfully Submitted, Inc. 'EIrk G E T Solutions, �rOFEss : Pe No. l✓� — 033529 Glenn W. Hohmeier, P.E.<<c�FNciN�Ee � �. Senior Project Engineer '�, ti k H0Nf NC Reg. # 033529•"" f CARO Camille A. Kattan, P.E. o senL �. Principal Engineer 014103 NC Reg. # 014103 = �'•. :��ij ,�"NC I NEE' �•.`p�.. A. Copies: (1) Client 415-A Western Boulevard • Jacksonville, NC 28546 • Phone: (910) 478-9915 • Fax: (910) 478-9917 _info@getsolutionsinc.com I ' TABLE OF CONTENTS EXECUTIVESUMMARY.............................................................................................i 1.0 PROJECT INFORMATION..............................................................................1 ■ 1.1 Project Authorization..............................................................................1 1.2 Project Description.................................................................................1 ' 1.3 Purpose and Scope of Services.............................................................1 2.0 FIELD AND LABORATORY PROCEDURES..................................................2 2.1 Field Exploration....................................................................................2 2.2 Laboratory Testing.................................................................................3 ' 3.0 SITE AND SUBSURFACE CONDITIONS........................................................4 3.1 Site Location and Description................................................................4 3.2 Subsurface Soil Conditions....................................................................5 ' 3.3 Groundwater Information.......................................................................6 4.0 EVALUATION AND RECOMMENDATIONS...................................................7 ' 4.1 Subsurface Voids...................................................................................7 4.2 Clearing and Grading.............................................................................8 4.3 Subgrade Preparation............................................................................9 4.4 Structural Fill and Placement...............................................................10 4.5 Shallow Foundation Design Recommendations...................................11 4.6 Settlements..........................................................................................11 ' 4.7 Foundation Excavations.......................................................................11 4.8 Floor Slabs...........................................................................................12 4.9 Seismic Design Recommendations.....................................................13 ' 4.10 Soil Permeability..................................................................................13 ' 5.0 CONSTRUCTION CONSIDERATIONS.........................................................14 5.1 Drainage and Groundwater Concerns.................................................14 5.2 Site Utility Installation...........................................................................14 ' 5.3 Excavations.........................................................................................15 6.0 REPORT LIMITATIONS.................................................................................15 ' APPENDIX I BORING LOCATION PLAN APPENDIX II BORING LOGS APPENDIX III GENERALIZED SOIL PROFILE APPENDIX IV ADDENDUM NO. 1 TO THE ORIGINAL FEASIBILITY STUDY REPORTED ON THE DATE OF FEBRUARY 19, 2010 (GET Project No. EC09-106G) APPENDIX V HYDRAULIC CONDUCTIVITY WORKSHEETS ' APPENDIX VI CLASSIFICATION SYSTEM FOR SOIL EXPLORATION GE® I Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G EXECUTIVE SUMMARY November 24, 2010 ' The project site is located on the west side of Sneads Ferry Road within the Camp LeJeune military installation in North Carolina. The development at this site is planned to consist of constructing a single story pre-trial detainee facility with a mezzanine having a total plan area of approximately 25,000 square feet. The maximum wall and column foundation loads associated with the structure were not known at the time of this report. However, based on our experience with similar projects the maximum wall loads associated with the building are not expected to exceed 5 kips per linear foot, and the column loads are not expected to exceed 100 kips. The structure's first floor will be supported on -grade with the distributed loads estimated at 150 pounds per square foot. The construction at this site is also planned to consist of paved driveways and parking areas, infiltration/bioretention basins and installation of associated infrastructure components. Our field exploration program included four (4) recently completed 30-foot deep Standard Penetration Test (SPT) borings drilled by G E T Solutions, Inc. within the footprint of the proposed structure, and four (4) 15-foot deep SPT boring (designated as BMP-1 through BMP-4) drilled within the proposed infiltration/bioretention basins. A total of four (4) 75-foot deep previously completed SPT borings identified as B-5 through B-8 and four (4) CPT soundings (CPT-1 through CPT-4) were performed during the project's initial feasibility study and were included in our evaluations for foundation design recommendations for the proposed building. Additionally, boring INF-1 is included herein but was limited to evaluating the soil conditions in the vicinity of the proposed southeastern infiltration/bioretention basin. A brief description of the natural subsurface soil conditions is tabulated below: AVERAGE RANGES OF STRATUM DESCRIPTION SPTI'i N- DEPTH (Feet) VALUES 0 to 0.17-1.2 2 to 14 inches of Topsoil 0.17-1.2 SAND with varying amounts of silt and/or clay to I (SP, SP-SM, SM, SC-SM, SC) WOH to 100 15 - 75 4 to 6 IA Lean CLAY (CL); Boring B-5 & B-11 only 5 to 8 7 to 7.5 & N/A @ B-6; IB Fat CLAY (CH); Boring B-6 & B-9 only 23 to 28 1 @ B-9 28 to 32 - Void; Borings B-7 and B-8 only N/A MARLSTONE; at varying depths between 30 and 30 to 58 IC 58 feet below the existing site grades at 32 to 77 Borings B-6, B-7, and B-8 Note (1) SPT = Standard Penetration Test, N-Values in Blows -per -foot WOH — Weight of Hammer Solutions. Inc w I ' Report of Subsurface Investigation and Geotechnical Engineering Services November 24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G ' The groundwater level was recorded at the boring locations and as observed through the wetness of the recovered soil samples during the drilling operations. The initial ' groundwater table was measured to occur at depths ranging from 8 to 10 feet below current grades at the B-9 through B-12 boring locations, which corresponds to an elevation of about 20.0 feet (MSL). In addition, four (4) temporary piezometers were ' installed at the boring BMP-1 through BMP-4 locations at the time of drilling and 24 hour groundwater readings were measured to occur at depths ranging from 4.8 to 5.29 feet below current grades (boring locations BMP-1 and BMP-2) which corresponds to an ' approximate elevation of 27.0 feet MSL and at depths of 9.875 to 9.92 feet below current grades (boring locations BMP-3 and BMP-4) which corresponds to an approximate elevation of 20.0 feet MSL. ' The soil sample colors were used to aid in identifying the estimated normal SHWT at the location of borings BMP-1 through BMP-4. It is noted that soil morphology is not a reliable indicator of the SHWT in drained soils. However, slight color distinctions were observed within the soil samples collected at the location of borings BMP-1 through BMP-4. As such, the normal SHWT depth was estimated to occur at approximately 4 feet below the existing site grade elevation at boring locations BMP-1 and BMP-2 and at approximately 6 feet below the existing site grade elevation at boring locations BMP-3 and BMP-4. ' The current groundwater levels encountered at the project site and the estimated normal SHWT depths are anticipated to be contributed to the varying site topography and possible perched groundwater conditions specifically at boring BMP-1 and BMP-2 locations. The following evaluations and recommendations were developed based on our field ' exploration and laboratory -testing program: • Field testing program during construction to include, subgrade proofrolling, compaction testing, and foundation excavation observations for bearing capacity verification. All other applicable testing, inspections, and evaluations should be performed as indicated in the North Carolina State Building Code (2006 ' International Building Code with North Carolina Amendments). • A cut of up to 14 inches will be required to remove the topsoil material from the ' construction area. • Some subgrade improvements should be anticipated within the construction ' areas (undercutting and backfilling with select fill) as a result of potentially very loose subgrade soils containing appreciable amounts of fines (silt and clay) and organics (vicinity of boring locations B-9 and B-10). ii Soludons. Inc--,: 11 Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G November 24, 2010 , Subsurface voids approximately 2-feet deep were encountered at the location of the initially completed borings B-7 and B-8 at depths of 28 to 30 feet, respectively below the existing site grade elevations. Subsequently, a supplemental subsurface investigation (Addendum No. 1 to the original feasibility study) was completed to further explore the subsurface soil conditions at the location of the new building site (shifted to the east). Four (4) Cone Penetrometer Test (CPT) soundings were performed as part of Addendum No. 1 within the newly established building footprint which did not encounter these voids. Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G) is included in Appendix IV of this report. The building was again relocated to the west since the time Addendum 1 was completed. The initially drilled borings were plotted onto the new site plan provided by the client. One boring (B-8) was determined to be located within the northwest portion of the newly positioned building footprint. It should be noted that no voids were encountered within the recently completed borings B-9 through B-12 and previously completed borings B-5, B-6 and CPT soundings CPT-1 through CPT-4 to depths of 30 to 36 feet. The subsurface voids, where encountered, can be addressed by means of pressure grout placement (injection) to fill the voids and prevent the potential for subsidence from occurring and resulting in foundation and/or slab -on -grade settlement. It is recommended that a grout injection specialty contractor develop the number, depths, and locations of the injection points. Other options would include shifting the building easterly away from boring B-8; supporting that portion of the building on deep foundations (such as auger cast piles) or assuming some risk associated with the subsurface voids and leave the building at the present location. In any case, additional void delineation efforts may be warranted, by means of advancing several CPT probes within the western building area. Shallow foundations designed using a net allowable bearing capacity of 2,000 psf (24-inch embedment, 24-inch width) in combination with void stabilization, if deemed necessary. • Estimated post -construction total and differential settlements up to 1-inch and ''/z- inch, respectively, as contributed by the foundation bearing soils. Based on our experience with similar construction in the general area of the project site and in accordance with the previously completed Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G included in Appendix IV of this report) and the NC Building Code; Chapter 16, this site would be classified as a site Class C. N GET I Report of Subsurface Investigation and Geotechnical Engineering Services November 24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G This summary briefly discusses some of the major topics mentioned in the attached report. Accordingly, this report should be read in its entirety to thoroughly evaluate the contents. Solutlortfi Iris::.".:: I Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 1.0 PROJECT INFORMATION 1.1 Project Authorization November 24, 2010 I G E T Solutions, Inc. has completed our subsurface investigation and geotechnical engineering services for the proposed P-1310 Pre -Tail Detainee Facility located within the Camp LeJeune military installation in North Carolina. The Geotechnical Engineering Services were conducted in general accordance with G E T Solutions, Inc. Proposal No. PJX10-120G, dated October 6, 2010. Furthermore, these services were provided in conjunction with our previously completed feasibility study reported on the date of April 17, 2009 (GET Project No. EC09-106G) and Addendum No. 1 dated February 19, 2010. Authorization to proceed with the Geotechnical Engineering Services was received from Mr. Barret Boozer of M.B. Kahn Construction Company, Inc. 1.2 Project Description The development at this site is planned to consist of constructing a single story pre-trial detainee facility with a mezzanine having a total plan area of approximately 25,000 square feet. It is expected that the structure will be of steel frame and CMU wall design. The maximum wall and column foundation loads associated with the structure were not known at the time of this report. However, based on our experience with similar projects the maximum wall loads associated with the building are not expected to exceed 5 kips per linear foot, and the column loads are not expected to exceed 100 kips. The structure's first Floor will be supported on -grade with the distributed loads estimated at 150 pounds per square foot. The structure's first floor elevation (FFE=35.0 MSL) is expected to be located slightly above existing site grade elevations, which range from approximately 27 feet to 31 feet (MSL) within the building footprint. Therefore, it is anticipated that 4 to 7 feet of structural fill will be required to establish the design grade elevations. The construction at this site is also planned to consist of paved driveways and parking areas, infiltrationlbioretention basins and installation of associated infrastructure components. If any of the noted information is incorrect or has changed, please inform G E T Solutions, Inc. so that we may amend the recommendations presented in this report, if appropriate. 