The URL can be used to link to this page

Home My WebLink AboutApplication-PermitI Garfield County Building & Planning Department 108 8th Street, Suite #401 Glenwood Springs, Co. 81601 Office:970·945·8212 Fax: 970·384·3470 Inspection Line: 970·384·5003 Building Permit No. Parcel No: 2409-352-00-151 Locality: Job Address: 1620 CR 300 Parachute ~~--~---··---·-·· . ·--·--··· ~~- Use of Building: ------~Tl_~osure for a natural g~~ comJlr_EJssor-unit C-32!_ _ ________ _ Owner: Williams Production RMT Contractor: Williams Production RMT Fees: Plan Check: $ 130.44 Septic: ... ·~·---.. ·-~~---~ Bldg Permit: $ 401.35 Other Fees: Total Fees: $ 531.79 Clerk: Date: I 1 2 3 4 5 6 7 8 9 GARFIELD COUNTY BUILDING PERMIT APPLICATION 108 gth Street, Suite 401, Glenwood Springs, Co 81601 Phone: 970-945-8212/ Fax: 970-384-3470 I Inspection Line: 970-384-5003 www.garfield"countv.com Parcel No: (this information is available at the assessors office 970-945-9134) l<o ~0 Cit .Soo 2409-352-00-151 Job Address: (if an address has not been assigned, please provide Cr, Hwy or Street Name & City) or and legal desctiption p(L(Ci.. Cc 'iS/to SJ~ SW 1/4 NW 1/4 of Section 35, Township 7 South, Range 96 west of the 6th P.M. Garfield County, CO Lot No: Block No: Subd./ Exemption: Owner: (prope~ owner) Maili{§ Address: Ph: AltPh; Williams Pro uction RMT Co. 1058 R 215 Parachute, CO 81635 970-263-27 43 Contractor: MailiC Address: Ph: AltPh: Williams Production RMT CO. 1058 R 215 Parachute, CO 81635 970-263-27 43 Architect I Engineer: Mailing Address: Ph: AltPh: S.M. Naeem Akhter 8WDryCreekCircLittletonC080120 303-513-3632 S~ Ft. of Building: SSJ. Ft. or Acres of Lot: '-/O(LCA!uJ He~1t: No. of Floors: 63 s.f. 2. 55 acres 20'~ " 1 Use of Building: Acoustical Enclosure for a Natural Gas Compressor-Unit C-321-F2 Occupancy ~ (.'1JA {;.;., Jtr-L Describe Work: ' AO Construction of an acoustical enclosure foundation and building. Garfield County SUP 2008-137 -r~ fiAn "r-6\. 10 Class of Work: s.-,_ . ftlNew o Alteration o Addition II Garage: Septic: o Attached 0 Detached o ISDS o Community 12 Driveway Permit: Owners valuation of Work: $30,000.00 $ NOTICE .A!!!hru:.i!Y. This application for a Building Permit must be signed by the Owner of the property, described above, or an authorized agent. If the signature below is not that of tho Owner, a separate letter of a\Jthority, signed by the Owner, must be provided with this Application. Legal Access. A Building Permit cannot be issued without proof of legal and adeqm'lte access to the property for p\lrposes of inspections by the Building Department. Other l~ermit~. Multiple separate permits may be required: (l} State Electrical Permit, (2) Cmmty ISDS Permit, (3) another permit required for me on the property identified above, e.g. State or County Highway/ Road Access or a State Wnstewater Discharge Permit. Void Permit. A Building Permit becomes null and void ifthc work authorized is not commenced within 180 days of the date of issuance and if work is suspended or abandoned for a period of J 80 days after commencement CERTIFICATION I hereby certify that I have read this Application and that the information contained above is true and correct. I understand that the Building Department accepts the Application, along with the plans and specifications and other data submitted by me or on my behalf (submittals}, based upon my certification as to accuracy. Assuming completeness of the submittals and approval of this Application, a Bt1ilding Permit will be issued granting permission to me, as Owner, to construct the structure(s) and facilities detailed on the submittals reviewed by tl1c Building Department. In consideration of the issuance of the Building Penn it, I agree that I and my agents will comply with provisions of any federal, state or local law regulating the work and the Gal'field County Building Code, ISDS regulations and applicable land use regulations (County Regulation(s)). I aclmowledge that the Building Pcnnit may be suspended or revoked, upon notice from the County, if the location, construction or use ofthe StnlCture(s) and facility(ies}, described above, are not in compliance with Cmmty Regulation(s) or any other applicable law. I hereby grant permission to the Building Department to enter the property, described above, to inspect the work. I further aclmowledgc that the issuance of the Building Permit does not prevent the Building Official from: (I) requiring the correction oferrors in the submittals, if any, discovered after issuance; or (2) stopping construction or usc ofthe structure(s) or facility(ies} if such is in violation of County Rcgulation(s) or any other applicable law. Review of this Application, including submitta'ls, ana lnspections of the work by the Building Department do not com;titute an acceptance of responsibility or liability by the County of errors, omissions or discrepancies. As the Owner, I acknowledge that responsibility fur compliance with federal, state and local laws and County Regulations rest with me and my authorized agents, including without limitation my architect designer, engineer and/ or builder. I HEREBY ACKNOWLEDGE THAT I HAVE READ AND UNDERSTAND THE NOTICE & CERTIFICATION ABOVE: fu;, ~~ ~~~~ri'L_ 2/18/09 Please call Phil Vaughan 625-5350 when permit is readY OWNERS SIGNATURE DATE STAFF USE ONLY speeiai;t~~'1zvx\q.~ ?M~~ ~ Adjusted Valuation: Plan Cbeck Fee: Pei"mit Fee: Manu home Fee: Mise Fees: 2.54MJ.'72 I i'?0·11 40~. '75 ISDS Fee: Total Fees: 11-q~'.'JO Balance Due: BP No & Issue Date: ISDS No & Issued Date: .5~(. 7'1 2~~.oq Jt232 2t. "b.O( Setbacks: OCC Group: Const Type: Zoning: R lD~PT: ·~· I ·APP~-~tDATE ~~'-V~ P~E~1 ~ ' APP o~•-: ~t~ 2i~gfG The following items are required by Garfield County for a final Inspection: 1) A final Electrical Inspection from the Colorado State Electrical Inspector. 2) Petmanent address assigned by Garfield County Building Department and posted at the structure and where readily visible from access road. 3) A finished roof; a lockable building; completed exterior siding; exterior doors and windows installed; a complete kitchen with cabinets, sink with hot & cold running water, non-absorbent kitchen floor covering, counter tops and finished walls, ready for stove and refrigerator; all necessary plumbing. 4) All bathrooms must be complete, with washbowl, tub or shower, toilet, hot and cold running water, non-absorbent floors, walls finished, and privacy door. 5) Steps over three (3) risers, outside or inside must be must have handrails. Balconies and decks over 30" high must be constructed to all IBC and IRC requirements including guardrails. 6) Outside grading completed so that water slopes away from the building; 7) Exceptions to the outside steps, decks, grading may be made upon the demonstration of extenuating circumstances., i.e. weather. Under such circumstances A Certificate of Occupancy may be issued conditionally. 8) A final inspection sign off by the Garfield County Road & Bridge Department for driveway installation, where applicable; as well as any final sign off by the Fire District, and/or State Agencies where applicable. A CERTIFICATE OF OCCUPANCY (C.O.) WILL NOT BE ISSUED UNTIL ALL THE ABOVE ITEMS HAVE BEEN COMPLETED. A C.O. MAY TAKE UP TO 5 BUSINESS DAYS TO BE PROCESSED AND ISSUED. OWNER CANNOT OCCUPY OR USE DWELLING UNTIL A C.O. IS ISSUED. OCCUPANCY OR USE OF DWELLING WITHOUT A C.O. WILL BE CONSIDERED AN ILLEGAL OCCUPANCY AND MAY BE GROUNDS FOR VACATING PREMISES UNTIL ABOVE CONDITIONS ARE MET. I understand and agree to abide by the above conditions for occupancy, use and the issuance of a C.O. for the building identified in the Building Permit. ~~~~~"~ 2/18/09 OWNERS SIGNATURE DATE Bapplicationdecember2007 GARFIELD COUNTY BUILDING AND PLANNING 970-945-8212 MINIMUM APPLICATION REQUIREMENTS FOR CONSTRUCTION OF COMMERCIAL OR MULTI-FAMILY RESIDENTIAL BUILDINGS Including NEW CONSTRUCTION ADDITIONS ALTERATIONS And MOVED BUILDINGS In order to understand the scope of the work intended under a permit application and expedite the issuance of a permit it is important that complete information be provided. When reviewing a plan and it's discovered that required information has not been provided by the applicant, this will result in the delay of the permit issuance and in proceeding with building construction. The owner or contractor shall be required to provide this information before the plan review can proceed. Other plans that are in line for review may be given attention before the new information may be reviewed after it has been provided to the Building Department. Please review this document to determine if you have enough information to design your project and provide adequate information to facilitate a plan review. Also, please consider using a design professional for assistance in your design and a construction professional for construction of your project. Any project with more than ten (10) occupants requires the plans to be sealed by a Colorado Registered Design Professional. To provide for a more understandable plan and in order to determine compliance with the building, plumbing and mechanical codes, applicants are requested to review the following checklist prior to and during design. Plans to be included for a Building Permit must be on draft paper at least 18"x 24"" and drawn to scale. Plans must include a floor plan, a concrete footing and foundation plan, elevations all sides with decks, balcony steps, hand rails and guard rails, windows and doors, including the finish grade and original grade line. A section showing in detail, from the bottom of the footing to the top of the roof, including re-bar, anchor bolts, pressure treated plates, floor joists, wall studs and spacing, insulation, sheeting, house-rap, (which is required), siding or any approved building mate1ial. Engineered foundations may be required. Check with the Building Department. A window schedule. A door schedule. A floor framing plan, a roofing framing plan, roof must be designed to withstand a 40 pound per square foot up to 7,000 feet in elevation, a 90 M.P.H. windspeed, wind exposure B or C, and a 36 inch frost depth. All sheets need to be identified by number and indexed. All of the above requirements must be met or your plans will be returned. All plans submitted must be in compliance with the 2003 IBC, IPC, IMC, IFGC, and IFC. Applicants are required to indicate appropriately and to submit completed checklist at time of application for a permit: I. Is a site plan included that identifies the location of the proposed structure, additions or other buildings, setback easements, and utility easements showing distances to the property Jines from each comer of the proposed structure prepared by a licensed surveyor and has the surveyors signature and professional stamp on the drawing? Slopes of 30% or more on properties must be show on site plan. (NOTE: Section 106.2) Any site plan for the placement of any portion of a structure within 50 ft. of a property line and not within a previously surveyed building envelope on a subdivision final plat shall be prepared by a licensed surveyor and have the surveyors signature and professional stamp on the drawing. Any structure to be built within a building envelope of a lot shown on a recorded subdivision plat, shall include a copy of the building envelope as it is shown on the final plat with the proposed structure located within the envelope. Yes._X __ _ 2. Does the site plan when applicable include the location of the I.S.D.S. (Individual Sewage Disposal System) and distances to the property lines, wells (on subject property and adjacent properties), streams or water courses? This information must be certified by a licensed surveyor with their signature and professional stamp on the design. Yes Not necessary for this project _x __ 3. Does the site plan indicate the location and direction of the State, County or private road accessing the property? YesX __ 4. Is the I.S.D.S. (Individual Sewage Disposal System) designed, stamped and signed by a Colorado Registered Engineer? Yes Not necessary for this projectX __ _ 5. Are the plans submitted for application review construction drawings and not drawings that are stamped or marked identifYing them as "Not for construction, for permit issuance only", "Approval drawings only", "For petmit issuance only" or similar language? YesX Not necessary for this project __ _ 6. Do the plans include a foundation plan indicating the size, location and spacing of all reinforcing steel in accordance with the building code or per stamped engineered design? Y esX __ Not necessary for this project __ 2 7. If the building is a pre-engineered structure, is there a stamped, signed engineered foundation plan for this building? Y esX __ Not necessary for this project __ 8. Do the plans indicate the location and size of ventilation openings for under floor crawl spaces and the clearances required between wood and earth? Yes __ Not necessary for project X __ 9. Do the plans indicate the size and location of the ventilation openings for the attic, roof joist spaces and soffits? Yes __ Not necessary for this project X __ I 0. Do the plans include design loads as required under the IBC or IRC for roof snow loads, (a minimum of 40 pounds per square foot in Garfield County)? YesX __ Not necessary for this project __ II. Do the plans include design loads as required for floor loads under the IBC or IRC? Yes __ Not necessary for this project_X __ 12. Does the plan include a building section drawing indicating foundation, wall, floor, and roof construction? YesX __ Not necessary for this project __ 13. Is the wind speed and exposure design included in the plan? Yes_X __ Not necessary for this project __ 14. Does the building section drawing include size and spacing of floor joists, wall studs, ceiling joists, roof rafters or joists or trusses? Yes_X __ Not necessa1y for this project __ 15. Does the building section drawing or other detail include the method of positive connection of all columns and beams? Yes_X __ Not necessary for this project __ 16. Does the elevation plan indicate the height of the building or proposed addition from the undisturbed grade to the midpoint between the ridge and eave of a gable or shed roof or the top of a flat roof? (Check applicable zone district for building height maximum) Y es_X __ Not necessary for this project __ 3 17. Does the plan include any stove or zero clearance fireplace planned for installation including make and model and Colorado Phase II certifications or Phase II EPA certification? Yes __ Not necessary for this projectX __ 18. Does the plan include a masonry fireplace including a fireplace section indicating design to comply with the IBC or IRC? Yes __ Not necessary for this projectX __ 19. Does the plan include a window schedule or other ve1ification that egress/rescue windows from sleeping rooms and/or basements comply with the requirements of the IBC or IRC? Yes __ Not necessary for this projectX __ 20. Does the plan include a window schedule or other verification that windows provide natural light and ventilation for all habitable rooms? Yes __ Not necessary for this projectX __ 21. Do the plans indicate the location of glazing subject to human impact such as glass doors, glazing immediately adjacent to such doors; glazing adjacent to any surface normally used as a walking surface; sliding glass doors; fixed glass panels; shower doors and tub enclosures and specify safety glazing for these areas? Yes __ Not necessary for this project_X __ 22. Do the plans include a complete design for all mechanical systems plmmed for installation in this building? Yes_X __ No Not necessary for this project __ _ 23. Have all areas in the building been accurately identified for the intended use? (Occupancy as identified in the IBC Chapter 3) YesX __ Not necessary for this project. __ _ 24. Does the plan indicate the quantity, form, use and storage of any hazardous mate1ials that may be in use in this building? Yes __ Not necessary for this projectX __ 25. Is the location of all natural and liquid petroleum gas furnaces, boilers and water heaters indicated on the plan? Yes ___ Not necessary for this project_X __ 26. Do the plans indicate the location and dimension of restroom facilities and if more than four employees and both sexes are employed, facilities for both sexes? Yes __ Not necessary for this project_X __ 4 27. Do the plans indicate that restrooms and access to the building are handicapped accessible? Yes __ Not necessary for this project X __ 28. Have two (2) complete sets of construction drawings been submitted with the application? YesX __ 29. Have you designed or had this plan designed while considering building and other construction code requirements? YesX 30. Does the plan accurately indicate what you intend to construct and what will receive a final inspection by the Garfield County Building Department? YesX 31. Do your plans comply with all zoning rules and regulations in the County related to your zone district? For comer lots see supplemental section 5.05.03 in the Garfield County Zoning Resolution for setbacks. YesX __ _ 32. Do you understand that approval for design and/or construction changes are required prior to the implementation of these changes? YesX __ 33. Do you understand that the Building Department will collect a "Plan Review" fee from you at the time of application and that you will be required to pay the "Permit" fee as well as any "Septic System" or "Road Impact" fees required, at the time you pick up your building permit? YesX __ . 34. Are you aware that you are required to call for all inspections required under the IBC including approval on a final inspection prior to receiving a Certificate of Occupancy and occupancy of the building? Yes~- 35. Are you aware that the Permit Application must be signed by the Owner or a written authority be given for an Agent and that the party responsible for the project must comply with the Uniform Codes? YesX __ . 36. Are you aware that you must call in for an inspection by 3:30 the business day before the requested inspection in order to receive it the following business day? Inspections will be made between 7:30 a.m. and 3:30p.m. Monday through Friday. Inspections are to be called in to 384-5003. Yes_X __ 5 37. Are you aware that requesting inspections on work that is not ready or not accessible will result in a $50.00 re-inspection fee? Yes_X __ 38. Are you aware that prior to submittal of a building permit application you are required to show proof of a legal and adequate access to the site? This may include (but is not limited to) proof of your right to use a private easement/right of way; a County Road and Bridge permit; a Colorado Dept. of Highway Permit including a Notice to Proceed; a permit from the federal government or any combination. You can contact the Road & Bridge Department at 625-8601. See Phone book for other agencies YesX __ 39. Do you understand that you will be required to hire a State of Colorado Licensed Electrician and Plumber to perform installations and hookups? The license number will be required at time of inspection. YesX 40. Are you aware, that on the front of the building permit application you will need to fill in the Parcel/ Schedule Number for the lot you are applying for this permit on prior to submittal of the building permit application? Your attention in this is appreciated. Yes_X __ 41. Do you know that the local fire district may require you to submit plans for their review of fire safety issues? Yes_X __ (Please check with the building department about this requirement) 42. Do you understand that if you are planning on doing any excavating or grading to the property prior to issuance of a building permit that you will be required to obtain a grading permit? Yes X__ Not necessmy for this project __ 43. Did an Architect seal the plans for your commercial project? State Law requires any commercial project with occupancy of more than 10 persons as per Section 1004 of the IBC to prepare the plans and specifications for the project. Yes Not Necessmy for this project _x ____ _ 44. If you anticipate obtaining a water tap from the City of Rifle, please provide a letter indicating that the City will provide water setvice. No building permit application will be accepted without such a letter. Yes 6 I hereby acknowledge that I have read, understand, and answered these questions to the best of my ability. 2/19/09 Date 970-625-5350 Phone: _______ .( days); _________ (evenings) Una Compressor Station-Acoustical Encl. C-321 Project Name: ________________ _ SW1/4 NW1/4, Sec. 35, T7S, R96W of the 6thP~ Project Address: D Note: On any of these questions you may be required to provide this information. If required information is not supplied, delays in issuing the permit are to be expected. Work may not proceed without the issuance of the permit. *If you have answered "Not necessary for this project" on any of the questions and it is determined by the Building Official that the information is necessary to review the application and plans to determine minimum compliance with the adopted codes, please expect the following: A. The application may be placed behind more recent applications for building permits in the review process and not reviewed until required information has been provided and the application rotates again to first position for review. B. Delay in issuance of the permit. C. Delay in proceeding with constmction. BpcommDec2007 7 February 12, 2009 Mr. Fred Jarman Director Garfield County Building and Planning Department 1 08 glh Street, Suite 401 Glenwood Springs, Colorado 81601 Dear Mr. Jarman: Williams Production R.ivtT Company 'fiwver 3, Suire lOOO 1515 Arapahoe Street Denver, CO 80202 303/572-3900 main .~0.~/629·8282 f.tx By this letter, Williams Production RMT Co. and Bargath Inc. authorize PVCMI-Land Planning Division to represent us in any and all matters related to the building permit applications known as the Una Compressor Station Noise Enclosures for Units C-321, C-322, and C-323 located in the SW1/4 NWl/4 of Section 35, Township 7 South, Range 96 West, of the 61h P.M. on Garfield County Assessor's Parcel number 2409-352-00-151. This includes the preparation and submission of documents associated with the land use applications and representation of these applications before the applicable appointed and elected boards. Sincerely, Mr. Eric Miller Director of Facilities and Gathering Bargath Inc. Williams Production RMT Co. October I, 2008 Garfield County 1 09 s"' Street Glenwood Springs, CO 81601 RE: Authority as Agent Dear Cmmty Representative; EXl'LOliATION I!! PllOOtiGTION lOSS CR#2JS P.O.Bt».:,?70 l7a.Jdmrc, CO .81635-0370 970/285-9377 9701285~951.3 (;)X Tilis letter is to confmn tbe appointment of Sandy Hotard and Eric Miller as authorized Agents to execute documents for tbe following; • Williams Production RMl' Company • ll:argath Inc. • Wilgath LLC • Ryan Gulch LLC This authority is granted for all documents furnished to Garfield County. Sincerely, Alan Harrison Vice President Denver Region D!U3\SH 10/01/{lll Project: Williams Gas ANM Proj. #: 722500 Date: Febmary 09, 2009 Document: Mechanical Calculations Total Pages: 3 Page Total Included Calculations: Prepared by: Reviewed by: • Ventilation Calculations Diana Benson, B. Tech. Mechanical Designer Ralph Wesche, P. Eng. Chief Mechanical Engineer ATCO Noise Management Ltd. 1243 McKnight Blvd NE, Calgary, AB T2E STI Bus: (403) 292-7804 Fax: (403) E-mail: info@atconoise.com 722500 Williams Gas -Mech. Cales. 02/09/09 DB CAT engine G3516 obtained a heat rejection and combustion air inlet flow as stated below from the CAT engine specifications; HREngine= 7155 BTU/Min = 429,300 BTU/Hr Combustion air inlet flow = 3435 CFM Assumed compressor heat rejection to be 15% of engine heat rejection; HRcompressor= 15% (429,300 BTU/Hr) = 64,395 BTU/Hr Total heat rejection of building; HRTotal = 493,695 BTU/Hr Design Temps: Design Elev.: Density Ratio: Definition: Outdoor= 100.6° F TR=40°F 4839 ft 0.85 Q = Airflow in CFM Q = (493.695 BTU/Hr) ( 40°F)(0.85) = 14,520 CFM Safety Factor; Q = (14,250 CFM)(1.15) = 16,698 CFM Total CFM of building; Q = 16,698 CFM + 3435CFM = 20,133 CFM Inlet openings: (1200 FPM) 2 inlets allowing 10,067 CFM at an opening of 35" x 35" ATCO Noise Management Ltd Page 2 of3 722500 Williams Gas -Mech. Cales. Exhaust openings: (1200 FPM) 2 exhaust fans allowing 8349 CFM at an opening of 32" x 32'' Volume Vtotal = (22 ft)(30 ft)(21 ft) = 13,860 rtl Ventilation required= AirC/Hr = (20.648 CFM) * 60 (13,860 ft 3) = 89 AirC/Hr ATCO Noise Management Ltd 02/09/09 DB Page 3 of3 nllll GEClrFEG:rt!NIID.ts.~ . EI'{GJNEERING GRLJIJFl. August 12, 2010 Williams Production RMT Company P.O. Box370 Parachute, Colorado 81635 Attention: Mr. Tom Fiore· Subject: UNA Compressor Station Enclosure Foundations Garfield Building Permit Nos. 11232, 11233 & 11234 Garfield County, Colorado GEG Job No. 3,128 Dear Mr. Fiore, Garfield County Building Department Permit Nos. 11232, 11233 and 11234 relate to foundation support of noise enclosure structures for the three existing compressors at Williams Una Compressor station located in Garfield County, Colorado. The purpose of this letter is to present a summary the foundations are installed in general conformance with the design by this firm. Foundation designs are presented in the "Williams Production RMT, UNA Compressor Unit Acoustic Enclosure, Helical Pier Foundation Design Amendment, Garfield County, Colorado", Sheets 1 thru 3 of 3, dated March 25, 2010. As requested, a Geotechnical Engineering Group, Inc. (GEG) representative observed the installation of helical piers and structural connections during construction. It is our opinion the noise enclosure foundations, permit numbers 11232, 11233 & 11234 are completed in a manner that is consistent with design specifications and industry standards at this time. Geotechnical, Environmental and f)llaterials Testing Consultants Grand Junction -Montrose -Moab -Crested Butte -Rifle (970) 245-4078 • fax (970) 245-7115 • geotechnicalgroup.com 2308 Interstate Avenue, Grand Junction, Colorado 81505 If we may be of further service in discussing the contents of this report or the engineering aspects of this project please contact us. Sincerely, GEOTECHNICAL ENGINEERING GROUP, INC. Scott Godfrey, E.I.T. Project Engineer SEG: JPW: SG Reviewed by: John P. Withers, P.E. Principal Engineer 1cc: emailed Tom Fiore- 1cc: emailed Phil Vaughan- Tom. Fiore@Williams.com phil@pvcmi.com GEG Job No.3, 128 Williams Production RMT UNA Compressor Station Enclosure Foundations August 12, 2010 2 Parcel Oetail Garfield County Assessor IT reasurer Parcel Detail Information Page I of 5 Ass~.~~m:IT rBasurBr Prop~ITtyjBarch I As_~-~~!J.r..SubsBt O.uBry I A-~~~s~orS!ll~~S_B.i!r:.Gh CIBrk o RBcgrdflLRBG_B.Qtion Smch Basic Buildirm_C_bilfilJjBristics I Iildof!l.r!mtio_l} ParG.~.LOfl.tail I ~almLD_~!!liJ I SaiBs DBtaH I HB~identiai/CommBn::iCJIJmpr.QY.~rnB.OJJlgtail 1CJHdD.e1CJil I PhqtugrilRh~ I MilLigyy_fulven_u!tsD_~JaJI I Tax Area I Account Nu Parcel Number I2DDB Mill levy I I 027 II RDD5875 1 24os352ool51 1 35.oo7 I Dwner Name and Mailing Address !WILLIAMS PRODUCTION RMT COMPANY liD 58 CNTY RD 215 !PARACHUTE. CD 81835 Assessor's Parcel Description (Not to be used as a legal description) ISECT.TWN.RNG:35-7-86 DESC: SWNW IPRE:RDDS873 BK:D873 PG:D786 BK:DSDI IPG:D658 BK:D581 PG:D255 BK:D58D IPG:DD66 BK:D568 PG:D664 BK:DS68 IPG:D3DI HK:I84D PG:818 RECPT:706386 IBK:I84D PG:817 RECPT:706385 BK:I203 IPG:425 RECPT:568115 BK:II85 PG:443 IRECPT:56283D BK:II85 PG:44D http:// www.garcoact.com/ assessor I parcel.asp?Parcel Number= 2 40835200151 I I I I I I I I I I I 2/1812009 Parcel Detail Page 2 of 5 IRECPT:5S2S2S BK:II35 PG:820-823 I IRECPT:547474 BK:II35 PG:818-81S I IRECPT:547473 BK:II35 PG:BIB-817 I IRECPT:547742 BK:II27 PG:710 I IRECPT:544008 BK:II28 PG:41 I IRECPT:5443S3 81<:1128 PG:40 I IRECPT:5443S3 BK:OS48 PG:OOI8 I location I Physical Address: 111820 300 COUNTY RO PARACHUTE I I Subdivision: I I Land Acres: 1140 I I Land Sq Ft: I 0 I Section II Township II Range I I 35 II 7 II 88 I 211118 Property Tax Valuation Information II Actual Value II Assessed Value I I Land: II 135.oooll 10.7501 I Improvements: II 182.58011 15.3301 I Total: II 327.58011 28.0801 Most Recent Sale Sale Date: IIS/7/2008 Sale Price: 11385.000 http:! I www.garcoact.coml assessor I parcel.asp?ParceiNumber= 2 40935200151 211812009 Page 3 of 5 Basic Building Characteristics Number of Residential II Buildings: I Number of Comm/lnd lo I Buildings: I Residential Building 11ccurrence I Characteristics I I I STIJRY: jji.B20 I I TIJTAL HEATED AREA: )ji.B20 I I ABSTRACT CI111E: jjSINGLE FAM.RES-IMPROVEMTS I I ARCHITECTURAL STYLE: j)MODULAR -UBC/IRC/IBC I I EXTERIIJR WALL: jjMASONITE I I RI111HI1VER: JICOMP SHNGL I I RI111F STRUCTURE: jjGABLE I I INTERIIJR WALL: I DRYWALL I FL1111R: I SHT VINYL I FLI111R: ))CARPET I I HEATING FUEL: IiGAS I I HEATING TYPE: jjFDRCED AIR I I STIJRIES: jjSTDRIES 1.0 I I BATHS: 12 I RI111MS: js I UNITS: jl I BEDRI111MS: I 3 I YEAR BUILT: jji9SS I Tax Information http:!