1.3 Purpose and Scope of Services The purpose of this study was to obtain information on the general subsurface conditions at the proposed project site. The subsurface conditions encountered were then evaluated with respect to the available project characteristics. In this regard, engineering assessments for the following items were formulated: General assessment of the soils revealed by the borings performed at the proposed development. Solutions, Inc: I I I ' Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 2. General location and description of potentially deleterious material encountered in the borings that may interfere with construction progress or structure performance, including existing fills or surficial/subsurface organics. 3. Soil subgrade preparation, including stripping, grading and compaction. ' Engineering criteria for placement and compaction of approved structural fill material. ' 4. Construction considerations for fill placement, subgrade preparation, and foundation excavations. 1 1 5. Feasibility of utilizing a shallow foundation system for support of the proposed structure. Design parameters required for the foundation system, including foundation sizes, allowable bearing pressures, foundation levels and expected total and differential settlements. 6. Permeability (infiltration) values are provided based on the results of in -situ Saturated Hydraulic Conductivity Testing conducted within the proposed infiltration/bioretention basins as well as our experience with similar soil conditions. Normal seasonal high groundwater table (SHWT) was also estimated. The scope of services did not include an environmental assessment for determining the presence or absence of wetlands or hazardous or toxic material in the soil, bedrock, surface water, groundwater or air, on or below or around this site. Prior to development of this site, an environmental assessment is advisable. 2.0 FIELD AND LABORATORY PROCEDURES 2.1 Field Exploration In order to explore the general subsurface soil types and to aid in developing associated foundation parameters, four (4) 30-foot deep SPT borings (designated as B-9 through B- 12) were drilled within the proposed structure's footprint. To aid in developing associated storm water management parameters, four (4) 15-foot deep SPT boring (designated as BMP-1 through BMP-4) were drilled within the proposed infiltration/bioretention basins. In -situ soil permeability testing was performed at each of these boring locations. Four (4) temporary piezometers were also installed (one at each of the boring locations). I Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G November24,2010 ' The SPT borings were performed with the use of rotary wash "mud" drilling procedures in general accordance with ASTM D 1586. The tests were performed continuously from the existing ground surface to a depth of 12-feet, and at 5-foot intervals thereafter. The soil samples were obtained with a standard 1.4" I.D., 2" O.D., 30" long split -spoon sampler. The sampler was driven with blows of a 140 lb. hammer falling 30 inches, using an automatic hammer. The number of blows required to drive the sampler each 6-inch increment of penetration was recorded and is shown on the boring logs. The sum of the second and third penetration increments is termed the SPT N-value (uncorrected for automatic hammer). A representative portion of each disturbed split -spoon sample was collected with each SPT, placed in a glass jar, sealed, labeled, and returned to our laboratory for review. Following the exploration procedures, the borings were backfilled with a neat cement grout mix in accordance with NCDENR requirements, excluding the four (4) infiltration/bioretention boring locations (Boring BMP-1 through BMP-4) where piezometers were installed. The recently completed borings were performed in conjunction with, and labeled consecutively with the previously completed borings associated with the project's feasibility study reported on the date of April 17, 2009 (GET Project No. EC09-106G). Accordingly, the four (4) 75-foot deep SPT borings identified as B-5 through B-8 performed during our initial feasibility study for the proposed project, which are located in the vicinity of the proposed reconfigured building footprint, are included herein and in our evaluations for foundation design recommendations for the proposed building. Additionally, boring INF-1 is included herein but was limited to evaluating the soil conditions in the vicinity of the proposed southeastern infiltration/bioretention basin. Whereas, the remaining borings performed during the initial feasibility study identified as B-1 through B-4 are not included in this report as they were located outside the limits of the proposed building. Boring locations B-9 through B-12 were established and staked in the field by a representative of G E T Solutions, Inc. with the use of a Global Positions System unit as well as the "State Plane" coordinates provided by the client. Boring locations BMP-1 through BMP-4 were surveyed in the field by the client. The approximate boring locations are shown on the attached "Boring Location Plan" (Appendix 1), which was reproduced based on the site plan provided by the client. 2.2 Laboratory Testing Representative portions of all soil samples collected during drilling were sealed in glass jars ' and zip lock bags, labeled and transferred to our laboratory for classification and analysis. The soil classification was performed by a Geotechnical Engineer in accordance with ASTM D2488. Seventeen (17) representative soil samples were selected and subjected to laboratory ' testing, which included natural moisture, 4200 sieve wash and Atterberg Limit testing and analysis, in order to corroborate the visual classification. These test results are provided in ' Table 1 on the following page and are presented on the "Boring Log' sheets (Appendix II), included with this report. _-_ _ 3 GET ' Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G ' Table I - Laboratory Test Results Boring No. Depth (Feet) Natural Moisture ,/o u/o Passing #200 Atterberg Limits LL/PL/PI USCS Classification B-9 4-6 22.0 32.9 Not Tested SC-SM B-9 8-10 26.7 25.1 Not Tested SP-SM B-9 23-25 69.2 90.6 70/25/45 CH B-10 6-8 21.5 34.9 32/22/10 SC 1-12 2-4 14.4 23.0 Not Tested SM BMP-1 1.5-2 15.2 31.1 Not Tested SM BMP-2 1.5-2 10.4 21.2 Not Tested SM BMP-3 3.5-4 15.7 24.0 Not Tested SM BMP-3 4-6 22.0 Not Tested Not Tested SM BMP-3 6-8 18.0 Not Tested Not Tested SP-SM BMP-3 8-10 21.7 Not Tested Not Tested Sp-SM BMP-3 10-12 25.4 Not Tested. Not Tested SP-SM BMP-4 4.5-5 12.6 17.5 Not Tested SM MP-4 4-6 9.2 Not Tested Not Tested SM MP-4 6-8 16.6 Not Tested Not Tested SM MP-4 rBMP-4 8-10 19.6 Not Tested Not Tested SM 10-12 21.0 Not Tested Not Tested SP-SM 3.0 SITE AND SUBSURFACE CONDITIONS 3.1 Site Location and Description ' The project site is located on the west side of Sneads Ferry Road within the Camp LeJeune military installation in North Carolina. This site consists predominantly of a heavily wooded parcel. The existing grades of the project site range from approximately 25 feet to 31 feet (MSL). The proposed construction areas are bordered to the north by Duncan Street, to the south by a wooded area, to the east by an existing dirt path followed by a heavily wooded area and to the west by a combination of an existing parking lot and an existing ' structure (Building 1042). An areal image of the general construction area is provided below and was obtained from Google Earth. 1 4 Soludons: Inc. •.....i Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 3.2 Subsurface Soil Conditions November24,2010 ' The results of our recently and previously completed soil test borings indicated the presence of approximately 2 to 14 inches of topsoil at the boring locations. Underlying the topsoil and extending to the boring termination depths of 15, 30, and 75 feet below existing site grades, the natural subsurface soils generally consisted of very loose to very dense SAND (SP, SP-SM, SM, SC-SM, SC) with varying amounts of silt, clay, marine shell fragments, and cemented sands. Trace amounts of organics were observed within these granular soils at depths ranging from 0 to 4 feet below existing grades at the location of borings B-9 and B-10. A shallow subsurface deposit of Lean CLAY (CL) was encountered at the location of borings B-5 and B-11 at a depth ranging from 4 to 6 feet below existing grades. Additionally, a deposit of Fat CLAY (CH) was encountered at the location of boring B-6 at a depth ranging from about 7 to 7.5 feet and at B-9 at a depth ranging from about 23 to 28 feet below the existing grades. ' Report of Subsurface Investigation and Geotechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G ' Deposits of Marlstone, which appear to be of a limestone formation, with varying thicknesses were encountered at,the location of borings B-6, B-7, and B-8 at depths ' ranging from 30 feet to 53 feet below existing grades and were noted to extend to depths ranging from 38 feet to 58 feet. Finally, during our previous subsurface investigation, 1.5- foot to 2-foot voids were encountered at the location of borings B-7 and B-8 at depths ' ranging from 28 to 32 feet below the existing site grade elevations. It should be noted that a supplemental subsurface investigation (Addendum No. 1) was completed to further delineate the presence of these subsurface voids encountered in these borings. Four (4) ' Cone Penetrometer Test (CPT) soundings were performed as part of Addendum No. 1 within a newly established building footprint which did not encounter these voids. Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 ' (GET Project No. EC09-106G) is included in Appendix IV of this report. The subsurface description is of a generalized nature provided to highlight the major soil ' strata encountered. The records of the subsurface exploration are included on the "Boring Log" sheets (Appendix II) and in the "Generalized Soil Profile" (Appendix III), which should be reviewed for specific information as to the individual borings. The stratifications shown on the records of the subsurface exploration represent the conditions only at the actual ' boring locations. Variations may occur and should be expected between boring locations. The stratifications represent the approximate boundary between subsurface materials and the transition may be gradual or occur between sample intervals. It is noted that the topsoil ' designation references the presence of surficial organic laden soil, and does not represent any particular quality specification. This material is to be tested for approval prior to use. 3.3 Groundwater Information The groundwater level was recorded at the location of borings B-9 through B-12 and as ' observed through the wetness of the recovered soil samples during the drilling operations. The initial groundwater table encountered at these boring locations was measured to occur at depths ranging from 8 to 10 feet below current grades, which corresponds to an ' elevation of about 20.0 feet (MSL). In addition, four (4) temporary piezometers were installed at the boring BMP-1 through BMP-4 locations at the time of drilling and 24 hour groundwater readings were measured to occur at depths ranging from 4.8 to 5.29 feet below current grades (boring locations BMP-1 and BMP-2) which corresponds to an approximate elevation of 27.0 feet MSL and at depths of 9.875 to 9.92 feet below current grades (boring locations BMP-3 and BMP-4) which corresponds to an approximate ' elevation of 20.0 feet MSL. The piezometers were removed following the 24-hour readings and the boreholes were backfilled. ' The soils recovered from the location of borings B-9 through B-12 and BMP-1 through BMP-4 were classified in general accordance with ASTM D 2487 test method. Based on the soil texture classifications located throughout the site, the shallow subsurface soils ' appeared to be relatively homogenous consisting predominantly of SAND (SC, SC-SM, SM, SP-SM, SP). WOM Soludons,'Inc: 1 I Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G November24,2010 , The soil sample colors were used to aid in identifying the estimated normal SHWT at the location of borings BMP-1 through BMP-4. It is noted that soil morphology is not a reliable indicator of the SHWT in drained soils. However, slight color distinctions were observed within the soil samples collected at the location of borings BMP-1 through BMP-4. As such, the normal SHWT depth was estimated to occur at approximately 4 feet below the existing site grade elevation at boring locations BMP-1 and BMP-2 and at approximately 6 feet below the existing site grade elevation at boring locations BMP-3 and BMP-4. The current groundwater levels encountered at the project site and the estimated normal SHWT depths are anticipated to be contributed to the varying site topography and possible perched groundwater conditions specifically at boring BMP-1 and BMP-2 locations. Groundwater conditions will vary with environmental variations and seasonal conditions, such as the frequency and magnitude of rainfall patterns, as well as man-made influences, such as existing swales, drainage ponds, underdrains and areas of covered soil (paved parking lots, sidewalks, etc.). Seasonal groundwater fluctuations of±2 feet are common in the project's area; however, greater fluctuations have been documented. We recommend that the contractor determine the actual groundwater levels at the time of the construction to determine groundwater impact on the construction procedures. 