/ www.garcoact.com/ assessor I parcel.asp?ParceiNumber= 2 4093520 0151 2/1812009 Parcel Detail Page 4 of 5 I Tax Year II Transaction Type II Amount I I 2008 II Tax Payment: Whole II ($813.00)1 I 2008 II Tax Amount II $813.001 I 2007 II Tax Payment: Whole I ($848.36)1 I 2007 II Tax Amount $848.361 I 2006 II Tax Payment: Whole I ($772.40)1 I 2006 Tax Amount $772.401 I 2005 Tax Payment: Second Half ($387.08)1 I 2005 I Tax Payment: First Half I ($387.08)1 I 2005 II Tax Amount II $774.181 I 2004 II Tax Payment: Second Half II ($388.63)1 I 2004 I Tax Payment: First Half II ($388.63)1 2004 Tax Amount II $778.261 2003 I Tax Payment: Second Half II ($418.07)1 2003 II Tax Payment: First Half II ($418.07)1 2003 I Tax Amount II $836.141 I 2002 Interest Payment ($3.55)1 I 2002 Interest Charge $3.551 I 2002 I Tax Payment: Second Half I ($354.72)1 I 2002 II Tax Payment: First Half II ($354.72)1 I 2002 II Tax Amount II $708.441 I 2001 II Tax Payment: Second Half II ($378.28)1 I 2001 II Tax Payment: First Half II ($378.28)1 2001 II Tax Amount II $756.581 2000 II Tax Payment: Whole II ($11.10)1 2000 II Tax Payment: First Half II $5.551 2000 II Tax Payment: First Half II ($5.55)1 I 2000 II Tax Amount II $11.101 http:// www.garcoact.com/ assessor I parcel. asp ?ParceiNumber= 2 4093520 0151 2/1812009 Geoteehnieal I ... Engiueering I Group, Ine. GEOTECHNICAL INVESTIGATION UNA Compressor Station Williams Production RMT Company Southwest '!. of the Northwest '!. of Section 35, Township 7 South, Range 96 West, 61h Principal Meridian, Garfield County, Colorado Prepared For: Star Valley Engineering 107657 N. U.S. Highway 89 Etna, WY 83118 Attention: Mr. Charles Bucans Job No. 3,071 November 5, 2008 Geotechnical, Environmental and Materials Testing Consultants Grand Junction -Montrose -Moab -Crested Butte (970) 245-4078 • fax (970) 245-7115 • geotechnicalgroup.com 2308 Interstate Avenue, Grand Junction, Colorado 81505 TABLE OF CONTENTS SCOPE ............................................................................................................................................ 1 SUMMARY OF CONCLUSIONS .................................................................................................... 2 SITE CONDITIONS ......................................................................................................................... 2 PROPOSED CONSTRUCTION ...................................................................................................... 3 SUBSURFACE CONDITIONS ........................................................................................................ 4 SITE DEVELOPMENT .................................................................................................................... 5 EXCAVATION ................................................................................................................................. 6 EMBANKMENT ............................................................................................................................... 8 FOUNDATIONS ............................................................................................................................ 10 DRIVEN FRICTION PILES ............................................................................................................... 11 DRILLED PIER AND SCREW PILE FOUNDATIONS ............................................................................ 13 SPREAD FOOTINGS-STRUCTURES WHERE MORE RISK OF MOVEMENT IS ACCEPTABLE ..................... 15 REINFORCED MAT FOUNDATIONS ................................................................................................. 16 TANK SPREAD FOOTING RING FOUNDATIONS AND TANK BOTTOM SUPPORT .................................. 18 SEISMIC AND VIBRATING FOUNDATION DESIGN CON SID ERA TIONS ................................ 20 FLOOR SYSTEMS ........................................................................................................................ 21 BELOW-GRADE CONSTRUCTION ............................................................................................. 23 SOIL RESISTIVITY CONSIDERATIONS ..................................................................................... 23 PAVEMENT ................................................................................................................................... 23 CONCRETE ................................................................................................................................... 28 SURFACE DRAINAGE ................................................................................................................. 29 CONSTRUCTION MONITORING ................................................................................................. 30 LIMITATIONS ................................................................................................................................ 31 FIG. 1 -VICINITY MAP FIG. 2-LOCATION OF EXPLORATORY BORINGS FIG. 3-KEY TO SYMBOLS FIGS. 4 THROUGH 7-LOGS OF EXPLORATORY BORINGS FIGS. 8 THROUGH 10-SWELL CONSOLIDATION TEST RESULTS FIG. 11 -DIRECT SHEAR TEST RESULTS FIGS. 12 THROUGH 15-GRADATION TEST RESULTS FIG. 16-MOISTURE DENSITY TEST RESULTS FIG. 17-CALIFORNIA BEARING RATIO TEST RESULTS FIG. 18-KEY AND BENCH CONCEPT FIG.19-KEY AND BENCH DRAIN DETAILS TABLES I AND II -SUMMARY OF LABORATORY TEST RESULTS APPENDIX A-SAMPLE SITE GRADING SPECIFICATIONS APPENDIX B-PAVEMENT DESIGN CALCULATIONS APPENDIX C -CONSTRUCTION RECOMMENDATIONS FOR FLEXIBLE AND RIGID PAVEMENT SCOPE This report presents the results of our Geotechnical Investigation for the proposed UNA Compressor Station to be located in the Southwest Y. of the Northwest Y. of Section 35, Township 7 South, Range 96 West, 6th Principal Meridian in Garfield County, Colorado. Our investigation was conducted to explore subsurface conditions and provide foundation design recommendations for the anticipated construction. The report includes descriptions of subsoil and groundwater conditions found in four exploratory borings made during this investigation, recommended foundation systems, allowable design soil pressures and design and construction criteria for details influenced by the subsurface conditions. This investigation was performed in general conformance with our proposal No. 08-133 dated September 24, 2008. The report was prepared from data developed during field exploration, laboratory testing, engineering analysis and experience with similar conditions. A brief summary of our conclusions and recommendations follows. Detailed criteria are presented within the report. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 SUMMARY OF CONCLUSIONS 1. Subsoils found in the exploratory borings consisted generally of 5% to 28% feet of sandy and gravelly clay with cobbles and boulders. No formational material was encountered to a depth of 28% feet, the maximum depth explored. Auger refusal was encountered in all exploratory test borings on cobbles and boulders. Groundwater was not encountered in the exploratory test borings on the day of drilling to the depths explored. 2. We believe a deep foundation such as drilled piers can provide a more positive foundation. An alternative, with risk of movement, footing type foundation bearing on a well-compacted structural fill and reinforced mat foundation is also presented. A discussion, including detailed design and construction criteria are included in the text of the report. 3. Surface drainage should be designed for rapid runoff of surface water away from the proposed structures. SITE CONDITIONS The subject site was located in the Southwest '!. of the Northwest '!. of Section 35, Township 7 South, Range 96 West, 6th Principal Meridian in Garfield County, Colorado. A project vicinity map is shown on Fig.1. The subject site was an existing staging area site adjacent to an existing well pad. The site was relatively flat and had been stripped of vegetation. The south portion of the site contained existing trailers and an operating drill rig. The area south and west of the site sloped down to the site at a inclination of about 1 horizontal to 1 vertical for a height of about 35 to 40 feet and appeared to be an excavation cut slope. The area above the excavation cut slope sloped down toward the site at an inclination of about 3 horizontal to 1 vertical and contained a cover of sage UNA Compressor Station Wllliiil_ms Production RMT Company Garfield County, Colorado Repqrt Dated November 5, 2008 GEG Job No. 3,071 2 brush and Juniper trees. The area north and east of the site sloped down from the site at an inclination of about 1.5 horizontal to 1 vertical for a height of about 50 feet and appeared to be a constructed fill slope. The area beyond the placed fill slope sloped down away from the site at an inclination of about 3 horizontal to 1 vertical or flatter and contained a cover of sage brush and Juniper trees. PROPOSED CONSTRUCTION We understand the proposed construction will consist of a gas compressor station. The proposed construction will include buildings, compressor pads and ancillary equipment. Building foundation loads will include column loads up to 30 Kips. Compressor foundation will be about 12 feet by 30 feet and have a total foundation load up to 1,000 Kips. Miscellaneous Equipment will be skid supported with skid dimensions fo 4 feet by 4 feet to 20 feet by 20 feet. Miscellaneous tanks will be 1 0 feet diameter by 15 feet high to 16 feet diameter by 25 feet high and will be supported by ring-wall foundations. We anticipate differential settlement tolerances for these structures are 2 inches. No below grade construction is planned. Site development may include existing excavation cut slopes up to 35 feet high and existing placed fill slopes up to 50 feet high. If proposed construction changes or is different from what is stated, we should be contacted to review actual construction and our recommendations. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 3 Proposed construction is gas field industrial. There will be no landscaping, irrigation or finished areas. SUBSURFACE CONDITIONS Subsurface conditions at the site were investigated by drilling and sampling four exploratory borings. Locations of the exploratory borings are shown on Fig. 2. Graphic logs of the soils found in the borings and field penetration resistance tests are presented on Figs. 3 through 7. Subsurface conditions encountered consisted generally of 5Y:. to 28Y, feet of sandy and gravelly clay with varying amounts cobbles and boulders. Auger refusal was encountered in all exploratory test borings on cobbles and boulders. When auger refusal was encountered the test boring was offset 5 to 1 0 feet and re-drilled until auger refusal was encountered. No formational material was encountered to a depth of 28Y:. feet, the maximum depth explored. Groundwater was not encountered in the exploratory test borings on the day of drilling. The sandy and gravelly clay was medium stiff to stiff, moist and brown. Existing fill was not encountered in the exploratory test boring, however we anticipate existing fill will be encountered near the northwest edge of the compressor site. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado R~;~port Dated November 5, 2008 GEG Job No. 3,071 4 Four sandy and gravelly clay sample tested had moisture contents of 3.2 to 11.0 percent, liquid limits of 27 to 30, plasticity indexes of 9 to 16 and had 50 to 68 percent passing a No.200 sieve (silt and clay sized particles). Three sandy and gravelly clay samples tested had moisture contents of 10.8 to 13.0 percent, dry densities of 94 to 115 pcf and exhibited 0.2 to 6.8 percent one-dimensional consolidation when wetted under a confining pressure of 250, 500 and 1,000 psf. One sandy and gravelly clay sample tested had a moisture content of 9.8 percent, a dry density of 105 pcf and exhibited an internal angle of friction of 23 degrees and a cohesion of 300 when tested for direct shear strength properties. Three sandy and gravelly clay samples tested had moisture contents of 3.2 to 11.0 percent and had a water soluble sulfate concentrations of 1 ,300 to 5,000 ppm. One blended bulk from exploratory test borings TH-2 and TH-3 at a depth of 0 to 5 feet had a liquid limit of 27, a plasticity index of 9, a maximum standard Proctor dry density of 114.5 pcf, an optimum moisture content of 13.0, had 68 percent passing a No.200 sieve, and had a California Bearing Ratio (CBR) of 3.2. Results of laboratory testing are presented on Figs. 8 through 17 and summarized on Tables I and II. SITE DEVELOPMENT The surface in areas to receive additional fill, if any, or support structures should be scarified to a depth of 10 inches, moisture conditioned to within 2 percent of optimum UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 5 moisture content and compacted to at least 95 percent of standard Proctor (ASTM 0 698) maximum dry density. On-site soils free of deleterious materials, organics and particles over 6-inches diameter can be reused in non-structural areas for general site grading. Fill in structural areas may include special requirements as discussed later under the "FOUNDATIONS" section of this report. Additional fill placement should be moisture conditioned to within 2 percent of optimum moisture content and compacted to at least 95 percent of standard Proctor (ASTM 0698) maximum dry density in 10-inch maximum thickness loose lifts. Subgrade soils and fill greater than 10 foot in depth should be moisture conditioned to within 2 percent of optimum moisture and compacted to at least 100 percent maximum dry density standard Proctor (ASTM 0698). Subgrade preparation, and placement and compaction of grading fill should be observed and tested by a representative of our firm during construction. Sample site grading specifications are included in Appendix A. Excavation Soils used to construct additional general site fill slopes, if any, will be obtained from the excavation cut slopes above the pad location. The subject site should be stripped of all vegetation and organic material prior to additional fill slope construction. We recommend that all material disturbed by excavation be removed from excavation areas to expose undisturbed material. The inclination of the cut slopes based on stability analysis will depend on the height of the slope and the soil strength characteristics. Our UNA Compressor Station Wllli~ms Production RMT Company Garfield County, Colorado R~port Dated November 5, 2008 GEG Job No. 3,071 6 analysis of the existing excavation cut slope was based on "Effect of Soil Strength Parameters on Stability of Man-Made Slopes" by Awtar Singh. The soil strength characteristics used in our stability analysis were obtained from direct shear strength test data from our laboratory and site soil samples. We used an internal angle of friction of 23 degrees, a cohesion of 300 psf, a moist soil density of 115 pcf and maximum cut slope height of 35 feet in our analysis. We consider a calculated factor of safety against movement of 1.5 or greater is adequate for permanent slopes and a calculated factor of safety of 1.2 is adequate for temporary slopes. We calculated a minimum factor of safety against slope failure of 1.2 for the existing/proposed cut slope of 1.0 H to 1.0 V with a maximum height of 35 feet. In our opinion, temporary excavations cut slopes should therefore be constructed for at least 1.0 horizontal to 1.0 vertical or flatter if possible. Cut slopes should be adequately treated to mitigate erosion and other potential stability concerns. Our observations and calculations indicate slopes constructed at an inclination of 1.0 horizontal to 1 vertical will require periodic maintenance due to surface erosion. We calculated a factor of safety against slope failure of 1.5 for an inclination of 2 horizontal to 1 vertical or flatter for permanent reclamation excavation cut slopes. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 7 Embankment Fill materials, if any, should contain no particles larger than about one half of the lift thickness with the largest scattered pieces no greater than six inches. All areas to receive additional fill should be stripped of all vegetation, organic soils, and other deleterious material prior to fill placement. Our recommendation for general fill materials, preparation and placement are included in APPENDIX A. Man made fill construction in soils such as those encountered in the area is problematic. Clays can require significant hydration periods. Silts are highly moisture sensitive and shale fragments require breakdown. These factors present more challenge than the moisture content, lift thickness and compactive effort factors involved with other embankment projects. The additional factors involved at the subject site result in less confidence in operator experience or 'dead reckoning' contractor methods and the need for more reliance on engineering controls such as laboratory Proctor and field moisture I density gauge measurements. Compaction equipment including large self propelled sheepsfoot compactor, steel drum vibratory compactor, disc and I or pneumatic breakdown (tractor attached or equivalent), blade and water truck have also been part of successful embankment construction such as that planned on the subject site. UNA Compressor Station WUIIams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 8 Areas to receive fill should be constructed with a toe key and benched into competent foundation material. The key and bench concept is shown on Fig. 18. We should observe the key and bench preparation to verify that the key and bench extends into competent material and meets our recommendations. Prior to placement of structural fill, the resulting subgrade should be scarified 1 0-inches, moisture conditioned and compacted as discussed in APPENDIX A. A drain should be constructed at the back of the toe key and each bench in all permanent fill slopes to drain subsurface water that may accumulate at the fill I natural soil contact. The toe key and bench drains should consist of a 4 or 6 inch diameter perforated drain pipe surrounded by at least 3 cubic feet per linear foot of drain, free draining aggregate all wrapped with an appropriate filter fabric. Toe key and bench drain details are shown on Fig. 19. The inclination of the fill slopes based on stability analysis will depend on the height of the slope and the soil strength characteristics. Our analysis of the embankment fill slope was based on "Effect of Soil Strength Parameters on Stability of Man-Made Slopes", by Awtar Singh. The soil strength characteristics used in our stability analysis were obtained from direct shear strength tests from our laboratory of soil samples from the subject site. We used an internal angle of friction of 23 degrees, a cohesion of 300 psf, a moist soil density of 115 pcf and a maximum fill height of 50 feet in our analysis. Our analysis indicates a temporary fill slope constructed with a slope inclination of 1 Yz horizontal to 1.0 vertical has a calculated factor of safety against UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 9 slope failure of about 1.3. Our analysis indicates a permanent reclamation fill slope constructed with a slope inclination of 2.0 horizontal to 1.0 vertical or flatter has a calculated factor of safety of 1.5. FOUNDATIONS This investigation indicates subsurface conditions at foundation levels generally consist of medium stiff to very stiff sandy, silty clay with volume change potential. The recommendations presented in this report are intended to reduce or mask the influence of swelling or settling soils but will not completely mitigate the influence of swelling or settling soils. In our opinion, a foundation to better mitigate risk of movement should be anchored below the zone of probable moisture variation and concentrate the weight of the structure to resist potential swell of the clay soils. In our opinion, a straight shaft drilled pier, driven pile or screw pile foundation bedded in an underlying competent stratum most nearly satisfies these criteria. Drilled piers, driven piles or screw piles will not likely reach a formational material bearing stratum due to the varying cobble and boulder content of the site subsurface soils. Drilled piers, driven piles or screw piles may be designed as friction piles in the natural undisturbed soils. UNA Compressor Station Wllllams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 10 We present design and construction criteria for drilled piers, driven piles, screw piles, spread footings and reinforced mat foundations in order of decreasing attractiveness. These criteria were developed from analysis of field and laboratory data and our experience. The additional requirements (if any) of the structural engineer should also be considered. Based on the soils encountered in the exploratory test borings and observations of the existing site conditions, the proposed compressor station structures will be located entirely on cut areas and will not be supported by existing fill. If existing fill is encountered during foundation construction, the existing fill should be completely removed and replaced with well compacted structural fill as discussed below. Driven Friction Piles 1. Pile material should be concrete filled, closed end, steel pipes (10-3/4-inch O.D., 0.25-inch thick walled or heavier). Pipe piles are typically used in this area. Tip reinforcement should be provided to reduce pile damage during hard driving. A maximum allowable service stress of 12,000 psi should not be exceeded. Based on our experience, capacities of 10 tons to 55 tons can be developed during driving. The piles should be driven to a minimum depth of 40 feet and designed using a skin friction value of 400 psf for the portion of pier in native sandy and gravelly clay soils. Skin friction should be neglected for the portion of pier within 5 feet of the ground surface. After installation the pile should be allowed to rest for a minimum of 24 hours then the pile driving hammer reinstalled on the pile and the pile re-struck to verify the skin friction has developed. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 11 2. We did not identify a competent bearing strata to a depth of 28)12 feet, the maximum depth explored. The subsurface soils contained varying amounts of cobbles and boulders which may provide varying resistance during pile installation. We anticipate variable and increased depths to competent bearing stratum across the site. Piles should have a minimum length of 40 feet below the finished site grade. 3. Groups of piles placed closer than three diameters, center to center, should be evaluated to determine their reduced capacity. 4. The pile-driving hammer should be operated at the manufacturer's recommended stroke and speed when the "set" is measured. 5. The contractor should select a driving hammer and cushion combination which is capable of installing selected piles without overstressing the pile. The contractor should submit the pile driving plan and the pile hammer cushion combination to the structural engineer for evaluation of the driving stress in advance of the pile installation. 6. We believe a modulus of subgrade reaction of 220 psi/in can be used for lateral resistance of pile caps. A plate load test can be performed to provide a more direct correlation between site soils and modulus of subgrade reaction. 7. There should be at least a 4-inch or thicker continuous void beneath all grade beams and foundation walls, between piles, to concentrate dead load on the piles and provide separation between the bottom of grade beams and site soils. 8. If the pile foundations are designed and constructed as discussed above, we estimate that the post construction total settlement will be about Y, to % inch with about Y, of the total settlement occurring as differential settlement. The estimated settlement is dependent on pile design loads, soil conditions supporting the piles and pile depth. If the pile design loads, soil conditions or the pile depths are different than discussed above, we should be contacted to provide additional settlement considerations. 9. Exterior walls must be protected from frost action. Refer to the local building code for details. We understand the Garfield County Building Department recommends coverage of at least 36 inches at an elevation up to 6,000 UNA Compressor Station Wllllams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 12 feet, at least 42 inches for elevations of 6,000 to 8,000 feet and at least 48 inches for elevations above 8,000 feet for frost protection. 10. A representative of our office should observe and keep records of penetration resistance, pile lengths and other factors that could affect the performance of the foundation, during driving. 11. We recommend performing a load test of select piles to verify the design load has been obtained during installation. Drilled Pier and Screw Pile Foundations 1. Piers and I or screw piles should be designed for a maximum allowable end bearing pressure of 4,000 psf and an allowable skin friction value of 400 psf for the portion of pier in native sandy and gravelly clay soils. Skin friction should be neglected for the portion of pier within 5 feet of the ground surface. 2. Piers should be designed for a minimum deadload pressure of 500 psf based on pier cross-sectional area. If this deadload cannot be achieved, pier length should be increased. The native sandy and gravelly clay can be assigned a skin friction value of 300 psf for uplift resistance, at least 5 feet below the pier cap. 3. Piers should penetrate at least 40 feet into the native sandy clay soils and have a total length of at least 40 feet. 4. Piers should be reinforced the full length of the pier with at least two No. 4 Grade 60 reinforcing bars to resist tension in the event of soil movement. Reinforcement should extend into grade beams and foundation walls. 5. Foundation walls and grade beams should be well reinforced; the reinforcement should be designed by a qualified structural engineer. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 13 6. If the pier or screw pile foundations are designed and constructed as discussed above, we estimate that the post construction total settlement will be about Y:z to % inch with about Y:z of the total settlement occurring as differential settlement. The estimated settlement is dependent on pier oor screw pile design loads, soil conditions supporting the piers or screw piles and pier or screw pile depth. If the pier or screw pile design loads, soil conditions or the pier or screw pile depths are different than discussed above, we should be contacted to provide additional settlement considerations. 7. There should be at least a 4-inch or thicker continuous void beneath all grade beams and foundation walls, between piers, to concentrate dead load on the piers and provide separation between the bottom of grade beams and site soils. 8. Piers should be carefully cleaned prior to placement of concrete. Groundwater was not encountered at the time of this investigation to the depths investigated. 9. We believe problems associated with pier installation can be significantly reduced by using a "drill and pour" construction procedure; that is, placing concrete immediately after pier holes are drilled, cleaned and inspected. Pumping, tremie placement, vacuum truck or auger cast methods may be required for proper dewatering of the pier holes if water is encountered during drilling. Concrete should not be placed in any pier hole containing more than 3 inches water. Due to recent experience with improper installation, we recommend the use of a contractor with previous drilled pier installation experience. 10. Installation of drilled piers should be observed by a representative of our firm to identify the proper bearing strata and confirm proper installation technique. Our representative should be called to visit the site at the time of the first pier excavation and all subsequent pier excavations. 11. Exterior walls must be protected from frost action. Refer to the local building code for details. We understand the Garfield County Building Department recommends coverage of at least 36 inches at an elevation up to 6,000 feet, at least 42 inches for elevations of 6,000 to 8,000 feet and at least 48 inches for elevations above 8,000 feet for frost protection. UNA Compressor Station WUIIa_ms Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 14 12. Formation of mushrooms or enlargements at the top of piers should be avoided during pier drilling and subsequent construction operations. It may be necessary to case the top portion of the pier hole prior to pier concrete placement to prevent flaring of the top of the pier. 13. Installation of drilled piers should be observed by a representative of our firm to identify the proper bearing strata and confirm proper installation technique. Our representative should be called to visit the site at the time of the first pier excavation. 14. We recommend performing a load test of select piers and I or screw piles to verify the design load has been obtained during installation. Spread Footings-Structures where more risk of movement is acceptable 1. Footing foundations bearing on at least 4-feet depth of well compacted, structural fill can be designed for maximum soil bearing pressure of 2,500 psf. The soil bearing pressure may be increased by 30 percent for temporary loading such as wind and seismic loads. Loose soils, existing fill, existing foundations, if any, and organic materials should be removed full depth and replaced with a well compacted structural fill. 2. The foundation areas should be over excavated 4-feet. The resulting subgrade should be scarified 10 inches, moisture conditioned and re- compacted to 95 percent of standard Proctor (ASTM 0698) to help mitigate potential soil settlement and provide a uniform subgrade. The foundation should bear completely on at least 4-feet uniform depth of well- compacted structural fill to at least 4-feet beyond each footing, horizontally. Loose soils should be completely removed from foundation bearing areas, prior to placing fill or concrete. The structural fill should be a crushed, uniformly graded, granular material with a maximum size of 1.5 inches, maximum of 15 percent passing the No. 200 sieve and maximum liquid limit of 30. A COOT Class 5 or Class 6 type crushed base course could be used to satisfy these criteria and is recommended. The structural fill should be placed in maximum 1 0-inch loose lifts, moisture conditioned to within 2 percent of optimum moisture content and compacted to at least 95 percent maximum standard Proctor (ASTM D UNA Compressor Station Williams ProducUon RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 15 698) dry density. If structural fill soils are required to achieve grade they should consist of a granular material and should be placed and compacted as stated above. 