4.0 EVALUATIONS AND RECOMMENDATIONS Our recommendations are based on the previously discussed project information, our interpretation of the soil test borings and laboratory data, and our observations during our site reconnaissance. If the proposed construction should vary from what was described, we request the opportunity to review our recommendations and make any necessary changes. 4.1 Subsurface Voids Subsurface voids approximately 2-feet deep were encountered at the location of the initially completed borings B-7 and B-8 at depths of 28 to 30 feet, respectively below the existing site grade elevations. Subsequently, a supplemental subsurface investigation (Addendum No. 1 to the original feasibility study) was completed to further explore the subsurface soil conditions at the location of the new building site (shifted to the east). Four (4) Cone Penetrometer Test (CPT) soundings were performed as part of Addendum No. 1 within the newly established building footprint which did not encounter these voids. Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G) is included in Appendix IV of this report. The building was again relocated to the west since the time Addendum 1 was completed. The initially drilled borings were plotted onto the new site plan provided by the client. One boring (B-8) was determined to be located within the northwest portion of the newly positioned building footprint. It should be noted that no voids were encountered within the recently completed borings B-9 through B-12 and previously completed borings B-5, B-6 and CPT soundings CPT-1 through CPT-4 to depths of 30 to 36 feet. 1 ' Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G The subsurface voids, where encountered, can be addressed by means of pressure grout placement (injection) to fill the voids and prevent the potential for subsidence from ' occurring and resulting in foundation and/or slab -on -grade settlement. It is recommended that a grout injection specialty contractor develop the number, depths, and locations of the injection points. ' Other options would include shifting the building easterly away from boring B-8; supporting that portion of the building on deep foundations (such as auger cast piles) or assuming ' some risk associated with the subsurface voids and leave the building at the present location. In any case, additional void delineation efforts may be warranted, by means of advancing several CPT probes within the western building area. 4.2 Clearing and Grading ' The proposed construction area should be cleared by means of removing the topsoil, trees, and associated root mat. It is estimated that a cut of up to 14 inches in depth will be required to remove the topsoil. This cut is expected to extend deeper in isolated areas to remove deeper deposits of organic soils, or unsuitable soils, which become evident during ' the clearing. It is recommended that the clearing operations extend laterally at least 5 feet beyond the perimeter of the proposed construction areas. In addition, varying amounts of organics were encountered generally in the upper 4.0 feet of the very loose granular soils at the location of borings B-9 and B-10. Based on our experience with similar heavily wooded areas within the Camp Lejeune military installation, subsurface organics which may include roots, tree limbs and stumps may be present below the current grades. Therefore, an estimated cut depth of up to about 2.0 to 4.0 feet may be required in order to remove surficial and/or subsurface deposits of organic soils, which may become evident during the clearing operation. Accordingly, the subgrade preparations procedures performed during construction, as indicated in Section 4.3 of this report, should include a series of test pit excavations to further evaluate the suitability of these soils to remain in -place for foundation, slab, and/or pavement support. As stated above, the subsurface soils in isolated areas (generally the upper 4.0 feet) recovered at the location of borings B-9 and B-10 contained varying amounts of organics. Accordingly, following the initial clearing, the resulting exposed subgrade will generally be comprised of SAND (SM, SC-SM, and SC) containing an appreciable amount of fines (silt and clay). Accordingly, combinations of excess surface moisture from precipitation ponding on the site and the construction traffic, including heavy compaction equipment, may create pumping and general deterioration of the bearing capabilities of the surface soils. Therefore, undercutting to remove unstable soils and/or soils containing organics may be required. The extent of the undercut will be determined in the field during construction, based on the outcome of the field testing procedures (subgrade proofroll and/or possible test pits). Solutions, Inc." 11 Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G November24,2010 ' Furthermore, inherently wet subgrade soils combined with potential poor site drainage make this site particularly susceptible to subgrade deterioration. Thus, grading should be performed during a dry season if at all possible. This should minimize these potential problems, although they may not be eliminated. The project's budget should include an allowance for subgrade improvements (undercut and backfill with structural fill or Aggregate Base Course material). Control of surface water is very important to the successful completion of the proposed construction. The contractor should plan his grading activities to control surface water and minimize erosion of exposed cut or fill material. This may include constructing temporary berms, ditches, flumes and/or slope drains to intercept runoff and discharge it in a controlled fashion, while complying with state and local regulations. 4.3 Subgrade Preparation Following the clearing operation, the exposed subgrade soils should be densified with a large static drum roller. After the subgrade soils have been densified, they should be evaluated by G E T Solutions, Inc. for stability. Accordingly, the subgrade soils should be proofrolled to check for pockets of loose material hidden beneath a crust of better soil. Several passes should be made by a large rubber -tired roller or loaded dump truck over the construction areas, with the successive passes aligned perpendicularly. The number of passes will be determined in the field by the Geotechnical Engineer depending on the soils conditions. Any pumping and unstable areas observed during proofrolling (beyond the initial cut) should be undercut and/or stabilized at the directions of the Geotechnical Engineer. The prepared subgrade should be sloped to prevent the accumulation and/or ponding of surface water. If the exposed subgrade becomes wet or frozen, the geotechnical engineer should be consulted. Following the proofroll and approval by the engineer, it is recommended that the newly exposed subgrade soils be compacted to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D1557), as tested to a depth of at least 12 inches. The suitability of compacting the natural subgrade soils should be more accurately determined in the field by the G E T Solutions, Inc. representative at the time of construction as the compaction operations could deteriorate the subgrade soil conditions. Accordingly, it is anticipated that this site will require monitoring of the clearing, subgrade preparation, and fill placement procedures by a G E T Solutions, Inc. representative in order to minimize potential deterioration of the natural subgrade soils. The compaction testing of the natural subgrade soils may be waived by the Geotechnical Engineer, where firm and stable bearing conditions are observed during the proofroll. Kom Solutions:, Inc ,c Report of Subsurface Investigation and Geolechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 4.4 Structural Fill and Placement ' Following the approval of the natural subgrade soils by the Geotechnical Engineer, the placement of the fill required to establish the design grades may begin. Any material to be used for structural fill should be evaluated and tested by G E T Solutions, Inc. prior to t placement to determine if they are suitable for the intended use. Suitable structural fill material should consist of sand or gravel containing less than 20% by weight of fines (SP, SM, SW, GP, GW), having a liquid limit less than 20 and plastic limit less than 6, and should be free of rubble, organics, clay, debris and other unsuitable material. The Silty SAND (SM)'and SAND (SP-SM, SP) subsurface soils encountered at the boring locations appear to meet the criteria recommended in this report for reuse as structural fill. ' Additionally, it is anticipated that any soils excavated on -site and proposed to be re -used as backfill, will require stockpiling and air drying in order to establish a moisture content suitable for placement and compaction. Soil deposits excavated at the site and noted to contain significant amounts of organics should not be used as fill and/or backfill within the proposed construction areas. Further classification testing (natural moisture content, gradation analysis, and Proctor testing) should be performed in the field during construction ' to evaluate the suitability of excavated soils for reuse as fill within building and pavement areas. The remaining on -site excavated soils (Topsoil, SANDS with organics, Clayey SAND, and CLAY) are not anticipated to be suitable for re -use as structural fill but may be ' used as fill within green areas. All structural fill should be compacted to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D1557). In general, the compaction should be accomplished by placing the fill in maximum 10-inch loose lifts and mechanically compacting each lift to at least the specified minimum dry density. A representative of ' G E T Solutions, Inc. should perform field density tests on each lift as necessary to assure that adequate compaction is achieved. Backfill material in utility trenches within the construction areas should consist of structural fill (as previously indicated above), and should be compacted to at least 95 percent of ASTM D1557. This fill should be placed in 4 to 6 inch loose lifts when hand compaction 1 equipment is used. Care should be used when operating the compactors near existing structures to avoid transmission of the vibrations that could cause settlement damage or disturb occupants. In this regard, it is recommended that the vibratory roller remain at least 25 feet away from existing structures; these areas should be compacted with small, hand -operated compaction equipment. I I M f I Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 4.5 Shallow Foundation Design Recommendations November24,2010 ' Provided that the subsurface void issues are addressed as described in Section 4.1 and previously stated construction procedures are properly performed, the proposed structure can be supported by shallow spread footings bearing upon firm natural soil or well compacted structural fill material. The footings can be designed using a net allowable soil pressure of 2,000 pounds per square foot (psf). In using net pressures, the weight of the footings and backfill over the footings, including the weight of the floor slab, need not be considered. Hence, only loads applied at or above the finished floor need to be used for dimensioning the footings. In order to develop the recommended bearing capacity of 2,000 pounds per square foot (psf), the base of the footings should have an embedment of at least 24 inches beneath finished grades and wall footings should have a minimum width of 24 inches. In addition, isolated square column footings are recommended to be a minimum of 3 feet by 3 feet in area for bearing capacity consideration. The recommended 24-inch footing embedment is considered sufficient to provide adequate cover against frost penetration to the bearing soils. 4.6 Settlements It is estimated that, with proper site preparation including the subsurface improvements noted above (where required), the maximum resulting post construction total settlement of the proposed building foundations should be up to 1 inch, as contributed by the foundation bearing soils. The maximum differential settlement magnitude is expected to be less than Yz -inch between adjacent footings (wall footings and column footings of widely varying loading conditions), as contributed by the foundation bearing soils. The settlements were estimated on the basis of the results of the SPT borings. Careful field control will contribute substantially towards minimizing the settlements. 4.7 Foundation Excavations In preparation for shallow foundation support, the footing excavations should extend into firm natural soil or well compacted structural fill. Some foundation improvements (undercut) may be necessary to remove unsuitable organic laden soils particularly within the vicinity of borings B-9 and B-10 where up to 4.0 feet of Silty SAND (SM) with organics were encountered. All foundation excavations should be observed by G E T Solutions, Inc. At that time, the Geotechnical Engineer should also explore the extent of excessively loose, soft, or otherwise unsuitable material within the exposed excavations. Also, at the time of footing observations, the Geotechnical Engineer may find it necessary to make hand auger borings or use a hand penetration device in the bases of the foundation excavations. If pockets of unsuitable soils requiring undercut are encountered in the footing excavations, the proposed footing elevation should be re-established by means of backfilling with "flowable fill", an open graded washed stone (such as No. 57 stone), or a suitable structural 1 ---- - GEC �. I ' Report of Subsurface Investigation and Geotechnical Engineering Services November24,2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G ' fill material compacted to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D 1557), as described in Section 4.4 of this report, prior to ' concrete placement. This construction procedure will provide for a net allowable bearing capacity of 2,000 psf. Immediately prior to reinforcing steel placement, it is suggested that the bearing surfaces of all footings be compacted using hand operated mechanical tampers, to a dry density of at least 95 percent of the Modified Proctor maximum dry density (ASTM D 1557) as tested to a depth of 12 inches, for bearing capacity considerations. In this manner, any localized ' areas, which have been loosened by excavation operations, should be adequately recompacted. The compaction testing in the base of the footings may be waived by the Geotechnical Engineer, where firm bearing soils are observed during the footing inspections. Soils exposed in the bases of all satisfactory foundation excavations should be protected ' against any detrimental change in condition such as from physical disturbance, rain or frost. Surface run-off water should be drained away from the excavations and not be allowed to pond. If possible, all footing concrete should be placed the same day the excavation is ' made. If this is not possible, the footing excavations should be adequately protected. 4.8 Floor Slabs The floor slab may be constructed as a slab -on -grade member provided the previously recommended earthwork activities and evaluations are carried out properly. It is recommended that the ground floor slab be directly supported by at least a 4-inch layer of relatively clean, compacted, poorly graded sand (SP) or gravel (GP) with less than 5% passing the No. 200 Sieve (0.074 mm). The purpose of the 4-inch layer is to act as a capillary barrier and equalize moisture conditions beneath the slab. It is recommended that all ground floor slabs be "floating'. That is, generally ground ' supported and not rigidly connected to walls or foundations. This is to minimize the possibility of cracking and displacement of the floor slabs because of differential movements between the slab and the foundation. Slab -on -grade post construction ' settlements should be limited to 1/2-inch or less. The slabs can be designed with the use of a subgrade modulus on the order of about 150 psi/in. I It is also recommended that the floor slab bearing soils be covered by a vapor barrier or retarder in order to minimize the potential for floor dampness, which can affect the performance of glued tile and carpet. Generally, use a vapor retarder for minimal vapor resistance protection below the slab on grade. When floor finishes, site conditions or other considerations require greater vapor resistance protection; consideration should be given to using a vapor barrier. Selection of a vapor retarder or barrier should be made by the Architect based on project requirements. 12 - —GET - I Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 4.9 Seismic Design Recommendations: November 24, 2010 1 Based on our experience with similar construction projects in the general area of the project site, and in accordance with the previously completed Addendum No. 1 to the original feasibility study reported on the date of February 19, 2010 (GET Project No. EC09-106G included in Appendix IV of this report) and the NC Building Code; Chapter 16, this site would be classified as a site Class C, based on which seismic designs should be incorporated. This recommendation is based on the data obtained from the 75-foot deep SPT borings, our experience with 100-foot deep CPT soundings and SPT borings performed within the vicinity of the project site, as well as the requirements indicated in the North Carolina State Building Code (2006 International Building Code). 4.10 Soil Permeability Four (4) infiltration tests were performed at boring locations BMP-1 through BMP-4 (one test at each boring location). The tests were performed at depths ranging from 2 to 5 feet below existing site grade elevations. The borehole was prepared utilizing an auger to remove soil clippings from the base. Infiltration testing was then conducted within the vadose zone utilizing a Precision Permeameter and the following testing procedures. A support stand was assembled and placed adjacent to the borehole. This stand holds a calibrated reservoir (2000 ml) and a cable used to raise and lower the water control unit (WCU). The WCU establishes a constant water head within the borehole during testing by use of a precision valve and float assembly. The WCU was attached to the flow reservoir with a 2-meter (6.6 foot) braided PVC hose and then lowered by cable into the borehole to the test depth elevation. As required by the Glover solution, the WCU was suspended above the bottom of the borehole at an elevation of approximately 5 times the borehole diameter. The shut-off valve was then opened allowing water to pass through the WCU to fill the borehole to the constant water level elevation. The absorption rate slowed as the soil voids became filled and an equilibrium developed as a wetting bulb developed around the borehole. Water was continuously added until the flow rate stabilized. The reservoir was then re -filled in order to begin testing. During testing, as the water drained into the borehole and surrounding soils, the water level within the calibrated reservoir was recorded as well as the elapsed time during each interval. The test was continued until relatively consistent flow rates were documented. During testing the quick release connections and shutoff valve were monitored to ensure that no leakage occurred. The flow rate (Q), height of the constant water level (H), and borehole diameter (D) were used to calculate KS utilizing the Glover Solution. 13 -GE - 1 11 I ' Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G November 24, 2010 Based on the field testing and corroborated with laboratory testing results (published values compared to classification results), the hydraulic conductivity of the shallow soils is tabulated below (Table III) and is presented on the "Hydraulic Conductivity Worksheet" (Appendix V), included with this report. Table III - Infiltration Test Results Boring Boring depth ft * Water depth ft * Percent Silt and/or Clay Ksat Value cm/sec Ksat Value in/hr Ksat Class BMP-1 2.0 4.8 31.1 7.23 x 10 0.102 Moderately Low BMP-2 2.0 5.29 21.2 8.94 x 10 1.267 Moderately High 6MP-3. 4.0 9.875 24.6 2.27 x 10 0.321 Moderatel High BMP-4 5.0 9.92 17.5 6.33 x 10 0.898 Moderatel Hi h The boring test and water depths noted above are referenced from below the existing site grade elevations. 5.0 CONSTRUCTION CONSIDERATIONS ' 5.1 Drainage and Groundwater Concerns It is expected that dewatering may be required for excavations that extend near or below 1 the existing groundwater table. Dewatering above the groundwater level could probably be accomplished by pumping from sumps. Dewatering at depths below the groundwater level may require well pointing. It would be advantageous to construct all fills early in the construction. If this is not accomplished, disturbance of the existing site drainage could result in collection of surface ' water in some areas, thus rendering these areas wet and very loose. Temporary drainage ditches should be employed by the contractor to accentuate drainage during construction. ' If water collects in foundation excavations, it will be necessary to remove water from the excavations, remove saturated soils, and re -test the adequacy of the bearing surface soils to support the design bearing pressure prior to concrete placement. 5.2 Site Utility Installation The base of the utility trenches should be observed by a qualified inspector prior to the pip and structure placements to verify the suitability of the bearing soils. If unstable bearing soils are encountered during installation some form of stabilization may be required to ' provide suitable bedding. This stabilization is typically accomplished by providing additional bedding materials (NCDOT No. 57 stone). In addition, depending on the depth of the utility trench excavation, some means of dewatering may be required to facilitate the utility installation and associated backfilling. All utility excavations should be backfilled with structural fill, as described in Section 4.4 of this report. 14-- - GET Report of Subsurface Investigation and Geotechnical Engineering Services P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G 5.3 Excavations November24,2010 , In Federal Register, Volume 54, No. 209 (October, 1989), the United States Department of Labor, Occupational Safety and Health Administration (OSHA) amended its "Construction Standards for Excavations, 29 CFR, part 1926, Subpart P". This document was issued to better insure the safety of workmen entering trenches or excavations. It is mandated by this federal regulation that all excavations, whether they be utility trenches, basement excavation or footing excavations, be constructed in accordance with the new (OSHA) guidelines. It is our understanding that these regulations are being strictly enforced and if they are not closely followed, the owner and the contractor could be liable for substantial penalties. The contractor is solely responsible for designing and constructing stable, temporary excavations and should shore, slope, or bench the sides of the excavations as required to maintain stability of both the excavation sides and bottom. The contractor's responsible person, as defined in 29 CFR Part 1926, should evaluate the soil exposed in the excavations as part of the contractor's safety procedures. In no case should slope height, slope inclination, or excavation depth, including utility trench excavation depth, exceed those specified in local, state, and federal safety regulations. We are providing this information solely as a service to our client. G E T Solutions, Inc. is not assuming responsibility for construction site safety or the contractor's activities; such responsibility is not being implied and should not be inferred. 6.0 REPORT LIMITATIONS The recommendations submitted are based on the available soil information obtained by G E T Solutions, Inc. and the information supplied by the client and their consultants for the proposed project. If there are any revisions to the plans for this project or if deviations from the subsurface conditions noted in this report are encountered during construction, G E T Solutions, Inc. should be notified immediately to determine if changes in the foundation recommendations are required. If G E T Solutions, Inc. is not retained to perform these functions, G E T Solutions, Inc. can not be responsible for the impact of those conditions on the geotechnical recommendations for the project. The Geotechnical Engineer warrants that the findings, recommendations, specifications or professional advice contained herein have been made in accordance with generally accepted professional geotechnical engineering practices in the local area. No other warranties are implied or expressed. ,5 GEC- 1 I ' Report of Subsurface Investigation and Geolechnical Engineering Services November24, 2010 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: JX10-113G After the plans and specifications are more complete the Geotechnical Engineer should be provided the opportunity to review the final design plans and specifications to assure our ' engineering recommendations have been properly incorporated into the design documents, in order that the earthwork and foundation recommendations may be properly interpreted and implemented. At that time, it may be necessary to submit supplementary ' recommendations. This report has been prepared for the exclusive use of M.B. Kahn Construction Company, Inc. and their consultants for the specific application to the proposed P-1310 Pre -Trial Detainee Facility project located within the Camp LeJeune ' military installation in North Carolina. ,- _ — 16 ET APPENDICES I BORING LOCATION PLAN II BORING LOGS III GENERALIZED SOIL PROFILE IV ADDENDUM NO. 1 TO THE ORIGINAL FEASIBILITY STUDY REPORTED ON THE DATE OF FEBRUARY 19, 2010 (GET Project No. EC09-106G) V HYDRAULIC CONDUCTIVITY WORKSHEET VI CLASSIFICATION SYSTEM FOR SOIL EXPLORATION IN AMIRR"Immi GET " •'^-, - c„v.e.x.o r.o.,,,..:•a.rnx„� BORING LOG B-rj PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MS' DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-30-09 DEPTH TO WATER - INITIAL`: 4 9' AFTER 24 HOURS: —X CAVING> -C c wo n m E a y o Description n n o z >Plastic n H m n z o TEST RESULTS Limit H Liquid Limit Moisture Content -• N-Value - 10 20 30 40 50 60 70 0 3 6 8 10--- 12 7 7 7 7 4 6 3.1 14 inches of TOPSOIL ... ... 1 24 SS 1 z . . . . .0.: _.: .:...:. :...: . ......... ........ .. --- .- .'. .-' . .. ...... ...... :...:...:.. :...: :.. :. ....... _. ..... .... :.. ........... ......... .... . . ...... ... ........ ........ 1.2 Tan, moist, Silty fine SAND (SM), very loose Gray, moist, Silty, Clayey SAND (SC-SM), loose 4 Mottled Gray -Reddish Tan, moist, Lean CLAY (CL), medium stiff 6 Mottled Tan -Reddish Tan, moist to wet, Silty fine SAND (SM), very loose to loose Light Gray and with clay from 8 to 15 feel Wet from 9feet Light Tan from 10 feet Reddish Tan from 13 feet With day from 23 to 28 feet Dark Gray from 28 feet 38 Dark Gray, wet, poorly graded fine to medium SAND (SP-SM) with .: :::: ;::: ..... 2 3 4 24 24 20 SS SS SS 2 3 4 a 4 4 s 5 6 zs z 5 !I' 5 16 SS 6 20 -- 10 4 " 6 24 SS 3 3 4 [ i 7 21 SS a a 4 15 5 8 14 SS 3 3 4 m 20 3 s :::: 9 16 SS 3 4 4 zs : ::: 10 18 SS z z z 0 — 3o ra 11 20 SS 2 3 3 4 5 35 .