3. We recommend a minimum width of 18 inches for continuous footings. Isolated pads should be at least 30 inches by 30 inches. Foundation walls should be well-reinforced top and bottom. We recommend reinforcement sufficient to span an unsupported distance of at least 12 feet. A qualified structural engineer should design foundation reinforcement. 4. If the footings are designed and constructed as discussed above, we estimate that the post construction total settlement will be about 1 to 1 Y. inch with about Y, of the total settlement occurring as differential settlement. The estimated settlement is dependent on foundation bearing pressure, soil conditions supporting the footings and footing width. If the foundation bearing pressures, soil conditions or the footing widths are different than discussed above, we should be contacted to provide additional settlement considerations. 5. Exterior walls must be protected from frost action. Refer to the local building code for details. We understand the Garfield County Building Department recommends coverage of at least 36 inches at an elevation up to 6,000 feet, at least 42 inches for elevations of 6,000 to 8,000 feet and at least 48 inches for elevations above 8,000 feet for frost protection. 6. The completed foundation excavation should be observed by our representative, to test subgrade and fill compaction and to verify subsurface conditions are as anticipated. Reinforced Mat Foundations 1. Reinforced mat foundations bearing on at least 4-feet depth of well compacted, structural fill can be designed for maximum soil bearing pressure of 2,500 psf. The soil bearing pressure may be increased by 30 percent for temporary loading such and wind and seismic loads. Loose UNA Compressor Station Wllll~ms Production RMT Company G;ufleld County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 16 soils, existing fill, existing foundations and organic materials need to be removed full depth and replaced with a well compacted structural fill. 2. The foundation areas should be over excavated 4-feet. The resulting subgrade should be scarified 10 inches, moisture conditioned and re- compacted to 95 percent of standard Proctor (ASTM 0698) to help mitigate potential soil settlement and provide a more uniform subgrade. The foundation should bear completely on at least 4-feet uniform depth of well-compacted structural fill to at least 4-feet beyond each footing, horizontally. Loose soils should be completely removed from foundation bearing areas, prior to placing fill or concrete. The structural fill should be a crushed, uniformly graded, granular material with a maximum size of 1.5 inches, maximum of 15 percent passing the No. 200 sieve and maximum liquid limit of 30. A COOT Class 5 or Class 6 type crushed base course could be used to satisfy these criteria and is recommended. The structural fill should be placed in maximum 1 0-inch loose lifts, moisture conditioned to within 2 percent of optimum moisture content and compacted to at least 95 percent maximum standard Proctor dry density (ASTM D 698). If structural fill soils are required to achieve grade they should consist of a granular material and should be placed and compacted as stated above. 3. We performed a California Bearing Ratio (CBR) test in general accordance with ASTM 01883. The CBR test results are presented on Fig. 17. The CBR test results indicate a CBR of 3.2 when compacted to about 95 percent of the maximum dry density as defined by ASTM 0698, standard Proctor test. Based on the CBR test results we calculated a modulus of subgrade reaction (K) of 220 psi/in. 4. Mat foundations should be well reinforced, both top and bottom. We recommend reinforcement sufficient to span an unsupported distance of at least 12 feet and to distribute loads over entire mat. Reinforcement should be designed by the structural engineer. 5. If mat foundations are designed and constructed as discussed above, we estimate that the post construction total settlement will be about 1% to 2 inch with about % of the total settlement occurring as differential settlement. The estimated settlement is dependent on foundation bearing pressure, soil conditions supporting the mat foundation and rnat foundation width. If the foundation bearing pressures, soil conditions or UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 17 the mat foundation widths are different than discussed above, we should be contacted to provide additional settlement considerations. 6. Foundations should be protected from freezing. Refer to local building code for details. We understand the Garfield County Building Department recommends coverage of at least 36 inches at an elevation up to 6,000 feet, at least 42 inches for elevations of 6,000 to 8,000 feet and at least 48 inches for elevations above 8,000 feet for frost protection. 7. The completed foundation excavation should be observed by our representative to verify subsurface foundation conditions are as anticipated from our borings and to test compaction. Tank Spread Footing Ring Foundations and Tank Bottom Support 1. Footing foundations bearing on a 2 feet depth layer of well compacted structural fill can be design for a maximum soil bearing pressure of 2,500psf. Loose soils should be completely removed from foundation bearing areas, prior to placing concrete. We understand the tank bottoms will be supported on grade. The tank bottom can be designed for a maximum soil bearing pressure of 2,500 psf. Loose soils should be completely removed from foundation bearing areas, prior to well compacted structural fill or tank foundations. 2. The completed ring spread footing foundation excavation should be over excavated 1 feet depth below tank bottom bearing level and 2 feet depth below the ring footing bearing elevation. The tank bottom should be supported completely on a layer of well compacted structural fill at least 1 foot thick and the ring foundation should be supported on a layer of well compacted structural fill at least 2 feet thick. The well compacted structural fill should extend horizontally beyond each edge of the ring footing at least 2 feet. The resulting subgrade should be scarified 1 0-inches, moisture conditioned to within 2 percent of optimum moisture content and compacted to at least 95 percent of standard Proctor (ASTM 0698) maximum dry density. Our representative should be called to test subgrade compaction, UNA Compressor Station Wllll"'ms Production RMT Company Garlleld County, Colorado R@port Dated November 5, 2008 GEG Job No. 3,071 18 prior to structural fill placement. A granular imported structural fill should consist of a maximum particle size of 1.5-inches, maximum of 30 percent passing the No. 200 sieve and a maximum liquid limit of 30. We recommend structural fill be placed in a maximum 1 0-inch thickness loose lifts and compacted to at least 95 percent of maximum dry density and within 2 percent of optimum moisture content (ASTM D698). Structural fill should be tested every 1 foot depth of placement. If soft conditions are encountered in the open excavation then stabilization may be necessary. Our representative should be called to test compaction of subgrade and/or observe stabilization, prior to forming. 3. We recommend a minimum width of 1.5 feet for continuous footings. Foundation walls should be well-reinforced top and bottom. We recommend reinforcement sufficient to span an unsupported distance of at least 12 feet. The structural engineer should design reinforcement. 4. Based on a design soil bearing pressure of 2,500 psf, a footing width of about 1.5 feet and footings placed on a 2 feet thick layer of well compacted structural fill the estimated total settlement is about 6 inches at the edge of the tank and about 4 inches at the center of the tank. The tank bottom should be designeo with sufficient camber to accommodate the estimated differential settlement between the center and the edge of the tank. Utility lines that will be connected to the tank should be designed with flexible connections to accommodate the total settlement. If the support conditions are modified or the tank support is changed we should be contacted to provide additional settlement analysis and recommendations. The tank and contents will act as a uniformly applied load over the area of the tank and will significantly influence the supporting soil to the depth of about 30. Due to the influence of the tank and contents loads acting as a uniformly applied load on the entire tank bottom area, the settlement of the spread footing type ring foundation will be directly associated with the estimated settlement of the tank bottom as discussed below. The ring footing will likely be nearly uniform to itself 5. Exterior walls should be protected from freezing. We understand the Garfield County Building Department recommends coverage of at least 36 inches at an elevation up to 8,000 feet and at least 42 inches for elevations above 8,000 feet for frost protection. Frost protection concepts are shown in Appendix A. In our experience, a 1.5 inch imported aggregate is not particularly frost sensitive and the proposed construction does not lend UNA Compressor Station Williams Production RMT Company Garfteld County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 19 itself well to frost protection. While more risk is involved, frost protection via minimum depth of imported aggregate fill and/or an equivalent styro board type insulation product may be substituted for strict burial. 6. The completed foundation excavation should be observed by our representative prior to placing forms, to verify the foundation bearing conditions, test compaction. 7. Exterior walls should be protected from freezing. We understand the Garfield County Building Department recommends coverage of at least 36 inches at an elevation up to 8,000 feet and at least 42 inches for elevations above 8,000 feet for frost protection. In our experience, a 1.5 inch imported aggregate is not particularly frost sensitive and the proposed construction does not lend itself well to frost protection. While more risk is involved, frost protection via minimum depth of imported aggregate fill and/or an equivalent styro board type insulation product may be substituted for strict burial. 8. The completed foundation excavation should be observed by our representative to verify subsurface foundation conditions are as anticipated from our borings and to test compaction. SEISMIC AND VIBRATING FOUNDATION DESIGN CONSIDERATIONS Foundation and floor systems include structural support from the surficial clay with shale fragment soils. Based on 2000 UBC we believe the site is located in Seismic Zone 1. Based on our understanding of proposed construction and subsurface conditions, we suggest a "Site Class D" be used for foundation seismic design as described in 2006 IBC. Based on the field and laboratory results we calculate a shear modulus of 3,000 psi. We have estimated a modulus of subgrade reaction based on field and laboratory test data. We recommend a modulus of subgrade reaction of 220 UNA Compressor Station Wlllia:ms Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 20 psi/inch. FLOOR SYSTEMS The near -surface soils that will support slab-on-grade floors exhibited movement potential. Some movement must be assumed. To our knowledge, the only reliable solution to control floor movement is the construction of floors supported by the foundation system over a minimum 12 inch void. If the owner and builder accept the risk of movement and associated damage, the floors may be constructed as slab on grade floors. We recommend the following precautions for construction of slabs-on-grade at this site. These precautions will not prevent movement in the event the underlying conditions become wetted; they tend to reduce damage if movement occurs. 1. Slabs should be supported by at least a 1 foot depth of well compacted, structural fill. The completed subgrade should be scarified 1 0-inches depth, moisture conditioned to within 2 percent of optimum moisture content and compacted to at least 95 percent of maximum standard Proctor (ASTM 0698) dry density, prior to structural fill placement. The compacted structural fill should consist of a non expansive granular material with a maximum size of 1.5 inches, a maximum of 15 percent passing the number 200 sieve, a maximum liquid limit of 35 and a maximum plasticity index of 10. The structural fill should be moisture conditioned to within 2 per cent of optimum moisture content placed in thin lifts and compacted to at least 95 percent of the maximum standard Proctor (ASTM 0698) dry density. A Geotechnical Engineering Group, Inc. representative should be called to visit the site to test compaction and observe soils in the excavation bottom UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No, 3,071 21 and structural fill. 2. We performed a California Bearing Ratio (CBR) test in general accordance with ASTM 01883. The CBR test results are presented on Fig. 17. The CBR test results indicate a CBR of 3.2 when compacted to about 95 percent of the maximum dry density as defined by ASTM 0698, standard Proctor test. Based on the CBR test results we calculated a modulus of subgrade reaction (K) of 220 psi/in. 3. Slab-on-grade construction should be limited to unfinished areas and exterior flatwork where practical. 4. Slabs should be separated from exterior walls and interior bearing members with a slip joint which allows for free vertical movement of slabs. 5. The use of slab-bearing partitions should be minimized. Where such partitions are necessary, a slip joint allowing at least 4 inches of free vertical slab movement should be used. Doorways and stairwells should also be designed for this movement. 6. Underslab plumbing should be eliminated where feasible. Where such plumbing is unavoidable, it should be thoroughly pressure tested during construction for leaks and should be provided with flexible couplings. Plumbing extending through slab on grade floors should be separated from floor slab to allow independent movement. 