`.'.'." P 4 — Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample - - --- -HA-= Hand Auger Sample— BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the Field in general accordance with ASTM D 1586, 4; GET '•` ' •' `�.:.w'"' BORING LOG B-rj PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: JMT Inc. PROJECT LOCATION: Camp LeJeune North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-30-09 DEPTH TO WATER - INITIAL-: s 9' AFTER 24 HOURS: ? _ CAVING> L i w w m m p E — w m p Description m C� m n E Z rn v o a > E> woo d o. °' E H - 3 [o o v m a j j Z\ oo "� #b TEST RESULTS Plastic Limit H Li uid Limit g Moisture Content- • N-Value- 10 20 30 40 50 60 70 .10 12 silt, medium dense -48 Gray, wet, Silty fine SAND (SM) with trace Cemented Sand, dense 53 Gray, wet, Silty fine SAND (SM) mixed with Cemented Sand and trace Marine Shell Fragments, dense 58 Gray, wet, Silty, Clayey SAND (SC-SM), dense 63 Gray, wet, Silty fine SAND (SM), dense to very dense ra:rr 1!C L r i :g i1 Y [1: +:Ef ri .I:,: f i [G I'64r1 ii!jE 12 19 SS a 12 12 19 36 33 38 46 63 48 ..: _.:...:... ' .:...:...: ...:. ..:. :.. :.. .. ..:...:...: ..�...:. .f.. ;.. 14 13 18 SS 8 18 13 45 14 19 SS 13 1] 19 24 so 18 50 ?iiip 15 24 SS 12 16 1] 13 -z 55 ....: — 16 — 20 SS y 15 2] 26 1s 0p 60 17 17 SS 14 19 27 32 — 35 20 65 18 24 SS 21 34 50, 40 22 70 i!iii I 19 -- 20 SS n q3 d5 75 Boring terminated at 75 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample -- — --- -- --- --- - -- ---HA'= Hand Auger Sample'- BS = Bulk Sample PAGE 2 o/ 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GET BORING LOG B-6 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29' MSI DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary(wash) DATE: 3-30-09 DEPTH TO WATER -INITIAL-: Q¢ 11' AFTER 24 HOURS: a CAVING> L c wo o. v E s m o w Description LEa C� u y o rn Z a o vE�i d a w vE�i t— 3 tO m n w z o v TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value- 10 20 30 40 50 60 70 0 0 2 6 14 11p:- 10 s 8 6 s 25 32 17. 18.7 10 inches of TOPSOIL 1 24 ss 1 1 . � .... .. ..... :. :...:.. I. - : .:...: . .:...: ..:...:...: .: . 1 .I I: 1' . . . . . . . Tan, moist, Silty fine SAND (SM), very loose to loose Perched water encountered at 3.5 feet 2 18 ss 2 3 5 2s 2 5 Reddish Tan, moist, Silty fine SAND (SM) with clay to Silty, Clayey. SAND (SC-SM), loose to medium dense 6-inch Fat CLAY (CH)lense from 7lo 7.5 feet Tan, moist to wet, Silty fine SAND (SM), loose Wet from 11 feet Reddish Tan from 13 feet Dark Gray and With clay from 23 feet 28 Light Gray, wet, Silty fine SAND (SM) mixed with Marlstone, medium dense 33 Light Gray, wet, MARLSTONE, dense 38 Gray, wet, Silty fine SAND (SM) with Cemented Sand, dense to very 3 24 ss a a 8 4 20 ss 4:... s 5 20 5 s 20 21 ss ss 4 s 4 3 4 4 0 - 15 [[ ..... 7 15 ss 3 n 4 15 6 10 8 16 ss 2 3 5 2 5 e ..... ..... ! s za ss 2 3 3- 25 " . 10 16 ss y 13 12 16 0 30 10 11 22 ss 15 n 16 -5 35 1 1 n 23 .10 Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample ----- -- —'— ' - —HA'= Hand Auger Sample— BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. ti c VET m..+.,4.1r•b....,...W.>Hi�, BORING LOG B-6 PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary(wash) DATE: 3-30-09 DEPTH TO WATER -INITIAL': V, 11' AFTER 24 HOURS: 3 CAVING> -L c m wo o. m E n m o Description o a m n o N z o- > b n m rn H 3 �o m n b z o v TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value- ��/ j 10 20 30 40 50 60 70 12 40 dense With trace Marlstone from 53 to 59 feet : 12 24 as 90 51 43 47 47 45 77 85 100 ..:...: ..:.. ..:...:. :... :...:...:... ........ ... ... 5 ' -15 14 " "19 13 22 ss 12 za 26 45 16 -20 ..... 14 20 ss ie 21 33so 50 -25 15 24 ss 14 25 22 55 16 -30 16 24 ss 12 26 25 60 20 - 5 3 Gray, wet, poorly graded fine to medium SAND (SP-SM) with silt to Silty fine SAND (SM), very dense :' ` » 22 ss e 41 36 32 65 E 10 18 24 ss 21 B 50• 22 70 ... '45 E 19 10 ss So So 75 Boring terminated al 75 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample -------- -- — -- ----HA-- Hand Auger Sample BS = Bulk Sample PAGE 2 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GET BORING LOG B-% PROJECT: P-1310: Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MS' DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 DEPTH TO WATER - INITIAL': -IV, 12' AFTER 24 HOURS: ; CAVING> -C q > 0i L m y v p E o, m y y p Description u n ER r? m n o E Z to n W E$ rn 01n a 01 E H- 3 tO o y m n y m z o v TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value - 10 20 30 40 50 60 70 0 0 4 6 12l: 11 9 8 6 7 9 0 77 7. 15.�; 12 inches of TOPSOIL 1-.... Tan, moist, poorly graded fine to medium SAND (SP-SM) with silt, very loose Tan, moist, Silty, Clayey SAND (SC-SM) to Clayey SAND (SC) with silt, loose to medium dense'- Perched water encountered at 4 feet Mottled Light Tan -Reddish Tan from 4 feet' Reddish Tan from 8 feet 10 Reddish Tan, moist to wet, Silty fine SAND ISM), loose Wet from 12 feet Reddish Tan, wet, Silty, Clayey SAND (SC-SM), loose 18 Reddish Tan, wet, Silty fine SAND (SM) with clay, loose Gray from 23 feet Soil Void Extending from 28 to 29.5 feet 29.5 ... 1 24 ss z 2 ' . . t-1 I: ... I:...:...:.. :.. :...: .:. .: ..:...:...:...:. :.. :.. :...:...[...:...: t.. l . ..: ..:. ..:...: .. :.. - . ". " .. ....................... ... .... .... ........... .... . .. .' . " ...... ....... ...... . . "' 2 24 $s 3 3 a — 25 2 5 3 2a ss 4'I: 6 0 — 4 24 ss 5 6 5 5 5 6 24 24 ss ss 3 s 5 4 4 0 10 4 7 15 ss 3 3 is 8 21 ss 34 3 4 5 10 20 5 iiiii 9 20 as 3 4 5 5 25 10 10 ss word WOH s 0 30 Light Gray, wet, MARLSTONE with Silty Sand, Cemented Sand, antl Marine Shell Fragments, very dense Light Gray, wet, Silty fine SAND (SM) with Cemented 38 Sand, very _ — — 10 11 18 66 1e 32 as 26 12 20 5 35 — .. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST =Shelby Tube Sample ---------- —' "—HA'='Hand Auger Sample— BS = Bulk Sample PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586 c GET PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. �,...na.r..,,,,.,.�•nu:�, BORING LOG B-% PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29.5' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 DEPTH TO WATER - INITIAL`: Az 12' AFTER 24 HOURS: a CAVING> -C . c c 0 .. C v o E L n o Description U a m N n o E 6 W n> E g oe m n d 0 F- w- 3 o m n ? > Z oo o TEST RESULTS Plastic Limit H Liquid Limit Moisture Content- • N-Value - 10 20 30 40 50 60 70 -10 12 40 dense 43 Light Gray, wet, MARLSTONE, dense 48 Gray, wet, Silty fine SAND ISM) with Cemented Sand, dense 53 Light Gray, wet, MARLSTONE, very dense 8 Light Gray, wet, Silty fine SAND ISM) with Cemented Sand, dense 63 Light Gray, wet, Silty fine SAND ISM), very dense Gray from 68 feet 12 22 ss M 28 53 43-- 57 31 80 65 100 ...:...:...:...:..... .. ............ .... . ....... ..... ... ' .. ..:...;...I ...:...:...:...:... 100' 13 24 as y 17 9 26 29 14 16 t5 45 14 16 ss37 16 22 15 12 20 50 :. =qs 15 20 ss t4 26 31 39 25 55 16 24 as 14 is 16 25 18 be :. �'�" 30 17 24 ss 9 36 94 5e. 20 as 65 — — i 18 24 ss 177 37 44 ao 22 70 75 19 14 — as 54 50 <s Boring terminated at 75 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample - --'-- HA'=Hand-Auger Sample-- BS = Bulk Sample 1—W WOH — We phi of Hammer PAGE 2 of 2 Standard Penetration Tests were performed in the field in ,general accordance with ASTM D 1566. GET PROJECT: P-1310 Pre -Trial Detainee Facility +' CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30' MSL . BORING LOG DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 ' B-8 DEPTH TO WATER - INITIAL-: 12' AFTER 24 HOURS: _ _ CAVING> -C � L d o. w n m a o a 0 �- 3 tD m m uc oJNV2' TEST RESULTS Limit H Liquid Limit 0 E❑ Description m l2 E Z rn E> N m E N H o y Ei n Z vture Content - • ' of lue - 10 o a 20 30 40 50 60 7012 inches of TOPSOIL1 1 24 ss 23 Tan -Brown, moist, Silty fine SAND (SM), very loose to loose 3 z2 24 55 3 64 4 Light Gray, moist, Silty, Clayey SAND (SC-SM), loosea3 49 :.........7 24 ss 17. .... e 2 Light Gray, moist, Silty fine SAND (SM), loose to medium dense Perched water encountered at 6 feel424 ss 116 4 !o to 5 24 ss 3 3 7 Light Gray, moist to wet, Silty fine SAND (SM) with trace clay, loose6 t t.. 24 ss 47.t.. ..1. .t...t.. — Wet from 12 feel 4 _ — ° Reddish Tan from 13 feet 3 ' 7 24 55 j 6 .. ...... ......: .:.:. 16 ° ....... ....:.. .: ...:...:...: .. :...:. .:.. Light Gray, wet, poorly graded fine to medium SAND (SP-SM) with :: s 4 I 6 silt to Silty fine SAND (SM), very loose to loose 8 20 as 3 7 - Soil Void extending from 30 to 32 feet Mottled Dark Gray -Tan, wet, Silly fine SAND (SM), very loose Light Gray, wet, Silty fine SAND (SM) with Cemented Sand and Marine Shell Fragments, very dense .. .. ... .. ..... .. ... ... :.. :..:...:...: ..:..:. 3 9 21 as u 8 ..: ..:...:...:. :.. . s t 10 19 as s 4 :...:...: ..:...:.. :.. 3 11 124 I ss I 31 177 46 Dark Gray, wet, Silty fine SAND (SM), dense to very dense 11;1;liljl!l I I I zt I I J Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan t SS = Split Spoon Sample ST = Shelby Tube Sample HA ='Hand Auger Sample — AS a R„14 SI. PAGE 1 of 2 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GET PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. PROJECT LOCATION: Camp LeJeune North Carolina PROJECT NO.: EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30' MSL DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 DEPTH TO WATER -INITIAL*: S 12' AFTER 24 HOURS: 3 CAVING> -C BORING LOG B-8 g w = v o E -- Q Description u a n o N Z a> to m o- m VE�i ~ N 3 'o m n w 2 Z oo v TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - • N-Value- 10 20 30 40 50 60 70 -10 12 40 Light Gray from 43 feet" Mixed with Cemented Sand from 43 to 45 feet 57 Gray, wet, poorly graded fine to medium SAND (SP-SM) with silt to Silty fine SAND (SM), dense to very dense ; 12 24 as 26 47 39 45 63 33 63 58 92 .:. .:...:... ..:...:...:...:...:........ . .:...:...:. :... 2: 14 :' 13 ..... 20 as 15 zz 31 -15 45 -z0 14 ::[:: 15 ss 12 za 22 16 50 ws P 15 14 ss 16 36 32 -25 55 . 16 16 :::: 16 ss 1z is 20 ws 20 17 17 as 1e 38 46 -35 65 — 18 24 as 9 28 37 <0 22 70 — --- 7 : 19 24 55 36 420 5 45 Boring terminated at 75 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan SS = Split Spoon Sample ST = Shelby Tube Sample - --- ------------------_HA '=Hand 'Auger Sample-' BS = Bulk Sample no may not be indicative 0 VVOH - We ant of Hammer PAGE 2 of 2 Standard Penetration Tests were performed in the Field in general accordance with ASTM D 1586. GET PROJECT: P-1310; Pre -Trial Detainee Facility CLIENT: JMT, Inc. ._ PROJECT LOCATION: Camp LeJeune, North Carolina PROJECT NO.:. EC09-106G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28' MSL BORING LOG DRILLER: J. Brown (G.E.T.) LOGGED BY: G. Stalls, P.E. DRILLING METHOD: Mud Rotary (wash) DATE: 3-31-09 IN FA DEPTH TO WATER - INITIAL': S 9' AFTER 24 HOURS: d15 _ CAVING> L m m o TEST RESULTS Plastic Limit H Liquid Limit n d m n v w Description n m n o E z o- E$ E o u ' w o E �, o rn m a z\ Moisture Content -• N-Value - 10 inches of TOPSOIL ;;; 2 1 24 ss 2 4 Tan -Gray, moist, poorly graded fine to medium SAND (SP-SM) with "$'f y r z silt, very loose 4 5 Tan, moist, Clayey SAND (SC) with silt, loose to medium dense 2 24 ss 5 10 Perched water encountered at 3 feet: 4 Mottled Light Gray -Reddish Tan from 4 feet 3 ...... 3 16 ss c 11 Reddish Tan, moist to wet, Silty fine SAND (SM) with clay, loose 4 18 ss iws 9 4 2 41' Wet from 9feet 5 t5 ss 36 0,, 43 Mottled Gray -Reddish Tan, wet, Clayey SAND (SC) with silt, loose x:. 3 6 16 ss 5 a 4 13 �r4 9 Reddish Tan, wet, poorly graded fine to medium SAND (SP-SM) with 4 silt, loose rr°cv 12 ss 4 a 15 6 Borino terminated at 15 ft. Notes: Existing site grade elevations estimated based on topographic information provided on the project site plan j 1 1 . :..:...: ..:...:...: ..:...:... ..:.. :. .:.. :.. PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, d GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G -- BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-9 DEPTH TO WATER - INITIAL': S 9 AFTER 24 HOURS: E CAVING> L g L U v W 0o TEST RESULTS Plastic Limit H Liquid Limit > d y$ n v Description E m a o E Z a> E a °1 E 3 'o o m # W a E w �, o m rn rn I- m n Z\ Moisture Content - e N-Value - 10 20 0 4 50 60 70 a o 4 inches of Topsoil woH 1 11 Ss woH woH O .3 Brown, moist, Silty fine to medium SAND (SM) with organics, Very Loose woH 2 11 SS woH 2 2$ 4 2 7 2. /i j 4 5 Light gray, moist, Silty Clayey One to medium SAND (SC-SM), LoosE 3 22 SS 3 ° 2 ° : 1 / I\ Tan, moist, Poorly Graded fine to medium SAND (SP-SM) with trace'�:��'ti Silt, Loose ;j:r{ 3 s 8 Tan, wet, Silty fine to medium SAND (SM) , Very Loose _ 5 24 SS 2 2 4 5.1.; 1 2 10 2 Tan and orangish brown, wet, Silty fine to medium SAND (SM) with trace Clay, Very Loose E ... 6 22 SS 2 2 4 :\ ° 1 1'irr 2 \ \ Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose 2 1 a:f[ 7 18 SS 3 6 /- { 15 rxr1: 4 AlC( C 4Ctl l la 1: uI[- 4[1 3 1 16i i i ra:[1: 8 20 SS 3 6 j\ ' 6 2 is°i1 L n:il. 3 /... A: •i d(i i \ 23 \: Gray, wet, Fat CLAY (CH) with trace SAND, Very S000r 9 23 SS o 0 1:. 25 28 Dark gray, wet, Poorly Graded fine to coarse SAND (SP-SM) with trace Silt, Very Loose '� "� i i Ni L+ 10 23 SS 3 1 1 2 0 10 3 Boring terminated at 30 O. 3$ -10 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample ----- -- —---HA'=-Hand Auger Sample — BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GETPROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G w.r-a.l BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-1 U DEPTH TO WATER -INITIAL-: 8 8 AFTER 24 HOURS: a CAVING> _L n n °1 fD w oo TEST RESULTS > -� w m w a w w Description n m o E Z n> E> E 0 y m u Plastic Limit H Liquid Limit w i p E o ro O N N W y 1_ in n z Moisture Content - • tLI (ifN-Value o - 10 20 30 40 50 60 7 0 0 8 inches of Topsoil 1 23 SS p 3 .6V1 Brown, moist, Silty fine to medium SAND (SM) with trace organics, Very Loose 2 z 25 2 21 SS 3 5 Light gray and orangish brown, moist, Silty fine to medium SAND ISM) with trace Clay, Loose 2 5 3 21 SS 2 5 2 2 4.� j . t-t Light gray and orangish brown, moist, Clayey fine to medium SAND::: (SC), Loose 4 24 ss a 4 Tan and orangish brown, wet. Silty fine to medium SAND (SM) with trace Clay, Loose [ ?? 5 27 SS a 3 6 -' 10 3 4 0 Tan and orangish brown, wet, Clayey fine to medium SAND (SC), Very Loose 6 24 SS 2 2 1 3 Orangish brown, wet, Silty fine to medium SAND ISM). Very Loose 5 y 1 7 18 SS p 4 15 8 2 10 5 20 Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Very Loose "VI. 8 16 SS 1 2 2 ii tL 7?a [ Cf•tl iJar 'i[uri 2 .- .-..- 9 18 SS 25 F{1 ]u:rt I.J:t}. Jxt r :...: .: ...:. .:.. . 0 28 Gray, wet, Poorly Graded fine to coarse SAND (SP-SM) with traces Silt, Very Loose ' ' a. t i f Y n f 10 19 SS woN wort wort 1 Boring terminated at 30 ft. 35 -10 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample ---- --- ----- --�-- -HA-=HandAuger Sample BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GETPROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 29 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-11 DEPTH TO WATER - INITIAL`: $ 9 AFTER 24 HOURS: T _ CAVING> L PAS C� w _ o o TEST RESULTS Plastic Limit H Liquid Limit " m Description n o E z E$ E o y A a > W m v o E m o 0 fin W m n z V Moisture Content - o Co N-Value - 10 20 30 40 50 60 70 4 inches of Topsoil 2 1 24 SS 2 4 .34 Brown, moist, Silty fine to medium SAND (SM), Very Loose 2 Orangish brown, moist, Silty fine to medium SAND (SM), Very Loos 2 22 SS 2 3 25 a Light gray, moist, Sandy Lean CLAY (CL), Medium Stiff ? 3 23 SS 2 2 3 5 %< 2 2 7 Light gray, moist to wet, Silty fine to medium SAND (SM) with trace to little Clay, Very Loose to Loose !;;! ; ; 4 24 SS 3ne 3 n 5 2 zo 5 20 SS 2 4 .: ..: .: _.:. .:...: .. 10 3 3 6 24 SS 2 4 A 2 15 Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Very Loose to Loose xt r r+ 7 zz SS 2 2 a 2 GltS1: i rtt 16:ii 2 10 :f i'i: 8 21 SS 2 5 2 I a:n i afir r 1:11' 1:Ctl V:Sf 3 5 1:r.[r 9 18 SS 3 zs e a: n' t{tl I:I ( f I:4[f 1 o 10 19 SS 2 10 Boring terminated at 30 ft. -5 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample - HA = HandAugerSample BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GET PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G �.,.® BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30 MSL BORING LOG DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 B-12 DEPTH TO WATER -INITIAL*: $ 10 AFTER 24 HOURS: a CAVING> -C r_ v y o TEST RESULTS Plastic Limit H Liquid Limit a m m Description o. a o Z a> �- w 0 o E o„ N N N m n Z Moisture Content - o N-Value- 10 20 30 40 50 60 70 30 o a 4 Inches of Topsoil 2 [ 1 24 SS 3 3 6 7 23 ' j: o .3 Brown, moist, Silty fine to medium SAND ISM), Loose Light gray and orangish brown, moist, Silty fine to medium SAND (SM), Loose 2 20 SS 3 4 3 4 %z % 6' 25 5 Light gray, moist, Silty fine to medium SAND ISM) with little Clay, Very Loose 3 z2 SS 2 2 2 3 8 Tan, moist, Poorly Graded fine to medium SAND (SP-SM) with trace Sill, Loose uiii. .vc[r y3.Ef 4 23 SS 2 4 nar r) 5 2 5 19 SS 3 7- 20 10,, 10 Tan and orangish brown, moist to wet, Poorly Graded fine to mediu SAND (SP-SM) with trace Silt, Very Loose to Loose 16i i f n: i 6 24 SS 3 3 3 3 6 ir L01. 2 2 i i,ir 7 20 SS 3 4 s 1 i.r1. afii : n 2 XLIr :ii }iril !]i[P l :rlr 4 b i 8 19 SS 2 2 10 2 Tr[ 2 1 :plj 2 Orangish brown, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Sill, VeryLoose 1';t i f ri:[t: Gr[ 9 23 SS 2 1 3 5 2 u:ii. 2 a:cr r e n:[r r is[1r 2 10 24 SS 0 30 t t 10 Boring terminated at 30 ft. -s Notes: SS = Split Spoon Sample ST =Shelby Tube Sample -- -- "—_HA '='Hand Auger Sample BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. 'GET BORING LOG BMP-1 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28 MSL DRILLER: GET Solutions, Inc. LOGGED BY: gwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER -INITIAL': S 8 AFTER 24 HOURS: a 4_8 CAVING> L � O w 2 L p E n m Description U m d E o z w2,m o. > E$ 0, a E F- ' o m n y Z\ oo TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - o N-Value - 10 20 30 40 50 60 70 0 0 9 8� 8 8 1 1 1 31.1 2 inches of Topsoil T ': 1 2 24 24 SS SS 3 4 4%: <%j a ° o . . MR, i .1 Dark brown, moist, Silty fine to medium SAND (SM), Loose 2 Grayish brown, moist, Silty fine to medium SAND (SM), Loose Estimated SHWT @ 4-feet below site grade 2 6 3 23 SS 4 3 3 Light gray and orangish brown, moist, Silty fine to medium SAND (SM) with trace Clay, Loose 20 2 Tan, moist, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose 1;t;ij n:i1: '11f 4 24 SS 3 44 n Gray, moist, Silty fine to medium SAND (SM) with some Clay, Very Loose 5 24 SS ' ° 0 ° 10 Gray, moist, Silty fine to medium SAND (SM), Very Loose 12 Gray, wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Very Loose ....' L?: F!. ; t v 1pa [ 6 24 SS o z 1s 7 20 SS 1 4 15 Boring terminated at 15 ft. 6 10 20 8 25 0 10 35 -i Notes: SS = Split Spoon Sample ST = Shelby Tube Sample - --- - ----- ——HA=Hand 'Auger Sample— BS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. GET BORING LOG BMP-2 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 28 MSL DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER -INITIAL-: S 8 AFTER 24 HOURS: a 5.29 CAVING> S D > 'w � L d w d o E L aai p Description V L m d o. E Z to N v E > E In , N o o- E �- y c 3 0 o v> m a j z o O �' \ TEST RESULTS Plastic Limit H Liquid Limit q Moisture Content- • N-Value - 10 20 30 40 50 60 70 0 0 7 8' 6 7 4 16/ 7 4 inches of Topsoil 24 SS 3 3 3 y V j % .3j Brown, moist, Silty fine to medium SAND (SM), Loose Estimated SHWi @ 4-feet below site grade Light gray and orangish brown, moist to wet, Silty fine to medium SAND (SM) with trace Clay, Very Loose to Loose -10 Light gray to tan, moist, Poorly Graded fine to medium SAND (SP- SM) with trace Silt, Loose to Medium Dense 2s ' 2 3 23 SS SS 3 ° e 3 2 4 23 SS 3 3 d 20 9:(1: 5irr :rrt 11'rl t'rr 5 6 24 24 SS SS 3 2 5 5 s 1 d 5 7 24 SS 3 n Boring terminated at 15 ft. 10 20 s e z 0 35 .10 Notes: SS = Split Spoon Sample ST = Shelby Tube Sample -- --'—'- ----' _HA '='Hand -Auger Sample— SS = Bulk Sample PAGE 1 of 1 Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586, GETPROJECT: ,, ``f`' -• BORING LOG BMP-3 P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Lejeune North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30 MSL DRILLER: GET Solutions, Inc. LOGGED BY: qwh DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER - INITIAL': S 13 AFTER 24 HOURS: 3 9.875 CAVING> f- o 19 W d aai v p E a'm w m p Description n C7 n o E Z N o. > E$ N a E 3 m o y m n m" Z\ o TEST RESULTS Plastic Limit H Liquid Limit Moisture Content - o N-Value- 10 20 30 40 50 60 70 0 3 5 6 7 4 6 4 4. 2 inches of Topsoil 1 20 SS 1 2 2 ` R . } n I } 1. : 1 . : .1 Brown, moist, Silly fine to medium SAND (SM), Very Loose Brown and tan, moist, Silty fine to medium SAND (SM) with trace Clay, Loose Estimated SHWT @ 6-feet below site grade 2 19 SS 2 3 3 z 5 i 3 20 SS 2 3 3 Light gray and orangish brown, moist, Silty fine to medium SAND (SM), Loose 6 Orangish brown, moist, Poorly Graded fine to medium SAND (SP- SM), Very Loose to Loose - 1?f f f ,� ti: ii. :qi r 'ti 1:L1: n.Li x t I i 1tt1: 4 5 22 24 SS SS 3 a z 2 2 20 0 4 6 24 SS 3 3 3 7 24 SS 2 2 1 Boring terminated at 15 ft. 10 z0 5 2 0 30 3 NOtes: SS = Split Spoon Sample ST = Shelby Tube Sample - — ------------ — --- HA'= Hand Auger Sample— BS = Bulk Sample PAGE 1 Of l Standard Penetration Tests were performed in the field in general accordance with ASTM D 1566. GET ® BORING LOG BMP-4 PROJECT: P-1310 Pre -Trial Detainee Facility CLIENT: M.B. Kahn Construction Co., Inc. PROJECT LOCATION: Camp Leleune, North Carolina PROJECT NO.: JX10-113G BORING LOCATION: See Attached Boring Location Plan SURFACE ELEVATION: 30 MSL DRILLER: GET Solutions, Inc. LOGGED BY: own DRILLING METHOD: Rotaey Wash Mud Drilling DATE: 10-29-10 DEPTH TO WATER -INITIAL': S 13.5 AFTER 24 HOURS: 3 9.92 CAVING> L c g m w� n m o E n m o Description o, O m E o m z m m a o w w E °' w m n" w z oo e TEST RESULTS Plastic Limit H Liquid Limit Moisture Content -• N-Value - 10 20 30 40 50 60 70 W 0 0 4 5 8 11 7 7 7 17. 2 inches of Topsoil 1 23 SS 2 2 _ q j }. I } % : 1 : 3 . .1 Brown, moist, Silty fine to medium SAND (SM), Very Loose Brown and tan, moist, Silty fine to medium SAND (SM) with trace Clay, Loose Tan, moist, Silly fine to medium SAND (SM), Loose Estimated SHWT @ 6-feet below site grade 2 3 21 19 SS SS 2 3 23 3 a� 2 5 25 4 20 SS 4; s 5 Light gray and orangish brown, moist, Silty fine to medium SAND (SM) with trace Clay, Loose to Medium Dense 10 Light gray and orangish brown, moist to wet, Poorly Graded fine to medium SAND (SP-SM) with trace Silt, Loose f 't ryjii- Ja[f 5 21 SS a 3 2 i 20 is a 7 24 SS 4 5 15 15 Boring terminated at 15 ft. 10 20 e 5 25 30 10 a Sample ST = Shele Sample Notes: SS = SplitLAuger ' '- ---------'—'--'—HA='HanSample BS = Bulk e PAGE 1 of l Standard Penetration Tests were performed in the field in general accordance with ASTM D 1586. 1 m, --- - -- -- - - -- -- -i t =- - - :- - _ ....... - - ME ELEVATION{NFE£!' Z w W o Z w J_ = LL o cd U U J o O Q> ¢ N Q a C)¢ O 6 o W> N m >G W o Z U W U a tVn N vu v.v nv - N N S Zz 2 Z 2 E 2 5 UJ N U L N � U � `m y in v a u a - N U ttn U or '- « n O 127d N{NOLLYA:!/! APPENDIX IV ADDENDUM NO. 1 TO THE ORIGINAL FEASIBILITY STUDY REPORTED ON THE DATE OF FEBRUARY 19, 2010 (GET Project No. EC09-106G) S,yolutto`ris�'Inc. t' February 19, 2010 TO: JMT, Inc. 272 Bendix Road Suite 260 Virginia Beach, VA 23452 Attn: Mr. Timothy Gaffney, P.E. RE: Report of Subsurface Investigation and Geotechnical Engineering P-1310 Pre -Trial Detainee Facility MCB, Camp Lejeune, North Carolina GET Project No: EC09-106G Addendum No.1 Dear Mr. Gaffney: Pursuant to your request, G E T Solutions, Inc. has completed our supplemental subsurface investigation and Geotechnical Engineering analysis for above noted project. The purpose of our supplemental subsurface investigation was to further delineate the presence of subsurface voids encountered during our original Standard Penetration Test (SPT) boring program and noted in our "Report of Subsurface Investigation and Geotechnical Engineering" issued on the date of April 17, 2009. Additionally, our supplemental services included a seismic site classification analysis. This report is provided to serve as a summation of our supplemental field exploration services as well as the results of our Geotechnical Engineering analysis. The supplemental subsurface investigation and geotechnical engineering services for this project in accordance with G E T Solutions, Inc. Proposal No. PEC09-179G, dated May 19, 2009 and subsequently revised on the date of May 29, 2009. Authorization to proceed with the services was provided in the form of subcontract agreement (contract N40085-08- D-1412, TO #1) authorized by Mr. Timothy Gaffney, P.E. with JMT, Inc. on January 12, 2010. Proiect and Site Discussion As indicated in our above referenced report, subsurface voids were encountered at the location of our previously completed SPT borings designated as B-7 and B-8. These borings were performed at the locations established by JMT, Inc. and were generally positioned slightly west of the west building wall line. Additionally, the results of the remaining previously completed borings performed within the vicinity of the original building limits (designated as B-5 and B-6 which were performed east of the east wall line) did not indicate the presence of subsurface voids. Subsequently, it was our understanding that the building location was shifted slightly to the east in an effort to locate the building outside the limits of the encountered subsurface voids. 