7. Frequent control joints should be provided to reduce problems associated with shrinkage and curling. The American Concrete Institute (ACI) and Portland Cement Association (PCA) recommend a maximum panel size of 8 to 15 feet depending upon concrete thickness and slump, and the maximum aggregate size. We advocate additional control joints 3 feet off and parallel to grade beams and foundation walls. UNA Compressor Station W!lll~ms Production RMT Company Garfield County, Colorado RepQrt Dated November 5, 2008 GEG Job No. 3,071 22 BELOW-GRADE CONSTRUCTION No below-grade construction is anticipated at this site. Typically, building foundation drains are not required for construction of this type. Crawl space, if any, in building areas should be sloped so that potential moisture will not collect in these areas, but flow out of the crawl space. Crawl space areas should also be well ventilated to reduce potential humidity and musty odors. SOIL RESISTIVITY CONSIDERATIONS Our field study included performing field soil resistivity tests at one location Line on the proposed compressor location. The approximate location of the field soil resistivity test was between exploratory test borings TH1 and TH-2 and between exploratory test borings TH-3 and TH-4 . The field soil resistivity tests were conducted in general conformance with ASTM test method G-57. The field soil resistivity tests indicate a resistivity of about 490 and 1460 Ohm-em. PAVEMENT The pavement subgrade soils include medium stiff to stiff, sandy and gravelly clay. We tested a combined bulk sample (TH-1, TH-2 and TH-3 at a depth of 0 to 5 feet) for UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 23 pavement design purposes. The sample was tested for standard Proctor, and California Bearing Ratio (CBR). The sample tested exhibited a maximum dry density of 114.5 pcf, an optimum moisture of 13.0 percent and a California Bearing Ratio (CBR) of 3.2. We used a California Bearing Ratio of 3.2 in our analysis. The results of the laboratory testing are shown on Table II and included on Figs. 16 and 17. Our design utilized the computer program WinPAS, based on the 1993 AASHTO Guide for Design of Pavements Structures a 20 year design period and our experience. We understand pavements will be used for general drive lanes. We used an Equivalent Single Axle Load (ESAL) of 62,400, 156,000 and 187,200. The ESAL values were calculated using an EDLA of 10, 25 and 30 over a 20 year period. We used a regional factor of 2.0 and a design serviceability index of 2.0. We used an AASHTO developed, non-linear relationship to relate the CBR value to the subgrade resilient modulus (M,), for flexible pavement. Using this relationship, we calculated a M, value of 4,300 psi. We used this M, value for flexible pavement design. Using the calculated M, value we calculated a modulus of subgrade reaction, K value of 220 psi/in for rigid pavement design. The WinPAS analysis results are presented in Appendix B. Table A below shows our recommendations. UNA Compressor Station Willla_ms Production RMT Company Garfi~ld County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 24 TABLE A SUMMARY OF RECOMMENDED PAVEMENT SECTIONS Traffic Type Asphaltic Asphalt and Asphalt, Aggregate Base Portland Cement Concrete Concrete Aggregate Base Course and Aggregate Course Sub Base Course ESAL = 62,400 6%" 3"+11 " 3"+ 5" + 8" 6" ESAL = 156,200 TY.t 4 "+ 11" 4"+ 5" +8" 6" ESAL = 187,200 7%" 4" + 12" 4"+6"+8" 6" 5"+5"+9" Existing fill was not identified in the exploratory borings, however we anticipate that existing fill may exist on site associated with previous development. Existing fill, if any, should not be relied upon for structural support and should be removed full depth and be replaced as a well compacted structural fill as described in the "SITE DEVELOPMENT" section of this report. Geotechnical Engineering Group, Inc. representative should be called to confirm adequate stabilization prior to placement of fabric. Prior to construction of the recommended section, the resulting subgrade should be stripped free of organics and deleterious materials, scarified at least 1 0-inches depth, UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 25 moisture conditioned to within 2 percent of optimum moisture and compacted to at least 95 percent standard Proctor (ASTM 0698) maximum dry density. Portions of the pavement subgrade areas may encounter soft yielding soils. If yielding soils are encountered it may be necessary to provide subgrade stabilization. Subgrade stabilization may include over excavation about 1 to several feet, placement of a geotechnical stabilization fabric and placement of compacted structural fill. We should be contacted to observe subgrade conditions and provide additional recommendations as needed. The design of a pavement system is as much a function of paving materials as supporting characteristics of the subgrade. The quality of each construction material is reflected by the strength coefficient used in the calculations. If the pavement system is constructed of inferior material, then the life and serviceability of the pavement will be substantially reduced. Prior to construction of the recommended section, the resulting subgrade should be stripped free of organics and deleterious materials, scarified 1 0- inches depth, moisture conditioned to within 2 percent of optimum moisture content and compacted to at least 95 percent standard Proctor (ASTM 0698) maximum dry density. The asphalt component of the pavement was designed assuming at least 1,650 pounds Marshall Stability. Normally, an asphaltic concrete should be relatively impermeable to moisture and should be designed with a well-graded sand/gravel mix. UNA Compressor Station Wlllia:ms Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 26 The oil content, void ratio, flow and gradation need to be considered in the design. We recommend a job mix design be performed and periodic checks are made to verify compliance with these specifications. We can perform these services, as requested. If construction materials cannot meet the above requirements, then the pavement design should be evaluated based upon available materials. We recommend the materials and placement methods conform to the requirements listed in the Colorado Department of Transportation "Standard Specifications for Road and Bridge Construction". All materials planned for construction should be submitted and tested to confirm their compliance with these specifications. A primary cause of early pavement deterioration is water infiltration into the pavement system. The addition of moisture usually results in softening of untreated base course and subgrade and eventual failure of the pavement. We recommend drainage be designed for rapid removal of surface runoff. Curb and gutter should be backfilled and the backfill compacted to reduce ponding adjacent to pavements. Final grading of the subgrade should be carefully controlled so that design cross-slope is maintained and low spots in the subgrade which could trap water are eliminated. Seals should be provided between curb and pavement and at all joints to reduce moisture infiltration. Landscaped areas and detention ponds in pavements should be avoided. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 27 We have included construction recommendations for flexible and rigid pavement construction in Appendix C. Routine maintenance, such as sealing and repair of cracks annually and overlays at 5 to 7 -year intervals, are necessary to achieve the long-term life of an asphalt pavement system. If the design and construction recommendations cannot be followed or anticipated traffic loads change considerably, we should be contacted to review our recommendations. CONCRETE Three samples (TH-1, TH-2 and TH-3 at a depth of 0 to 5 feet) were tested for water soluble sulfate concentrations. The test results indicate a water soluble sulfate concentration of 1,300 to 5,000 ppm. Sulfate concentrations in this amount are considered to have a severe effect on concrete that comes into contact with the soils. We recommend following the American Concrete Institute (ACI) guidelines for sulfate resistant cement. ACI recommends a Type V (sulfate resistant) cement be used for concrete that comes into contact with the subsoils. In addition, the concrete should have a water cement ratio of 0.45. We understand that Type V cement may not be locally available. Although, not meeting ACI recommendations for sulfate resistant cement, Type II modified cement has been used in similar conditions. UNA Compressor Station WUIII:~ms Production RMT Company Garlleld County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 28 SURFACE DRAINAGE Performance of foundations and concrete flatwork is influenced by surface moisture conditions. The site sandy clay soils have significant consolidation potential. The consolidation and I or swell potential typically is mobilized by wetting and or loading. Reducing the potential for moisture migration into the site soil and formational sandstone with reduce the risk of mobilization of consolidation or swell potential of site materials. Risk of wetting foundation soils can be reduced by carefully planned and maintained surface drainage. Surface drainage should be designed to provide rapid runoff of surface water away from the proposed structures. We recommend the following precautions be observed during construction and maintained at all time after the construction is completed. 1. The ground surface surrounding the exterior of the structures should be sloped to drain away from the foundations in all directions. We recommend a slope of at least 12 inches in the first 10 feet around the structures, where possible. In no case should the slope be less than 6 inches in the first 5 feet. The ground surface should be sloped so that water will not pond adjacent to the foundations. 2. Backfill around foundation walls should be moistened and compacted. Foundation backfill should be moisture conditioned to within 2 percent of optimum moisture centered and compacted to at least 90 percent of the maximum standard Proctor (ASTM 0698) dry density. Foundation backfill supporting concrete flatwork or other structural components should be moisture conditioned and compacted to at least 95 percent of the maximum standard Proctor dry density. UNA Compressor Station Williams Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 29 3. Roof downspouts and drains should discharge well beyond the limits of all backfill. Splash blocks and downspout extenders should be provided at all discharge points. 4. Landscaping, if any, should be carefully designed to minimize irrigation. Plants used close to foundations should be limited to those with low moisture requirements; irrigated grass should not be located within 5 feet of the foundation. Sprinklers should not discharge within 5 feet of foundations. Irrigation should be limited to the minimum amount sufficient to maintain vegetation; application of more water will increase likelihood of slab and foundation movements. 5. Impervious plastic membranes should not be used to cover the ground surface immediately surrounding the structures. These membranes tend to trap moisture and prevent normal evaporation from occurring. Geotextile fabrics can be used to limit the weed growth and allow for evaporation. CONSTRUCTION MONITORING Geotechnical Engineering Group, Inc. should be retained to provide general review of construction plans for compliance with our recommendations. Geotechnical Engineering Group, Inc. should be retained to provide construction-monitoring services during all earthwork and foundation construction phases of the work. This is to observe the construction with respect to the geotechnical recommendations, to enable design changes in the event that subsurface conditions differ from those anticipated prior to start of construction and to give the owner a greater degree of confidence that the additions are constructed in accordance with the geotechnical recommendations. UNA Compressor Station Wlllllil!ms Production RMT Company Garfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 30 LIMITATIONS Four exploratory borings were drilled in the proposed structure areas at locations requested by Sun Valley Engineering. The exploratory borings are representative of conditions encountered only at the exact boring locations. Variations in the subsoil conditions not indicated by the borings are always possible. Our representative should be called to monitor deep foundation installation and provide actual pile capacities based on actual installation conditions. Our representative should observe open foundation excavations, observe proof roll and test compaction of subgrade and structural fill soils (as applicable) to confirm soils are as anticipated from the borings and foundations are prepared as recommended herein. The scope of work performed is specific to the proposed construction and the client identified by this report. Any other use of the data, recommendations and design parameters (as applicable) provided within this report are not appropriate applications. Other proposed construction and I or reliance by other clients will require project specific review by this firm. Changes in site conditions can occur with time. Changes in standard of practice also occur with time. This report should not be relied upon after a period of three years from the date of this report and is subject to review by this firm in light of new information which may periodically become known. UNA Compressor Station Williams Production RMT Company Gatfield County, Colorado Report Dated November 5, 2008 GEG Job No. 3,071 31 We believe this investigation was conducted in a manner consistent with that level of care and skill ordinarily used by geotechnical engineers practicing in this area at this time. No other warranty, express or implied, is made. If we can be of further service in discussing the contents of this report or the analysis of the influence of the subsurface conditions on the development or design of the proposed construction, please call. Sincerely, GEOTECHNICAL EN<31NI~ffi~:~~~~~~~ on:vur-. INC. NWJ:nj ( 1 copy sent) (1 copy by E-mail: sve@silverstar.com) UNA Compressor Station WUII"ms Production RMT Company Gaffjeld County, Colorado R~pQrt Dated November 5, 2008 GEG Job No. 3,071 32 II Geotechnical kt)),_Engineering ~Group, Inc. GEGJOBNO. Una Compressor Station 3.071 DATE: 10/28/2008 Fig. 1 Note: This figure was based on drawing UN-BHL-1 OO.dwg provided by Williams Production RMT Company, dated September, 2008 and notes obtained during our field study, and is intended to show test boring locations only. Note: Longitude, latitude, and elevation are based on a handheld GPS, and are approximate. e Indicates approximate test boring locations. I Geotechnical 1-..,.E:nglneering Ia, Group, Inc. GEGJOBNO. 3,071 Bore Lonaitude Latitude H-1 108°5'5.100" 39°23'42.144" H-2 108°5'3.804" 39"23'42.504'' H-3 108°5'6.432" 39°23'42.072" i-i-i-4 1 08"5'6.00" 39"23'42.828" Una Compressor Station Test Boring Location Map Elevation N/A N/A N/A N/A DATE: 10/28/2008 Fig. 2 Symbol Description Strata Symbols Clay, sandy, slightly KEY TO SYMBOLS gravelly, with cobbles and boulders, medium stiff to stiff, moist, brown (CL) • .... .... ~ ""•~~~· Notes: Boulders, very dense, dry, tan 1. SH -Thinwall Tube Sample. 2. CT -Modified California Barrel Sample. 3. STD -Standard Split Barrel Sample. 4. Bulk -Bulk Disturbed Sample. 5. 15/12 -Indicates Standard Penetration test where 15 Blows with a 140 LB hammer falling 30 inches was required to drive the sampler 12 inches. 6. Exploratory test borings were excavated on 10/03/08 using a track mounted 4 inch diameter solid stem power auger. 7. These logs are subject to the interpretation by GEG of the soils encountered and limitations, conclusions, and recommendations in this report. Fiqure 3 I Geotec,hnic,al PROJECT: UNA Com2ressor Station Garfield Coun!): PROJECT NO.: .