504 East Elizabeth Street • Elizabeth City, NC 27909 • Phone: (252)335-9765 • Fax: (252)335-9766 -- — info@getsolutionsinc:oom—-------- Report of Subsurface Investigation and Laboratory Analysis P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: EC09-106G Addendum No.1 Field Exploration 2/19/10 , In order to explore the presence of potential subsurface voids along the western portion of the newly established building limits, a total of three (3) 30-foot deep Cone Penetrometer Test (CPT) soundings (designated as CPT-2 through CPT-4) were performed at the locations designated by representatives of NAVFAC. Additionally, in order to perform a seismic site evaluation, one (1) 36-foot deep CPT sounding (designated as CPT-1) was performed within the approximate center of the newly established building limits. This CPT sounding was limited to a depth of 36 feet below existing grades as penetration refusal was encountered at the termination depth. Shear wave velocity testing was performed at the location of CPT-1 from the existing surface grade elevations to the termination depth of 36 feet. The results of the CPT soundings are provided on the attached CPT Sounding and/or Shear Wave Velocity sheets. The CPT sounding locations were established by representatives of NAVFAC and subsequently identified in the field by G E T Solutions Inc. personnel with the use of a Global Positions System unit based on the coordinates and dimensions indicated on the project site plan provided by The Spectra Group. More specific information regarding boring locations and depths is provided in the following table (Table I — Sounding Schedule). Table I — Sounding Schedule Boring Boring Depth Boring Location 1+1 Number (feet) CPT-1 36 Approximate Center Building CPT-2 30 Approximate Southwest Building Corner CPT-3 30 West Wing; Approximate Center of West Wall CPT-4 30 Northwest Wing; Approximate Northwest Corner Note (1): The boring locations noted above are considered to be approximate and are referenced from the newly established building limits. Subsurface Conditions Based on the results of CPT soundings (CPT-1 through CPT-4) performed to depths ranging from 30 to 36 feet, subsurface voids were not encountered at the newly explored locations. Accordingly, the subsurface improvements, as indicated in Section 4.7 of our "Report of Subsurface Investigation and Geotechnical Engineering" (dated April 17, 2009; GET Project No. EC09-106G), do not appear to be warranted at this time. Solutionsjnc.,. , I I Report of Subsurface Investigation and Laboratory Analysis 2/19/10 P-1310 Pre -Trial Detainee Facility MCB, Camp LeJeune, North Carolina GET Project No: EC09-106G Addendum No.1 Furthermore, the CPT soundings indicated that the subsurface soils at the recently tested locations are generally consistent with those encountered during our SPT exploration procedures. Accordingly, it is our professional opinion that the remaining recommendations, excluding the subsurface grouting improvements, presented in our above referenced report remain valid. Additional subsurface exploration and Geotechnical Engineering services, as indicated in Section 5.3 of our "Report of Subsurface Investigation and Geotechnical Engineering' (dated April 17, 2009; GET Project No. EC09-106G), are recommended to be completed once the Design/Build team has been selected in order to substantiate the recommendations presented herein and/or in our previously referenced report. Seismic Design Recommendations: The results of our field exploration indicate that the average shear wave velocity recorded in the upper 36 feet (refusal depth) was about 1,330 ft/sec. As such, the project site is within a site class 'C' in accordance with Table 1613.5.5 of the 2006 International Building ' Code. The comprehensive results of the CPT soundings are provided on the attached CPT Sounding and/or Shear Wave Velocity sheets. We trust that the information contained herein meets your immediate need, and we would ask that you call this office with any questions that you may have. Respectfully Submitted, G E T Solutions, Inc. r i LCsi.AJ, Gerald W. Stalls Jr., P.E..�o.tH CARpZ�•,,,�� Senior Project Engineer �..•oFESS/O� :y9 NC Reg. # 034336 SEAL q� 034336 .ENGINE`.. . �'•�� W. Sia��.�`� ,n.umD•• Camille A. Kattan, P.E. ;; �N.\ CARO"'o, SSiO.% ; SEAL r 014103 Principal Engineer NC Reg. # 14103 Attachments: CPT Sounding and Shear Wave Velocity test sheets (CPT-1) CPT Sounding test sheets (CPT-2 through CPT-4) ' Copies: (3) Client -- ----- - ----- - GET I F 1 CAROLINA DRILLING ' Bridger Drilling Enterprises Inc. dba Carolina Drilling 114 Chimney Lane Wilmington, INC 28409 ' 910.799.0493 w 910.799.5945 f 910.512.4600 m carolinadrillina@email.com ' CPT Analysis Results All information obtained utilizing Geoprobe® 6625 CPT, GeoTech Cones, ' and CPT Pro by Geosoft. Data interpretation to be exclusively determined by the client's engineering staff. ' r Classification by ' Robertson 1990 — Clean sands to silty sands (6) Silty santl to sandy silt (5) — 6 Clean sands to silty sands (6) C t Clayey sill to silty clay(4) Clean sands to silty sands (6) Silty sand to sandy silt (5) ' -Clean sands to silly sands (6) Silty sand to sandy silt (5) _ Clean sands to silly santls (6) Silly sand to sandy silt (5) Silty send to sandy silt (5) sands to silty sands (6) Silly sand to sandy silt (5) Clayey sill to silty clay(4) Silty sand to sandy silt (5) Clayey silt to silty, clay(4) Clays: clay to silty clay (3) Organic soilsyeats (2) Clayey sill to silty day (4) to silty sands (6) OWN wft CAROLINA GRILLING vz Cone No 4227 Tip.re.IrJn21'. 10 9leelre area Icm2I'. 150 LIlU U Li LI11J U LI LI1U L1 Gt XiOib ,II 111111 II I IIII IIII IIII II '11 1 n1llnnnTnnrlTn nr 1ILILIIUULIlUUL111111ULI1111JL III IIII11111111111111 lr4 rnnnrrtnnrmlTn nnrn nr u Ulu U UULU UL IJ 111111111y11111................ u ulu1JU11JUU...I. 11111111111111111 1 .... 1 Ri'n n r1 TIT Il n nTlr n n rlTll ll r .11 11 L IJIJ H 111 J w w LI 11J II 11I H II1I111I I1 II II III III i17.7--i i 1ir1T1r1r11r1.11.1- r(111 I11 1.4 `I IIIIIIIIiIH a 11t-1111 rI rIr ll rl rl TlT 11 r1 rIlI �II 11111HH1HwwH1HN I-L-HNC 111.................. it II��III1111111111111IIIII1111111 hI+JY H H fli lY H ..... H ....... H. ILT II I I¢Il1l1l .lI.L.._.._....I.IL.._.._....i.l.._.._..11`1y'^„nY'"I_ "TIT IIIIIIII I11111111111111 nrl+n "U n rl+ "U nn rn nr LL11iyaJ ULI l UULLL UULll I lUUL I 1 11111111111111111111111111111 r¢.+Tnnrrtnnn1JUUL1Tnr IL IUUULUUUUILLUUU1u UL n "tU ............. 111n (IIIII ry T T n n rlTTl n n rlTnnnTn nr kL. lI J U U 1111J U U LI.I U ULIlU U L 111111n nr: 1111111111n nr: TITn �nrlTnnrrtnnnrrtn nnrnnr I yL'ILUUULU IJ VLI LIIV VLlill LJl IIf?II nrIT1T1T nil TlTn nr?lint I L iJu uLuu u. II IIInIIlil lilull111111 nnu111 Tlnlnn Trtn nnrnn nnrnnr HaIJw FILHw w 1 111111111111111111 ~ iii 111111 ~I IF ___ 111 r1 TIT 1111 r1T11 i1i hlYNww1HH HH41aN HH1HN� 111111/1 �111_____................ ________ Irk Ihlllllilil~111111~III IY 1r�-Iiinili1r1111 i1i1i1iili liiHi "Y HFl fIYnTH fITnTIT1YH'MI 1 n1lJ 1J LI LIL IJ LI LI LIL IJ LI LIL IJ IJt - Iilllnnlnn111 Will 1 Tlr li l'11'1 flT n n n in n n rlrn nr 1ULUU ULILIJ LI LILLIJ LI LILViJL INI :1: 1111I111111 I II111 ULILI'll, ILI UULIL Il U... I I I I TI1 n n rITIT n IITIT n n rIrIT nr I LILUULI1111 I ULI LIlU ULIlUU1 1111111111111111111111n nr,111111 1 r1 r1 I n nI n n n rim n n Aril nr I LIlUU LI LIlU ULI LIlU ULILUUL I1':1 nil ilTn nil T ITn n rrt 11 1 LLLLuu uluu uu Ij UULJIJ I IIIII i rrtnnln rrt nrn rrni n nnrn nr u u LU IJ UL u 1I1I111,1 _______71IrITIrlIrlTim - 111H hI h HH N hH IYN1 _ IIII_II I_ _I_II 111 1111 T 11111 ~ _ 1_II IJIII 11111111 IIILIJ n hl III, rl III n n rlrn nr LI LIJU111 i111Jll L11111J UL111J IJt IIIII I1111 I1 rlTn rlr !LILY IJ VLLLIJ L1 L111UJUULV Vt I II111111 'n' Tn n r1T4 n n II I n rl T IT ! ILUUU ULIU ULIIUu ULLLIJuI 111�11Ill: 1111111111 IIIIIII I1111 1 rl TIT n n -ITll n n 111 n n LIIII nr 1 LI11 J U U LI l U U U 11J U UULU UI 1111111111111 (nrn nn rrr lnnnrin n nnrnnr JLJIJ�l IJ U LILIl uu LIlU LI 1111111111111111111111111111111111 1 Winn nrrrll n nrlTn nrlrnnr I LILIJ U U 1111J V II... u .11.1J UI 59 5 6 7 8 9 10 J_1_L i i r - - I'T-r T'r I-'-T-r I 1 l- T-rl-r-rl-r -I-I -L I 1_I I )J - T-r I-r-- T—r -'-'-r �i-TYI-T'I-I-r-I' T-f 1 ri r--i-r 1-4-1 1 I 1i I I_I _I_ 1_L __ I I I I I I Y I I y-r-YY-r Y I _1_l I_ J_ L J_ 1_L I 1 1-r-I--1-r-T-r _ 1_ LJ_ L_I_ J_ LJ_ 1_L I I I I I __1_LJ_L _I_J_I I_I_L I I I I I- T-rl-r -rI I-1-T-r I-T-I I- r--l'r-I-T-r 1 1 J 1 1 1 1 1 --r-r l-r-r l-r-I-T—r JI I I 111 I I I II -1 _I 1 --rY-r-r+- r -r+-r J_J_L J_1_L I Tl r-I-+ I_1_LJ_LJ_L I_1_L -,T rl-r _1_LJ_ L_I_ J_ L J_ 1_L I I l'T rl'r-rl-r �I-T-r -T -rl-r-l'1-1-1-1 _J__I_ _ I _I_J -L -I L1_L I I I I I - -T-rl -r -i T- r -I-TT T_r �I_1T_______7 _r -L-I-J -I-l- I I _I -_II_____ I I I I _1_I_ J_1 J_J_L J_ LJ_ J_ LJ_ 1_L I I I I I-T T-r J_1 _L J_L_I_J_LJ_I _L J-T-rl-r-rl-r-rI-L I I_I J_L_I_J_ -1-11-r ri r 1-1-r J_I _L J_L_I_J_L _1_I_L PosiUon: Client: J J L_1_J__I_-L -i-I--'r-T_I--r"r J_ 1__L_L_J__I__L -['-1--1--rr-I- --- -r T I__1__r _1 _�I __r_r T_I--1--r-T_I--1--r -`d----r-T-T--i-'1r _I4_ ____1_i_i__i_ _I _r J, -L I _1_ J_J__ L_ 1_ J__I__L 1 _T (l_ -1__r._T_ I__i__r _J__I__L tr 1 T\\-I---r-T-I--I -r r�J I _ L i i _I L -T;I JI -T-IT-1--r-T-l--i -r __ _I__ l I I "-I--L- 1-J--I--L _1_J _I _L_1_J _L l -I- - T l -I J__I__L _1_J_ I__L - T-T -I ----—- r L - T-I- .--r- T -I-T-r L - r-T-l -r _____________I_____ I_ _I Ir J _1_ J_ J__ L_ 1_J__I__L J _I__L_I _J _I__L T - l -I 1_ J__I__ L_ 1_ J__I_-L - T-l -I - r -T'-l -I _ J__I__ L_ L_ J__I__L - I-I--I--r-I-I - -I- - r _1_J _I L 1 J _I _L trail detainee site Classification 0 0,9578544 1.9157088 2.8735632 3,8314176 4.7892720 5.7471264 6.7049808 Robertson 1990 1 � I I I I I I I I I Clean sands to silty sands (6) 1 _ L - � c 1 - 1 - J - J - J - J !_ _ _ _ _ -I_ OaU\Lf$ Silty sand to sandy silt (5) : _____r____r_____r_____7_____n__________-_____--- ____--- _____ p _L ! _L _1 _1 _J _J _J _! _I _ Clean sands to ally sends 6 C �- I I Clayey silt to silly clay(4) i'---___.L__ r_ Clean sands to silty sands (6) 7; _____ L_ ____ y Silty sand to sandy sill (5) _ _____4_�___.�=r='____a_____ a_____a_____�__________________ Clean sands to silty sands (fi) 1 - r - - - - ---'-�" ' ' ' -`— Silty send to standWilt (5) y Clean santls to silty sands (6) 11 ' ` r - Silty sandtosandvsilt (5) 1 _ _ .. _________________ I I Clean sands to silty sands (6) 1 _ _____ _____ _____ _____4--__-'___________ ______I______I______ - - gilty santl to santltl silt ((5 GleansandstosiliysaQ' (6) 14 I C'= ___________ --- ___ - -�'--'---- ______J_____ 1 _____L_____!_____!-I-----� !___ I ______ _____________________ Silty sand to sandy silt (5) I �_1_I I 1 . _____r____=__-�_____-_____y_____ 1______I_-----I______ Clean sends to siltysands (6) 21= _____r_____r_____T_____T�__`r_____r_____ 1______I____________ __ Silty sand to sandy sill (5) p _____i _____LJ_____J_____!______I______ 2 ______ _____r_____r_ _ r_____T_____T_____n_____�_-__________ I I Clae sill to sil clay4 2 I -----1�=�-----I- - - - -- -Silty _ sand to sandy sandy sill (5) I Clayey sill to silly clay (4) 27 2 _____"- ___ I_____ I ------ I ------ ______ 2 Clays. clay to silly day (3) _.__•____._____-_____ _____ __________________ 31 ___- Organic soils -pears (2) 3 ---- _ -; I Clayey sill to silty Clay (4) 34' - - -- i_-----------a--_-_- sends to silty sands (fi) L__ I __ I _____r_____I_____I_____-_____ y_____ y_____ y-_._=.,-- _Clean _ _ ______ J______I____________ 3 _____ L_____ L_____1I !_____ J_____ J_____ J______ I______ I I I I Q _____L_____r_____r_____T_____r_____-___ — -______I______I_ _____ 41 _L _L _1 _1 _J _J _J _!______I______ 42. _ I_____ _ _r _r _r _I _ __ Q _L __J _J J 45- I -f -T -i -1 -1 -1 -1 -I -1 4 _ _L _L i i _J i _J _I I f -T -T -1 -1 -1 -I -I -I 474 _L _L L _J _J _J _J _I _I _f _r _T _1 _l _l _I -I _i 4 __ - L _L _� _� _� _� I _I 5 _ -r __I ___I __ _ -1 y512 _____-_________________a=____ a_____ I_-__________ 5 -. -« -a -. -y -. -I -I -I ____ I_ _ _ _ __________--- ___ _____L_____ L_____L_____!_____J_____J_____ !__ __ _ !_____ ___ __-_ I 6 :_ _L _L _1 _1 _J _J _J _J _I______ 6 I I f T T -T -1 -'I l 64_ L _L _L _J _J _J _J _J _ ___ __ I I I I I I _____i-_____L_____L_____J_____J_____J_____J__________________ 67: I I I I I I I I ______L_____L_____L_____J_____J_____J_____J_____!______I______ 0 10 20 30 40 50 60 70 80 90 11 qc IT/fl^21 Location: Position: Groundlevel: Test m 'n X: 0.00 itV: 0.00 ft 0.00 001 Project ID: Client Date: Scale: 1: 100 C DRILLING2/18/2010 Cone ProlecL Page: Fig: 1 /1 rip areaa [cm2l cm2tl In Sleeve ane lcm2l Ica File: pre trail detainee site 2.CPT uXi y a n a o a a N n N v 0 X> N `m d v X> N In VI 41 V1 N N N Ul N 4 0. d HHHIIIHHHIII LLLLLLLLLLLL I I I I I I I I I I I I I 1 1 � I I I I 11 I I I I I I LI ! I 1 I I i I I I I I I ' I I 1 i I ' i I I I I I I I I I I I I I I M I I I I I I I I I I I I I I i 1 I 1 1 I I I I I I I i I I I I I I I i I I I I I I I i I U n I I I; I 11 I I I I I I I I I i � 0 I I I I I I O I I I I I ! I I I I 11 I I I I I I I I I I I I l 1 I I 1 I I I I i I I O N I I I I I I I i I II I I I I I I II ! I I I I ! 1 I I I 1 1 I I I O 1 I 1 I I I I I I I I I I I I I I I I I I I I I! I IA ry M N Q N N t0 m N O (w) glde(l I 1 o� ry m n r rc r n r m r r M n n ry ry m m m m m r rn M r M m �rl, m w m ro m m- rw m m � -- � � � � a- �- — LLLLLLLLLL?LLLLLLLLLLLLLLLLLLI N N V1 M UJ ? U1 N Y1 W N n w W UI m N O N N �-..—�—�—� (w)Ul�aa I I I 11 t I Classification by Robertson 1986 Silty sand to sandy sill (7) Sandy silt to clayey sill (6) Silty send to sandy sill (7) -Sandy silt to dayey silt (6) Clay (3) Silty day to day (4) Clay (3) Silty sand to sandy sill (7) Sand to silty sand (8) Silly sand to sandy sill (7) Sand to silty send (8) Silty sand to sandy silt (7) Sand to silty sand (8) Clayey silt to silty clay(5) Sandy silt to clayey sill (6) Sand to silty sand (8) Silty sand to sandy silt (7) Clayey silt to silty clay(5) CAROLINA DRILLING awr qc IMPar fs IT/fl^21 u21TIV21 So(gt.WL) IMP-1 0 1 2 3-1 0 1 2 3 4 5 6 7 00.13333R4U.r.13®71118391 � I111 II111 1 L 1 �I1r111llllll I � 11u1 1 I QIII u n IIII I I _-__1_____I____ __7-r-rl-r-1-- 1 - - - - - IInnnIn n n n II II IInI mm�nIIIIII II IIInIIII 1 1 1 I I I I i I 1 u 1111IIlI In II1 n I1 �1 1 1 1 1 i ' 1 II rinnrnlm nrtnnn --r----r--- --�-r 1 r i I ljln lnlullnilllnnin InyInIIuII1InI nIIlIlIlIlnn111n11 1 I 1---- I I I I I I 111 4- Jrin 1-1-r- ------I1 ------ -- ............ 1 r 1 1 1 II ....................... I n rinnlrlmnnlinn ----r ----1---- J -1 1-r-I-- -r- 1 -----r-----1-- - 137 IIIn1111111111111Illlln III II II II IIIIIII II I I II II n / I l 1 I I I I I I I 1 1 I rinililrrtIII linIII nn 1 1 1 IlailulnilllnIIIIII 1 1 \I 1 1 1 1 7. I u11111nnnI111nnu11 r I r 1 I 1 J______ _____ I I _____________ IfiF71 nIf11111111111n1I 1I11n IIIIn1111n111111111I1111 '__-- IIII I 1 1nln IIIllnllllnnlnn III11r 1 I1111111111 IIII __�--'_--- 4 1 1 I I I I I I I I r 1 IIIIII. III , 1 IILI!If_I Ier1111Ir1111ItI 1r11 r1I 111 n.H1111n1111InI1I1 l (__I Irl=1-1 1 1 I 1 1 y`1JL11LLIJI U JU UU ___J_ ___ `— J_1_L J_1 _I_!__ _ _ ___ I JI . Illljllllllllllll111IIIIII I I I I I I I I 11 ULLL111111J 1111IJlJU -----J---- 1_IL I_1_L J-- ----------JI 11111II1111111111......... f I r I . Intl sU1111111111 I, I. 111 l( 1 1 r 1 1 1 1 1 1 1 L1 Ll Ln.ILIlI11JIJ ll tl ll Ll I IIIIIfIIIIIIIIII IIIIIIIII IIIIIIIII IIIIIIII1111111111 > I I I I I I I I I I 1 uuL YILI1111JIJuu uu IIIII 1111111111111111111 r _r_1 _1 / I I _1_1_L I_J_L I ( I I I I I _1 _J II111 `IIIIII III III111111 I 1 1 1 1 I 1 III IIIIIIIII,III I'J u u Y - � -I - _ _ _ J_ _ _ _ I- , I I I I I I I 1 II11`�` IIIIII111JHHI 111u _� F I _I �11 .III FI R111111,111111111111 1111111J 111n111n 11H i I I I 1 I I 1 1 1 1 I 1 1 1 I IIIIYN�II F i y II I 11111111111111 IIII IIIIIII II1111111 \ I I 1 I I I I I I 17 1H H lflflr HH H H H H 1 -1 -1 T - . -1- ♦ -1 -1 ~ " 1111111ill llll11111111IIII `- � I I I I I I I I I I I 1 .IIIIIII IIIIIIIIIf II11111111111- - H YISIfnHlyHnn HH IIII IIII IIIII II II I - 1 -1 l� I I � T-r-1-f-r-1 II I I I I I I 1 -1 -y I I II IIIIA I1111111111111111 1 I I 1 _ nnflnTl TlT llnnnnrl z I -1 -I�I-r-I-T -I I " 11114111111111111111111111 IIIIII IIIIII11111111111111 / I I I I I I I I I I I 2 _ 111\I111111111111111111111 I/ C I 11 -I -� I 217 1In�hnInnn7n nnnnn _________I____ l_r _1_r_r n__ __________ II n1n. 111u111 I1 I 1 I 1 1 1 1 1 11 2 'nnElnnrrrnlnnnnln _l _r________ 1 1 1 1 1 _ T_r_I_T_r _I__ _____i_____r__ Will 11nn11111111nn1 1 1 1 1 1 1 1 1 1 n I III 1i IIIII n1I 11 1 1 1 1 1 1 1 1 1 1 2 nnA^nrrtrtrtnnn n n __ _r----1---- -1 1-r-rl-r-1-- -----11-----n-- In 2 -j ---1---- ---r----1-' -IIIIII .lirinrlr.rrrnnnnnn n11111111111u1n 1I1 1 rr-l-rrl— 2. r 1111111innl lnln''i 11 �- __i ____�____ i_7�1 1 1 1 1 _i__�__ 1 _____________ I rl rl rlilrlTl III ilr rind LIInluulllnu111u1111 1_r I IL{1lun ulr11u1nn1n1 I 1 1 1 Y 1 1 1 1 1 1 1 f 1 1 2 ---- --- nfr,IIIIIHIIIIII11111111 1 1 1 1 1 1 27 1I1i111i IIII l it 111 I II III I II ! 1 1 - I In 111111111111111111111 I114�1111111111111111111111 I I_ 2 8-I -i ll II II I I IIIIII I 2 - I111in LIL 11lLJIJ LLIL' __I____!____ '_!_L!_'_!!__ ____________ ....LI II IIIIIIIII11111111111I d1ut-L'11111I1111111 ULTY+LLYlL11J 1 1 1 1 I I I I I I I 1I 1 1 1 1 1 1 1 1 1 30 U L 1!JULI LI n1 u1111ull nllln1111 ____1____!____ !_\1 _!J_1_L!__ 1 __ 1nn1uu1111I 11n111u11 1 r 1 1 1 31- ULI LI LI LI l III UUUU I II11111111111111111111111 _1 _J J_1 _L J_1 _LJ _I_____J - 32 IIIIIIIIIIIIIIIIIIIIIIIIII u u L1u11Luuuu uuu 111I1111111111 n1I11111111 ____1____J__ I 1 J_1_LJ_J_LJ__ 1 1 I 1 1 I I _____1_____J__ 1 I 1n1111I111111 n11I 11u111 1 1 1 1 1 1 1 1 1 1 1 '� uuulluuJuuuuuu ____1_____1____ J_1_L_1_1 _LJ__ _____1_____J__ 111unn1111nun111n1I nllnllnlnll Willi 1 1 1 I 1 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 1 36 ul 11 uuuuLuuuuuuuu ____1_____I____ J_1_L_I_J_L_I__ _____1_____J_ uz t Cone No 4227 Tip area Icm1) 10 Sleare area 111 150 in level: Classification by Robertson 1986 Sensitive fine grained (1) Sandy silt to clayey sill (6) Silly sand to sandy silt (7) Silty clay to clay(4) Silty sand to sandy silt (7) Clay (3) Silty no to sandy silt (7) Sand to silty sand (8) Silty sand to sandy silt (7) Sand to silty sand (8) Silty sand to sandy silt (7) Sand to silty sand (8) Sandy silt to clayey silt (6) Sand to silty sand (8) Silty sand to sandy silt (7) Sandy silt to clayey silt (6) Silty sale to sandy silt (7) Sand to silly sand (8) Sandy silt to clayey silt (6) Clay (3) Silty sand to sandy silt (7) Sandy silt to clayey silt (6) CM. MM Dfll_ LUNG yin llnunnlu lralw4c 11 lulu ill ill Prl y . . l a lllllllulnnnn 11{I{I {I T:T lT rl rl ll rl rl rl TI TI TIT IT IT Il fl fl n - 1y 11 lu llllll ill T TT TT TT Tlnl I'r1 a u11 'n 4 n n rinrrtlnlnnrnn III r l l ................... 1111111111111.. il T. C IJpir1r111Trrn1111n❑❑ _ ,Il111llllllln IIIIIIIII 0 Till liliili it itT,-, T. T TIn TT TTT T TTTT II TT 7 I' u7,nn711, 111111i1ir:rl 17n 11n 111n n1111111n1 t11 _n I II UI nTIIII uTn TTTTTTTTT 1 C>'l lll111111111111111111 UUULIl000L1 III IIIL�/111I......II IIII11111 I III2111111111IUI I V II V IIUI nIp ........... ulllllu u uu 1 L1 L111 L11111111LL LI LI LI LJ I III I'111111111111111111111 I II I11111111111111u u u 4 I11 11�11111111�11111111 I lllrllll11111111+11111111 FLr1'14141111HIi HHHH y II I1111111111111111 Il l+ill III II II III IIII , INN 11 T11u 111 a 11 uynrrH I II 11 11 IIIIIIIIn 111111111 Tu%I 'Ill 'Ill ul'Ill I'll I'll it I", I", 11 1 u.1 u11111111n 111111111 1 nnslnmm�nnnnn 1 n 51111111111u 11 n11111 I I 111111111 1111n I I nirsl lln nnlu In ulTlT Of I I Cone No: 4227 nv area Icre21to slesre area Icn21150 ^llllll1 1111111 rynnil ...................11ll IIII III 1 T1 gr1r17IT17 ITIT rl n!1 n 1 ; rI 7Ir: TITI:T 111111 Il n n NJI ITII TI III TLIT TT T T T Tn 1rL'r1 T.............. n n n ul 111 lirT - TT T T_--- rinrrlTl-l-llnrlrl 1 IIIIIII III IIIIIII II 1 µ 111111I11111111IIII 11111 I I(IIIIIIIIIII II IIIIIIIII I Ivry LI LI IIII_ I_ I_ I_ I_ LI LI - �nnlin n111111111ru pp nlnn1n 11111 n1n1 !yL1 LILLLIL1111U1J IJ UIU IAlllllllllllll ll lllllllll !I LI LLLLLLLIlUUUL UL nlll uln 11 1111 11 IU U UL111111111111 U U U 11111111111111111111111111 l l ll lll1111111111 u u u 1 IJ LI LI L1111111111 LI LI LI LI l l l l 1l LllllllU l l u u U U I IIII II IIIIIIIII I 1 1 I 1 l I I I I I --___--- ___ �I I I 1 I 1 T I I I I I 1 I I \ I I I I _I I I 1 I I I I I I I -1 I 1 I I / 1 I I I I 1 _ 1 _ I I I I I I I I I I I _I _I 4 5 6 7 11 1 1 1 1 T_r_I__ 1 I 1 1 I I I I I i I i 1 I I -' 1 I I I i I 1 I i 1 I_ 1 1_ L J_1_L 1 1 1 1 1 1_L!_LL!__ i l l I I I 1_1_L__1_L J__ 1 I I I I 1 I I 11 I 1 I I I I I I-~ I I I 1 I I I I 1 1 i I I I I I I I I I I _I[T I 1 I Ir I T-r -1-rr 1 1 1 1 T1 T I 1 I T_r _I_T___I__ i_T__ III 1 T1 1_T _I -I'-___ -1 h i l l _1_L 1_1 I L .1 _L 11 1 I I L. 1 I 1 I I I I 1 I J__ T T I I 1 I 1 I I I 1 I I I I I _I J I I I y 1 I 1 I I I 1 I I I I -I I I -I- -1 I I T1 _____I ___-_I__ __ _ I I I I I I I I I I I no J qc IMPal fs IT/fl^21 u21T/0^2I Su(g6WL) IMPa1 Classification by _n 3gi`g7':.•,{' it 1 2IiIrII�lI'IIIIIIIrII1IIIIIII 5 7 R110 00.1A9_____I3IIJ__-_IIIIIIIIIIII1I4IrrII�III�IIII Elk ®____-_-__ TW-_JJJ_��nIIIIII'8III 3-1 0IIIII'I!°1'iiiIiIiilII 9- 3,rIIIIIIIIIIIIIIIIIIIIIIrI 6IIIIIIIIIIIIIIIIsIII 2IIIILIIIIILIirIrIrl1IIr_I1II_ I IIl1I1IIIlIIlllI1llIl .',IIrIl11IIIl1InnI1II IIJIIIlIIII1IIIIr11IIII �,I��j rt1lI1lIl1lIllInlII11II1Il nnLiLInl1IIIlnu1lllInI1IIIII I1U1111Il11IfI111IlI1lJIll111111Il1l1IlllI111Il1l _�=-_.-� TllIIll11I1ll1IulI11lIllInlIll111I1ll1IAlI11lUIl4lllrinl1lllInIlI11In1II1In . �1nIlLIInI1IIIn1IIIIIII1I ' lllIlllflI11lIllII111II r_1J4Tr11IIIIIIIIIIIlIIIII lrin1rlrIlIl11Il1II1IHlInnnIll11Illn1IlI11lInll /___-)=1J 1TLIlI1lIIIlnInnI11lIllIrtll1l1IIIlIlI11lIuLllTI1l1IIlnnlI11lIllllI1I 1iL1lnM1llInl1I1lu1nlI1Ill __-J-__ fI1�f ___-___ lr1rl,IIl1l1IIITII1III IIIllII __- TrLIlllI1l1IIIlIIllI11lIIllIrtlnu1l1IIIlIIlllI11lInIll 1IlIIlI11IIIiI1lIIII 11llnnIl11I1l1IlI1InIl 1Trrr__J1 . 1;I1lInnnln1IIIIl11G1/4,IIII C\L JluIun1I11111Ilu1InI111Il1l ' YLi,nnIiIIlnu1I1IIIlII1ll f____--) I I I I I I I APPENDIX V ' HYDRAULIC CONDUCTIVITY WORKSHEETS I 1 0 0 0 0 0 0 0 O o 'RO O j � J O o O M O 0 0 0 0 y a Z N u i L 0 0 0 0 0 0 0 O O C O L N y C L Z" 0 L � In 0 (n > �i 0y i O) r N W Cl! In N d a c o + > oY g 3 3 a .� O U O O U + W _ LLJ E aL c N O O O 90 0 0 O _ '6 fRll 0 w w w w w w W w 0 L U M N O Y H D C E .M- (O N p r �n Q Q c+i r Z a R y= .j -M R C p N U O O O O O O O O O } 1- 11 j E o 0 0 0 0 0 0 0 Z Z N N N ~ O Q l O O0i 0' Zd q N N Q Oi I-� [D co O Y R J ❑ f w a m U U o LL E 7 ai u u u w E m Q 7 O N N N U E OJ r O N of IN _ __ N lfJ ui 0 M Q r m O M Q Q a O d Q N M 0 0 0 6 G_ D } a N 0 n C7 w C_ O « U W N ~ U o E m m L (n = y N N Q l0 O W N Q S= 2 R y O 0 O 0 O 0 O 0 0 0 0 (n W y o 0 0 0 0 0 0 m 'S E O m In Z L u0i .d. o U C J❑ LL U M J Z � a a a a a a a a o R LLJ LL y In to N 6 r uD m N E « R n utEi 'C e U w Q C N O N n Z O 17 Q O 1P ++ a b m R m E o _m E d m v W « w An y A Ap 00 y A m O y LL z z m❑ p m E C O N M C C C In� .o a O In > E O In O m O m R z N D in O] m M O m� (fl iD M M N In C A L O 'O O1 O 10 i _T __ m r __ m (D m __ O w r Q Q (D O r r N r O (D O O) O O O m r Z i t Q 6 0 6 6 6 6 6 LO •3 O L N �' II U) Z, M r 0 0 0 r M Q (n N (n 'j 30 d d= U a U C O C M co O (O N m r r (D O (D 1� C6 E Y F o `—' `o o u� M M Q Q Q Q Q Q Q Q Q Q Q d N W E L N m o 0 0 o g o 0 0 0 0 0 0 0 = a '- `- Y d d w W w w w w W w W W W W w in U) 0 U . d — r O N m Q �O N O M M r Q r Y A E M— M— (D Q Q M r m N O O N d M 06 r r lD lD m tD Q Q Q W Z O A T a A (n ' N 0 0 0 0 0 0 0 0 0 0 0 O L' y a= r U a U _ — z z — r r In cD ID v (D rn .- QN m n d— ID m o m m M v, Wm <D rn o Z d A (o ID m c'i (D cli Q (D M 1* o M, 0 M 0 o rn m O m N Y A J ❑ d U U o f w a LL E u p u cEi W `m x E Q 3 O N N E• ifl m N --- O M M r r m O M M — -- Ix d "w ifi N O M (D r r 0) m m C7 N Q p 4 p M o 0 0 0 0 0 0 0 0 E a >- 'u Ljf N � d E L L 1 ~ o E w w U (n W N O O O O O O O O O O O O W 6 C n 3 E o o m cn y Z U U J❑ LL 3: U N J Z A 0 0) N M r M 01 m Q N tD 4t U a M Q lD m r m 0) >T C C d d F c N A J c "« E a a c o p Q o a 0 R (n p a` m C o N E M d > d w m 0 0 0 0 0 0 0 0 0 0 0 0 o -- d ti V E p c. z Z rn lalK J E U v O i A c c 1 « U o m z� in (O UJ M N Ol d' O 0 0 0 0 0 O C R S w !7 � p p OJ N N V M V N O1 f0 N M Z V O O N O .L-• N m C_ (n O r C N 6 m m vt5 c a o c ui co ai v o ai U C O L= d ry M N N m T G 0 p N O > Y o 3 m o U W W G 10 N N 0 0 0 _ W E A t° N w p o 0 0 0 w W w w W W 0 N Y in 0= , E O N r M N O QJ C O ? M N � � N z U C N o 0 0 0 o 0 o 0 0 F „ E o 0 0 0 0 0 0 > y E F Y C7 _ Y O U Z Z � — — a_ N T O m Y m m a Zi Z y cEi E cEi w E d Q J O N N f' O U E N m r O M N — N O NE0 � a d } O H to C m W C ' �2 E O M C W O o y WU o E a 00 m E t a t n F U N M M V (n W y O O O O O O m 3 E O 0 o: m q o Z N ` o J J❑ LL U N% Z Q .� o r o N v U U W d rn v W H C N N J c E 'N m w E E t - °r, o° r ❑ U m _ _ _ _ _ C °° 7r co Z o ~ Iri a a+ a ti m m o cn . E CL = > d m 0 0 0 0 0 0 0 .R. ai W 0w iconin' > U m z 5O rn 6J N 0) I� i- O M M 01 Q7 co 0 0 0 m m- r m m- N m m C @ -- -- C O O O ' T N O N m M 0O OMi -9 O) O OJ W CO W W aD Z 1 M "00 N t O O O O O O O O Cl 0 0 0 0 O O N O i to -O 2. m O) U �O O C C C t = y@ N N N N N N N N N N N O V N N T C 0 O o i> Y o 3 3 �n •� u F O V O U N W R V O V V _ V V V V V V V V d' W �_ N W E N L �_ N N 0 0 0 0 0 0 0 0 0 0 0 0 0 O = T '� -`� Y U w W W W W W W W W W W W W W W N (/) F (O (O N N N N N N (O 'L E o 0 0 0 0 0 0 0 0 0 0 0 0 0 > N E U Z Z M v M 0 o v 7 — — ~ O O a o IT N N Q L: `w ' ri o ri N ui z «@ M M M N N N N N O O Y T @ U @ � C ❑ J _ 3 E w a « LL @ d u u w E ' d 6 ULLE YG N z _N O O M N N of N O M M Q 3 O N N N O' E W ui ui o - 1� r r W 00 N w OJ O M M M C> Q O a 0 N e- M 0 0 0 0 0 0 0 0 0 0 0 0 0 rG E .Q = O C) W w 'u @ M C_ •E O O w U oN m t .c y a ~ U E m a x ❑ ❑ L N S N r S S= W N (A O O O O O O O 0 0 0 0 0 0 C A 3 E O o o m n o J u V U L N J❑ w LL U i Z rG 2E '.'E 2 p W N C ~ •E 41 y 'a J w c A o n u 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Z y N M N N co 7? 0 0 0 0 0 0 0 0 0 0 0 0 0 N C O N o @ U o Y cf) M 4 O •• O W OO I� N N V M N" O O) N I� ' 1� z z m❑ o w J E c c c U 3 c V o 2 � a m° � m° m° m° z w GET Virginia Beach Office 204 Grayson Road Virginia Beach, VA 23462 (757)518-1703 Williamsburg Office 1592 Penniman Rd. Suite E Williamsburg, Virginia 23185 (757)564-6452 CLASSIFICATION SYSTEM FOR SOIL EXPLORATION Elizabeth City Office 504 Fast Elizabeth St. Suite 2 Elizabeth City, NC 27909 (252) 335-9765 Standard Penetration Test (SPT). N-value Standard Penetration Tests (SPT) were performed in the field in general accordance with ASTM D 1586. The soil samples were obtained with a standard 1.4" LID., 2" O.D., 30" long split -spoon sampler. The sampler was driven with blows of a 140 lb. hammer falling 30 inches. The number of blows required to drive the sampler each 6-inch increment (4 increments for each soil sample) of penetration was recorded and is shown on the boring logs. The sum of the second and third penetration increments is termed the SPT N-value. NON COHESIVE SOILS (SILT, SAND, GRAVEL and Combinations) Relative Density Very Loose 4 blows/ft. or less Loose 5 to 10 blows/ft. Medium Dense I to 30 blows/ft. Dense 31 to 50 blows/ft. Very Dense 51 blows/ft. or more Particle Size Identification Boulders 8 inch diameter or more Cobbles 3 to 8 inch diameter Gravel Coarse 1 to 3 inch diameter Medium 1/2 to I inch diameter Fine I/a to 1/z inch diameter Sand Coarse 2.00 mm to 1/a inch (diameter of pencil lead) Medium 0.42 to 2.00 mm (diameter of broom straw) Fine 0.074 to 0.42 mm (diameter of human hair) Silt 0.002 to 0.074 mm (cannot see particles) CLASSIFICATION SYMBOLS (ASTM D 2487 and D 2488) Coarse Grained Soils More than 50%retained on No 200 sieve GW - Well -graded Gravel GP - Poorly graded Gravel GW-GM - Well -graded Gravel w/Silt GW-GC - Well -graded Gravel w/Clay GP -GM - Poorly graded Gravel w/Silt GP -CC - Poorly graded Gravel w/Clay GM - Silty Gravel GC - Clayey Gravel GC -GM - Silty, Clayey Gravel SW - Well -graded Sand SP - Poorly graded Sand SW-SM - Well -graded Sand w/Silt SW -SC - Well -graded Sand w/Clay SP-SM - Poorly graded Sand w/Silt SP-SC - Poorly graded Sand w/Clay SM - Silty Sand SC - Clayey Sand SC-SM - Silty, Clayey Sand Fine -Gained Soils 50%or more pass s the No. 200 sieve CL - Lean Clay CL-ML - Silty Clay ML - Silt OL - Organic Clay/Silt Liquid Limit 50%orgreater CH - Fat Clay MH - Elastic Silt OH - Organic Clay/Silt Highly Organic Soils PT - Peat COHESIVE SOILS (CLAY, SILT and Combinations) Consistency Very Soft 2 blows/ft. or less Soft 3 to 4 blows/ft. Medium Stiff 5 to 8 blows/ft. Stiff 9 to 15 blows/ft. Very Stiff 16 to 30 blows/ft. Hard 31 blows/ft. or more Relative Proportions Descriptive Term Percent Trace 0-5 Few 5-10 Little 15-25 Some 30-45 Mostly 50-100 Strata Changes In the column "Description" on the boring log, the horizontal lines represent approximate strata changes. roundwater Readings Groundwater conditions will vary with environmental variations and seasonal conditions, such as the frequency and magnitude of rainfall patterns, as well as tidal influences and man-made influences, such as existing swales, drainage ponds, underdrains and areas of covered soil (paved parking lots, side walks, etc.). Depending on percentage of fines (fraction smaller than No. 200 sieve size), coarse -grained soils are classified as follows: Less than 5 percent G W, GP, SW,SP More than 12 percent GM, GC, SM, SC ' 5 to 12 percent Borderline cases requiring dual symbols Plasticity Chart ■■■■■■■■., t �. twttta w a GET Revision 1V12/07 LIQUID LIMIT ILL) (%) ir 41, 1 I 7p7 I { 1! f rn aFi {�I FFF I. i `1 1. It 1f j ♦a a f } { c o + lJ f T 4 < 1 ♦. L nwi I 1 4 V f i 0