· 3 071 ~~ngi•ae.,rhag CLIENT: Group. ln.,. LOCATION: See Fio 2 ELEVATION: DRILLER: Odell CMR 55 LOGGED BY: MF LOG OF DEPTH TO WATER> INITIAL: ¥ NE AFTER 24 HOURS: 'If TEST BORING TH-1 DATE: 10/03/08 DEPTH TO CAVING: .C. 0 " ;..f!l %~ :c o.:g_ Description a. E,., o§ Notes ".!!! ~ c\'j>--ffi8 o-(!) 0 -Clay, !andy, slightly gravelly, with cobbles and boulders, stiff, moist, ~ browu (CL) i--~ BULK i-- i--15/12 ~ CT i--~ CT 12/12 i-- -~ -24/12 ___!Q_ '~ CT u. - -Bottom of boring when terminated: 11.5 ft. CT 50/0 -Auger Refusal. - ~ 1-- i-- 1-- i-- ~ i-- 1-- -- ~ - I-- 1--- I-- J.2Q- I-- 1--- I-- 1--- ~ 1--- I-- 1--- I-- This information nertains onlu to this borinn and should not be internreted as beinn indicitive of the site. Fiqure 4 PAGE 1 of1 I Gt-.atet:hni(:al · · PROJECT: UNA ComEressor Station Garfield Countx PROJECT NO.: 3 071 ~..:n~ineering CLIENT: {,roup. hoe. LOCATION: See Fig. 2 ELEVATION: DRILLER: Odell CME 55 LOGGED BY: MF LOG OF DEPTH TO WATER> INITIAL: Iii' NE AFTER 24 HOURS: "' TEST BORING TH-2 DATE: 10/03/08 DEPTH TO CAVING: £_ .c-u " ~J!l :c 0..~ Q.Q) Description 0. o" Notes ".J!! ~ ~~ m6 o-Cl (f) 0 0 -Clay, sandy, slightly gravelly, with cobbles and boulders, stiff, slightly v; dry, tan, slightly red (CL) -~ . BULK -~ 37112 CT - ---2_ CT 140/11 -Bottom of boring when terminated: 5.5 ft. 50/0 '-"'.!.. -Auger Refusal - - ~ - - - - ~ c-- r--- r--- r--- c-E- r--- r-- r--- r-- ~ r-- r--- r-- r--- ~ r--- r-- r--- r-- pL r-- r--- r-- r--- This information certains onlv to this borina and should not be interoreted as beina indicitive of the site. Fioure 5 PAGE 1 of 1 PROJECT NO.: __ 3""0'-'7_,_1 __ ~ ... l'11gi11eerhag CLIENT: l f~e•tte•'h llic,.al PROJECT: UNA Compressor Station Garfield County .... G roll)l• IIH'· LOCATIO_N_:~ S~ee-,~ F-"'ig-~ .. ~ 2~~~~~~~~~~~~~~~~~~~~~~~~~~~-E-LE_V_A_T-IO_N_: __ -_-_-_-_-_-_-_-_-_-_-_- LOG OF TEST BORING TH-3 DRILLER: Odell CME 55 LOGGED BY: ___ M"-'-'-F __ DEPTH TO WATER> INITIAL: "f __ __,N"'E,__ __ AFTER 24 HOURS: 'II'------- DATE: 10/02/08 DEPTH TO CAVING: .C.. Description 0 Clay, sandy, slightly gravelly, with cobbles and boulders, medium stiff, 1---slightly moist, brown (CL) k'-"~ v/. ~BULK ~"' '"' ~ CT 12112 ~ ~ ~ ~ k11-C-T-+;;,,-;;c,,,;-l ,-- c--- ,----~~ ~ _2L ~/ -~;,.- -~i.f ~--------------------------------------~27. ~ -Boulders verv dense drv, tan ~· • -Bottom of boring when tenninated: 28.5 ft. __lQ__ Auger Refusal - - - - ....1L - - - - SPT 37112 50/1 Notes This information oertains onlv to this borina and should not be interoreted as beina indicitive of the site. Fioure 6 PAGE 1 of 1 I fo«>ote•,lonieal PROJECT: UNA Com~ressor Station Garfield Coun!): PROJECT NO.: 3 071 ~~ugin<>ering CLIENT: Gro••t•• lne. LOCATION: See Fig. 2 ELEVATION: DRILLER: Odell CME 55 LOGGED BY: MF LOG OF DEPTH TO WATER> INITIAL: ¥ NE AFTER 24 HOURS: '!!' TEST BORING TH-4 DATE: 10/02/08 DEPTH TO CAVING: .C. " ID ;o!!l .c-:E c..~ 0..1i> Description Q. 0 c Notes ~~ ~ E " iii 5 rot-(!) (J) 0 0 f-- Clay, sandy, gravelly, with cobbles and boulders, stiff, slightly ~ f--moist, brown to slightly tan (CL) f--~ f--~ BULK f--~ r-2--CT 9/12 f--:% f-- f--~ f--~ CT 15/12 ~ f-- f--z. f--~ f-- ~ ~ - - -2 -19/12 _gQ_ ~ CT - -~ - - ..22_ ~ - -~ -37/9 • CT -Bottom of boring when terminated: 28.5 ft. _2!'._ Auger Refusal - - - - ~ - - - - This information certains onlv to this borina and should not be interoreted as beina indicitive of the site. Fiqure 7 PAGE 1 of1 SWELL I CONSOLIDATION TEST REPORT -1 I - 1 I WATER ADDED I 0 -o )., r--..... 1 r--, ""' 1'---1 i ' 2 ' r\ --2 3 !\ \ --3 c: \ " -~ I (J) -Cl (/) (J) -4 a c: (]) \ --4 I ~ (J) (]) "' a.. I cB 5 I \ ' --5 1\ 6 \ --6 7 I ~ --7 8 I ~ --8 I I 9 100 200 500 1000 2000 \ Applied Pressure -psf Natural Dry Dens. LL PI Sp. Overburden Pc Cc Cr Swell Press. Heave Sat. Moist. (pel) Gr. (psi) (psi) (psi) % eo 10.8% 93.7 961 -0.2 MATERIAL DESCRIPTION uses AASHTO Project No. 3,071 Client: Remarks: Project: UNA Compressor Station Garfield County Source: TH-1 Elev./Depth: 4 II Geoteehnieal ~~ngineering Group~ In~. Figure 8 SWELL I CONSOLIDATION TEST REPORT -1 I I I -0 1 I i --2 I 3 I I I ~I I I ' WATER ADDED I --4 I i'. 5 ' ' ...., "" --6 7 "' c ~ -u ·~ --8 (!) -r--.. £ en -9 ::J ~ c "' Q) " I E (!) Q) i m Q._ I --10 ~ ' 11 ' !'-.: I --12 ' 13 I I --14 I 15 I I --16 17 --18 I J ' 19 100 200 500 1000 2000 Applied Pressure -psf Natural Dry Dens, LL PI Sp, Overburden Pc Cc Cr Swell Press, Heave Sat. Moist. (pel) Gr, (psi) (psi) (psi) % eo 13.0% 115.0 522 -3.2 MATERIAL DESCRIPTION uses AASHTO Project No. 3,071 Client: Remarks: Project: UNA Compressor Station Garfield County Source: TH-3 Elev./Depth: 9 II Geotedmieal ~~ngineering Group~ lne. Figure 9 SWELL I CONSOLIDATION TEST REPORT -1 1-0 1 I I I 1--2 I I 3 I 1--4 I I 5 I I I 1--6 I I 7 WATER ADDED ....... ' c: -u -~ " 1--8 (!) I I r--.1 2 U5 (!) c 9 I :::> I I I"' ~ Q) " I I t' ,I (!) Q) 1-Ol a_ -10 (jj i 11 ' ~ 1--12 r\. 13 ' ' r--.. 1--14 ' 15 1--16 17 I I 1--18 I I I 19 00 200 500 1000 2000 5000 Applied Pressure -psf Natural Dry Dens. LL PI Sp. Overburden Pc Cc Cr Swell Press. Heave Sat. I Moist. (pcf) Gr. (psf) (psf) (psf) % eo 112.8% 98.4 1351 -6.8 MATERIAL DESCRIPTION uses AASHTO Project No. 3,071 Client: Remarks: Project: UNA Compressor Station Garfield County Source: TH-4 Elev./Depth: 19 II Geoteehniul ~~ngineering Group, ln..:. Figure 10 -0.03 -0.02 -~ c: -0.01 0 ~ Dilation E $1 " 0 0 -.; Consol. € 0.01 ~ 0.02 0.03 0 7 Strain,% 15 --; 12.5 ... -~ ·u; 10 a_ -+--vi "' ~ 7.5 a; " .<:: (f) 5 0 I 0 5 10 15 Strain,% Sample Type: Description: Assumed Specific Gravity= 2.65 Remarks: 11 14 -- 2 3 20 3 10 5 0 0 Sample No. Water Content, % Dry Density, pel -.; Saturation, % "" E Void Ratio Diameter, in. Water Content, % Dry Density, pel "" ~ Saturation, % :;;: Void Ratio Diameter, in. Normal Stress, psi Fail. Stress, psi Strain,% Ult. Stress, psi Strain,% Strain rate, in./min. Client: Results 2.06 23.3 0.43 5 10 Normal Stress, psi 1 2 9.8 9.8 104.6 104.6 44.5 44.5 0.5809 0.5809 1.94 1.94 20.9 20.9 104.6 104.6 95.3 95.3 0.5809 0.5809 1.94 1.94 10.40 6.90 6.59 4.93 4.1 6.2 0.63 0.63 Pnoie·ct: UNA Compressor Station Garfield County II S1om·ce of Sample: TH-4 Depth: 9 3 9.8 104.6 44.5 0.5809 1.94 20.9 104.6 95.3 0.5809 1.94 3.50 3.62 4.6 0.63 No.: 3,071 Date Sampled: 10/03/08 .,, . .,.,, .• ,,,.,i~nl l~ngin•·~·rin.e c;roup ......... . Tested By:""'-'-----------Checked By:"'-"''----------- 15 0:: w z u:: 1-z w ~ w (L Gradation Test Report .. S ~c.:.S ooo .S .S .!:~ .S·-·-oo o gg~ g ~if§ <.0 <") N ..--;:;:.; ~ M i :tk '"' '1:1: '1=1: 'It: ..... .,... '"' 1 oo rr-r-rT-'I --rr1i'n-T-1T-r I:Q-;Pl\-T-iii ,-rrr-ii'-r-rT-----riTI-1 IT-r'il-1 -r'i,l '-ri,li'-iT :II ,.-,.,--,nrn-r-,--;----, I 1: : ';<..,V I il 90 1-++-+--L-H-14-f+-t'-1-'-1'--=u-.~~tt+H!-1-+-+----l_ _ J I I : : 1: : : : I I : : : : :1 so~4-4-r-~~~~-4r-rhl+~~+-+---~++*-Hr~~ I I II I I I I I ''r-o. I I I I II +-t-t--1---+1+-HH-1-----· ---·-- 70 -+---t-IHI+I1+1 t+-f.-1 ++-1 +.1-+1-ITII+HHHI ++'-o,--"":rnHcllt-1 -1-+l+lr--Htl' I I I I I I I I I H-.,_.;,_~ : !lmui-+--+H-+++-H-+---- ! I I! 1111 I I I :~1 601-+~~+-4+~-+41-+~--~++~~--~-1~+++~-rr+-~~ -+-+---#t~~+-~--4 I I l1 I I I I I I I I I 11 I I I I I I I I I I I I 11 I so~~~,-~~+4r+~--rm++~t4--~-4*H++*--rr+-r<11HTirH-r+-+---+H++++-r-t--~ : I 1: : I : l1 I I I : : 11 I 40 H-+--1-1'--+HLf+++ li __ _LI'--'1-+IY++1-i'+-t--+---ftlH-Hf+-l-'1+-'1-+ ill---H-+-++H++++-t--1 I I I I I I II I I I I I I I I I I! I I I li I I I I I I I 3o~~~+-~hl4+4r+~--rm++~i-t--~-4*H++*-tr+-~H#rH-r+-+---+H++++-r-t--~ i I li 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 zoi-1-+-+-lr--l+t+l +++1-++1+1 -li-lifll t+t-lii+-1--1----Hil-1 H-t-ill +i-1 t-+1-IT-1 rhltH++-+---ttttt+tfF ! I I ~ ~ I ! I ! I I I ~ ! I I I 10 -1--1-++--+H++H-H-t~--+-iltH+-H-r-r-----ti+H++~-rr+---ttwm~+-+--+H-- I I I I I I II I I I I I !I I II I I I I I I I I I I I I I I , OLL~~-.,ttU~~~--~LU~-L-L--~UW~~L-~~W· -LL-L-~~LL~~orurr 100 10 1 0_1 0-01 0_001 %+3 .. SIEVE SIZE 1.0 11 3/4" 1/2" 3/8" #4 #8 #16 #30 #50 #100 #200 0 PERCENT FINER 100 93 91 89 81 76 72 69 66 62 57 GRAIN SIZE-mm_ %Gravel %Sand %Fines Coarse Fine Coarse I Medium I Fine Silt I 7 12 SPEC.* PERCENT PASS? (X=NO) 6 7 I II 57 Material Description Clay, slightly gravelly, dense, moist, brown (CL) Atterberg Limits IASTM D 4318) PL= 14 LL-28 PI-14 USGS= CL o85= 6.7620 D3o= Cu= Date Tested: Classification AASHTO= A-6(5) Coefficients o60 -o_ 1078 o50 = D15= D1o= Cc= 10/08/08 Tested By: SP Remarks Clay (no specification provided) Sample No.: Location: Checked Bv: LM Source of Sample: TH-1 Title: Client: Date Sampled: 10/03/08 Elev./Depth: 0-5 Project: UNA Compressor Station Garfield Cotmty Project No: 3,071 Fiaure 12 Gradation Test Report c c: .E . c 0 0 0 .E .E .E ~ c ·-0 0 0 0 0 0 " 0 ·-00 ;: "'$!.. ~(;) ;;t ;,;; II ro ;;t 11 ;jt ;t ~ "' ro N ~ " 100 : It i ~l 1: : : I I I I I I I -j~· I l_j . 90 ... -.•. I II I I I I I I I :1 I I I I I I I I j I I I I I 80 II i I \1 ..... il I I I I "a I I I I I I I II I .L .f-1 _ I I'... I I I I il I 70 I I I I I I I ~ I I . _ . ._._ ----·- I I I I I I 0: I I I ~ I I I I I I r-....., .-:. ! ~ I I w 60 z I lj IN I u::: I I: I I I I I I I I 1-I I I I I I I I I I I z 50 I l1 1: : I I I : : :1 I w u I I I I I I I I 0: 40 -I I II I I II ·---l I I il •. w I I 0. 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 I !t I 30 li il . I I I I I I I I I I I I 20 I I I I I I I I I I I I il I I II I I I I I I I I I : ll I I i I I! I I I I I I I I I I .. -1 -1-:I 10 --· ---~-1 . I I lj I I I :11 I I I I I jl I 0 I I I I I I I I I I I il I 100 10 1 0.1 0.01 0.001 GRAIN SIZE· mm. %+3" %Gravel %Sand %Fines Coarse I Fine Coarse I Medium I Fine Silt I Clay 0 0 21 6 8 I 14 51 SIEVE PERCENT SPEC.' PASS? Material Descrigtion SIZE FINER PERCENT (X=NO) Clay, slightly gravelly, dense, slightly dry, tan, slightly red 3/411 100 (CG) 112" 88 Atterberg Limits (ASTM D 4318) 3/8" 85 PL= 14 LL 27 PI-13 #4 79 Classification #8 74 #16 70 USCS= CL AASHTO= A-6(3) #30 67 Coefficients #50 62 o85= 9.0914 o60 -0.2216 D5o= #100 57 D3o= D15= D1o= #200 50 Cu= Cc= Date Tested: 10/08/08 Tested By: SP Remarks (no specification provided) Sample No.: Source of Sample: TH-2 Date Sampled: 10/03/08 Location: Elev./Depth: 0-5 Checked By: LM Title: I ...... ,.,.,..nif,al Client: ~~~·~inc,erin~ Project: UNA Compressor Station Garfield County t,;roul•· lne. Proiect No: 3 071 Fiaure 13 Gradation Test Report c -~ .~ . c 0 0 0 -~ -~ -~ ~ c --0 0 0 0 0 0 ""' 0 ·-ro ~ M N ~ ~ "' "$.M it ;;;; !il l1 l! \1: ;;;; ;;;; !il 100 I 1:1 II 1'1- I I ! I 'I I I I ! ! I I !It i i l. 90 I I I I I I ..... "Q. I I I I I I I i 1:, I I I I I I r-c. I I I I I I 80 ill I I"" ~ I I I I I I I I ~: I I ! II I I I I I I I I I I' 70 I "' I I I I II I .. T I I I 1 1! 0:: I 1 1! I ! I I I I I I I I I w 60 n; I 11 z I I I I I I I I I I I u:: I I lj I I I I II I I I I I I I f-z 50 I ill! I I I! I I w ! I ! I ! I! I I I I ! I I (_) 0:: ..L f-w 40 .. (L I l1 1 I I I I r! I :I I I I I I I ! II I I I I II I I I I I I 30 r1; I : lj I I I I I I I I I I I I llj I I I I II I I I I I I I 20 I 111 I I I I I! I I I I I I I I 1 1! I ! I ! r! I I I I I I I 10 _, ___ n; lli f- I I I I I I I I I I I 0 I ! lj I I I I Ill I I I I I I I 100 10 1 0.1 0.01 0.001 GRAIN SIZE -mm. %Gravel %Sand %Fines %+3" Coarse I Fine Coarse I Medium 1 Fine Silt I Clay 0 0 11 5 6 I 12 66 SIEVE PERCENT SPEC: PASS? Material Descri11tion SIZE FINER PERCENT (X=NO) Clay, slightly gravelly, medium dense, slightly moist, brown 3/4" 100 (CG)d 1/2tt 98 Atterberg Limits (ASTM D 4318) 3/8" 95 PL= 14 LL= 30 PI-16 #4 89 Classification #8 85 #16 82 USGS= CL AASHTO= A-6(8) #30 79 Coefficients #50 76 o85= 2.5354 D6o-D5o= #100 72 D3o= 015= D1o= #200 66 Cu= Cc= Date Tested: 10/08/08 Tested By: SP Remarks (no specification provided) Sample No.: Source of Sample: TH-3 Date Sampled: 10/03/08 Location: Elev./Depth: 0-5 Checked Bv: LM Title: I Geotflt,bnieal Client: ~.:nginN>ring Project: UNA Compressor Station Garfield County Gr•u•t•• l.ue. Proiect No: 3,071 Fi!!ure 14 Gradation Test Report .. E c .E . " 8 \l ~ .s .s c ·-0 0 0 0 ~ ,;:; ~ ·-ro m ~ N ~ ~ ~ ~M it " \1: ;.; it " " 100 I il I I i 1-1:1 I I : I ' 1\ I I : I I i I 90 jl -· -- I I I I I I I. I """" I I I I I I II I II I I I I I !""< I I I I 80 II I'N I I I I I I I I I I I 70 I I 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 0:: I I I I I I I I I I ! I I ''I w 60 z i I u: I II I I 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 z 50 I I I I I I w : I I : I : I I I I : : I I (.) 0:: w 40 I I I II I I I I I I CL I I I I I Ill I I I I I! I I I I I I I 30 I ~ I Ill I I I I ,, I I I I I I I Ill I I I I I I I I I I I 20 I II! I I I I I I I I I I I ! II! I ! I ! I I I ! : I I 10 I II' I I I I II I I I I I I I 0 I I I I I I I I I I I I I I 100 10 1 0.1 O.D1 0.001 GRAIN SIZE-mm. %+3" %Gravel %Sand %Fines Coarse T Fine Coarser Medium I Fine Silt I Clay 0 0 I 8 4 5 I 15 68 SIEVE PERCENT SPEC." PASS? Material DescriJ;!tion SIZE FINER PERCENT (X=NO) TH-1, 2, 3 Blended 3/4" 100 1/2" 98 Atterberg Limits (ASTM D 4318) 3/8" 96 PL= 17 LL-27 PI-9 #4 92 Classification #8 89 #16 87 USCS= CL AASHTO= A-4(4) #30 85 Coefficients #50 82 o85= o.6897 Deo-D5o= #100 77 D3o= 015= D1Q= #200 68 Cu= Cc= Date Tested: 10115/08 Tested By: SP Remarks (no specification provided) Sample No.: Source of Sample: 1-3Blend Date Sampled: 10/03/08 Location: Elev./Depth: 0-5 Checked Bv: LM Title: lt;eott~dlltit"tl Client: ~~ngin••••ring Project: UNA Compressor Station Garfield County t;r•n•r•· ln.,. Proiect No: 3,071 Fiaure 15 13 "- ~ c "' "0 c 0 Moisture-Density Relationship Curve ( Proctor) I Geo-tedtni.:al ..... Engineering Ia. Group~ In~. Curve No.: 1 Project No.: 3,071 Project: UNA Compressor Station Garfield County Date: 140 130 120 110 100 90 80 Source: l-3Blend Remarks: Description: TH-1, 2, 3 Blended Elev./Depth: 0-5 Sample No. MATERIAL DESCRIPTION Classifications - Nat. Moist. = 6.6 % Liquid Limit = 27 % > 3/8 in.= 4.0% uses: cL AASHTO: A-4(4) -- ·- --- Sp.G.= Plasticity Index = 9 % < No.200 = 68 % TEST RESULTS Maximum dry density= 114.5 pcf Optimum moisture= 13.0% 1'\. Test specification: 1"\ ASTM D 698-00a Method B Standard 1\. ' 1"\ 1\. " 1'\. " '\. '\. I '\. '\. '\. 100% SATURATION CURVES "'\.' " .. 1'\. ", FOR SPEC. GRAV. EQUAL TO: r--------'l 2.8 .., .. ...... J .. ~ f'-. 0 2.7 , 2.6 ..... ·-----)',. """--. r-..r--- ' 1'\. ' )',. I" 1'. ..... ' -' ' 1-' ..... ...... 1'\. ,..... ..... ,..... ' ,..... ,..... ..... ----... "--- 5 10 15 20 25 30 35 Water content, % t>-,..... ...... ...... ...... ...... --- 40 Figure 16 BEARING RATIO TEST REPORT ASTM D 1883-99 100 80 ~ ~~ "iii .!; "' 60 -----r-------------0 r: ,f! ~ Ill I 'i n: ~ r: 0 "' E 40 -"' r: "' 0.. 20 ,j 0 0 0.1 0.2 0.3 0.4 0.5 Penetration Depth (in.) Molded Soaked CBR(%) Linearity Surcharge Max. Density Percent of Moisture Density Percent of Moisture 0.10 in. 0.20 in. Correction (lbs.) Swell (pcfj Max. Dens. (%) (pcfj Max. Dens. (%) (ln.) (%) 1 0 99.0 86.5 12.4 99.0 86.6 19.4 4.1 3.2 0.000 17.6490 0 2!'. --····--·-}--··- 3D Material Description Max. Optimum uses ~:~· Moisture LL PI 1%\ TH-1, 2, 3 Blended CL 114.5 13.0 27 9 Project No: 3,071 Test Description/Remarks: Project: UNA Compressor Station Garfield County Source of Sample: 1-3Blend Depth: 0-5 Date: 10/03/08 11 ••. , .. ._ .......... ,. .• -~••##i•••""•~rin:.; ••......... I"· I •••~ .. Figure 17 II Geotechnical ~.._Engineering ~Group, Inc. GEGJOBNO. 3,071 Existing Slope Irrigation Ditch Fill Slope Compacted Fill \_Toe key excavated into competent foundation material Existing Slope Benched into competent foundation material. Number of benches is dependent on onsite condition encountered during construction. GEG representative to confirm at that time. Recommended Key and Bench Into Existing Slopes Concept DATE: 10/2912008 Fig. 18 II Geotechnical ~"'-Engineering ~Group, Inc. GEGJOBNO. Fill Slooe-~ Compacted Fill 4" or 6" diameter perforated drain pipe Free draining aggregate at least 3 cubic feet per linear foot of pipe wrapped with an appropriate filter fabric. nnr·nnrio+~ filter fabric 4" or 6" diameter perforated drain pipe Free draining aggregate at least 3 cubic feet per linear foot of pipe wrapped with an appropriate filter fabric. Toe Key and Bench Drain Details DATE: 10/2912008 3,071 Fig. 19 Hole TH-1 TH-1 TH-2 TH-3 TH-3 TH-4 TH-4 Geotechnical I ~ .... Engineering 1-...Group, Inc. Depth Natural Dry (feet) Moisture Density (%) (pel) 0 to 5 I 4.1 -- 4 10.8 94 0 to 5 3.2 -- 0 to 5 11.0 -- 9 13.0 115 9 9.8 105 19 12.8 98 Job No. 3071 TABLE I SUMMARY OF LABORATORY TEST RESULTS Atterberg Limits Swell/ Consolidation Direct Shear Passing Water Soil Type No. 200 Soluble Liquid Plasticity Swell Confining Estimated Internal Cohesion Sieve Sulfates Limit Index (%) Pressure Swell Angle of (psi) (%) (ppm) (%) (%) (psi) Pressure Friction (psfl (Degrees) 28 14 ----------56 5,000 Clay, slightly gravelly (CL) -----0.2 250 ---- ------Clay, slightly gravelly (CL) 27 13 --------50 1,300 Clay, slightly gravelly (CL) 30 16 -------- --65 3,800 Clay, slightly gravelly (CL) ----3.2 500 ----------Clay, slightly gravelly (CL) ------ --23 300 ------Clay, slightly gravelly (CL) -----6.8 1000 ------ ----Clay, slightly gravelly (CL) Page 1 of 1 Geoteclmical I ~.:ngineering I Gronp, Inc. Hole Depth Natural (Feet) Moisture TH~1, TH-2 0 to 5 6.6 and TH-3 Atterberg Limits Liquid Plasticity Limit(%) Index(%) 27 9 TABLE II Job No. 3071 SUMMARY OF LABORATORY TEST RESULTS Standard Proctor CBR Passing Water Soluble Soil Type (ASTM D698) Value No. 200 Sulfates Maximum Optimum Sieve (ppm) Dry Density Moisture (%) (pcf) Content (%) 114.5 13.0 3.2 68 --Clay, gravelly (CL) Page 1 of 1 APPENDIX A SAMPLE SITE GRADING SPECIFICATIONS SAMPLE SITE GRADING SPECIFICATIONS UNA Compressor Station Garfield County, Colorado Note: Appendix A presents sample specifications. These sample specifications are not project specific. The sample specifications should be modified by the Architect, Civil engineer or Structural engineer as needed to reflect project specific requirements.) 1. DESCRIPTION This item shall consist of the excavation, transportation, placement and compaction of materials from locations indicated on the plans, or staked by the Engineer, as necessary to achieve preliminary street and overlot elevations. These specifications shall also apply to compaction of excess cut materials that may be placed outside of the subdivision and/or filing boundaries. 2. GENERAL The Soils Engineer shall be the Owner's representative. The Soils Engineer shall approve fill materials, method of placement, moisture contents and percent compaction, and shall give written approval of the completed fill. 3. CLEARING JOB SITE The Contractor shall remove all trees, brush, and rubbish before excavation or fill placement is begun. The Contractor shall dispose of the cleared material to provide the Owner with a clean, neat appearing job site. Cleared material shall not be placed in areas to receive fill or where the material will support structures of any kind. 4. SCARIFYING AREA TO BE FILLED All topsoil and vegetable matter shall be removed from the ground surface upon which fill is to be placed. The surface shall then be plowed or scarified until the surface is free from ruts, hummocks or other uneven features, which would prevent uniform compaction by the equipment to be used. Job No. 3,071 Fig. A-1 5. COMPACTING AREA TO BE FILLED After the foundation for the fill has been cleared and scarified, it shall be disked or bladed until it is free from large clods, brought to the proper moisture content (within 2 percent above or below optimum) and compacted to not less than 95 percent of maximum density as determined in accordance with ASTM D 698. If soft/ yielding subgrade conditions are encountered, stabilization may be required. 6. FILL MATERIALS Fill soils shall be free from vegetable matter or other deleterious substances, and shall not contain rocks or lumps having a diameter greater than six (6) inches. Fill materials shall be obtained from cut areas shown on the plans or staked in the field by the Engineer. On-site materials classifying as CL, SC, SM, SW, SP, GP, GC and GM are acceptable. Concrete, asphalt, organic matter and other deleterious materials or debris shall not be used as fill. 7. MOISTURE CONTENT Fill materials shall be moisture treated to within 2 ± percent of optimum moisture content as determined from Proctor compaction tests. Sufficient laboratory compaction tests shall be made to determine the optimum moisture content for thee various soils encountered in borrow areas. The Contractor may be required to add moisture to the excavation materials in the borrow area if, in the opinion of the Soils Engineer, it is not possible to obtain uniform moisture content by adding water on the fill surface. The Contractor may be required to rake or disk the fill soils to provide uniform moisture content through the soils. The application of water to embankment materials shall be made with any type of watering equipment approved by the Soils Engineer, which will give the desired results. Water jets from the spreader shall not be directed at the embankment with such force that fill materials are washed out. Should too much water be added to any part of the fill, such that the material is too wet to permit the desired compaction from being obtained, rolling and all work on that section of the fill shall be delayed until the material has been allowed to dry to the required moisture content. The Contractor will be permitted to rework wet material in an approved manner to hasten its drying. Job No. 3,071 Fig. A-2 8. COMPACTION OF FILL AREAS Selected fill material shall be placed and mixed in evenly spread layers. After each fill layer has been placed, it shall be uniformly compacted to not less than the specified percentage of maximum density. Expansive soils classifying as CL or SC shall be compacted to at least 95 percent of the maximum dry density as determined in accordance with ASTM D 698 ( 100 percent for fill deeper than 15 feet below final grade). At the option of the Soils Engineer, soils classifying as SW, SP, GP, GC or GM may be compacted to 90 percent of the maximum density as determined in accordance with ASTM D 1557 (95 percent for fill deeper than 15 feet below final grade). Fill materials shall be placed such that the thickness of loose material does not exceed 1 0 inches and the compacted lift thickness does not exceed 6 inches. Compaction, as specified above, shall be obtained by the use of sheepsfoot rollers, multiple-wheel pneumatic-tired rollers, or other equipment approved by the Engineer for soils classifying as CL or SC. Granular fill shall be compacted using vibratory equipment or other equipment approved by the Soils Engineer. Compaction shall be accomplished while the fill material is at the specified moisture content. Compaction of each layer shall be continuous over the entire area. Compaction equipment shall make sufficient trips to insure that the required density is obtained. 9. COMPACTION OF SLOPES Fill slopes shall be compacted by means of sheepsfoot rollers or other suitable equipment. Compaction operations shall be continued until slopes are stable, but not too dense for planting, and there is no appreciable amount of loose soil on the slopes. Compaction of slopes may be done progressively in increments of three to five feet (3' to 5') in height or after the fill is brought to its total height. Permanent fill slopes shall not exceed 3:1 (horizontal to vertical). 10. DENSITY TESTS Field density tests shall be made by the Soils Engineer at locations and depths of his choosing. Where sheepsfoot rollers are used, the soil may be disturbed to a depth of several inches. Density tests shall be taken in compacted material below the disturbed surface. When density tests indicate that the density or moisture content of any layer of fill or portion thereof is below that required, the particular layer or portion shall be reworked until the required density or moisture content has been achieved. Job No. 3,071 Fig. A-3 11. COMPLETED PRELIMINARY GRADES All areas, both cut and fill, shall be finished to a level surface and shall meet the following limits of construction: A. Overlot cut or fill areas shall be within plus or minus 2/1 0 of one foot. B. Street grading shall be within plus or minus 1/10 of one foot. The civil engineer, or duly authorized representative, shall check all cut and fill areas to observe that the work is in accordance with the above limits. 12. SUPERVISION AND CONSTRUCTION STAKING Observation by the Soils Engineer shall be continuous during the placement of fill and compaction operations so that he can declare that the fill was placed in general conformance with specifications. All inspections necessary to test the placement of fill and observe compaction operations will be at the expense of the Owner. All construction staking will be provided by the Civil Engineer or his duly authorized representative. Initial and final grading staking shall be at the expense of the owner. The replacement of grade stakes through construction shall be at the expense of the contractor. 13. SEASONAL LIMITS No fill material shall be placed, spread or rolled while it is frozen, thawing, or during unfavorable weather conditions. When work is interrupted by heavy precipitation, fill operations shall not be resumed until the Soils Engineer indicates that the moisture content and density of previously placed materials are as specified. 14. NOTICE REGARDING START OF GRADING The contractor shall submit notification to the Soils Engineer and Owner advising them of the start of grading operations at least three (3) days in advance of the starting date. Notification shall also be submitted at least 3 days in advance of any resumption dates when grading operations have been stopped for any reason other than adverse weather conditions. Job No. 3,071 Fig. A-4 15. REPORTING OF FIELD DENSITY TESTS Density tests made by the Soils Engineer, as specified under "Density Tests" above, shall be submitted progressively to the Owner. Dry density, moisture content, of each test taken and percentage compaction shall be reported for each test taken. 16. DECLARATION REGARDING COMPLETED FILL The Soils Engineer shall provide a written declaration stating that the site was filled with acceptable materials, or was placed in general accordance with the specifications. 17. DECLARATION REGARDING COMPLETED GRADE ELEVATIONS A registered Civil Engineer or licensed Land Surveyor shall provide a declaration stating that the site grading has been completed and resulting elevations are in general conformance with the accepted detailed development plan. Job No. 3,071 Fig. A-5 APPENDIX B PAVEMENT DESIGN CALCULATIONS Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.49 62,400.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 0.00 0.00 0.00 0.00 0.00 Wednesday, October 29, 2008 2:33:00PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 6.22 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 It;N 4,300.00 psi 4.50 2.50 Layer SN 2.49 0.00 0.00 0.00 0.00 0.00 2.49 Fig. B1 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.49 62,400.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 Crushed Stone Base 0.12 0.00 0.00 0.00 0.00 Wednesday, October 29, 2008 2:27:10PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 3.00 1.00 10.72 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 L"'' 4,300.00 psi 4.50 2.50 Layer SN 1.20 1.29 0.00 0.00 0.00 0.00 2.49 Fig. B2 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.49 62,400.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 Crushed Stone Base 0.12 Granular Subbase 0.09 0.00 0.00 0.00 Wednesday, October 29, 2008 2:35:10PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 3.00 1.00 5.00 1.00 7.63 0.00 0.00 0.00 0.00 0.00 0.00 l: <;~ 4,300.00 psi 4.50 2.50 Layer SN 1.20 0.60 0.69 0.00 0.00 0.00 2.49 Fig. B3 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs A~ency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.88 156,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 0.00 0.00 0.00 0.00 0.00 Wednesday, October 29, 2008 2:38:33PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 7.19 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ~~~ 4,300.00 psi 4.50 2.50 Layer SN 2.88 0.00 0.00 0.00 0.00 0.00 2.88 Fig. B4 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.88 156,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent OA5 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete OAO Crushed Stone Base 0.12 0.00 0.00 0.00 0.00 Wednesday, October 29, 2008 2:42:43PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 4.00 1.00 10.64 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 );::;, 4,300.00 psi 4.50 2.50 Layer SN 1.60 1.28 0.00 0.00 0.00 0.00 2.88 Fig. B5 WinPAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.88 156,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 Crushed Stone Base 0.12 Granular Subbase 0.09 0.00 0.00 0.00 Wednesday, October 29, 2008 2:44:36PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 4.00 1.00 5.00 1.00 7.52 0.00 0.00 0.00 0.00 0.00 0.00 ~::;, 4,300.00 psi 4.50 2.50 Layer SN 1.60 0.60 0.68 0.00 0.00 0.00 2.88 Fig. 86 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.96 187,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 0.00 0.00 0.00 0.00 0.00 Wednesday, October 29, 2008 .2:47:00PM Engineer:. NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 7.40 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ~::;1\ 4,300.00 psi 4.50 2.50 Layer SN 2.96 0.00 0.00 0.00 0.00 0.00 2.~6 Fig. B7 WinPAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.96 187,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 Crushed Stone Base 0.12 0.00 0.00 0.00 0.00 Wednesday, October 29, 2008 2:48:26PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 4.00 1.00 11.33 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ~"'" 4,300.00 psi 4.50 2.50 Layer SN 1.60 1.36 0.00 0.00 0.00 0.00 2.96 Fig. 88 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.96 187,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 Crushed Stone Base 0.12 Granular Subbase 0.09 0.00 0.00 0.00 Wednesday, October 29, 2008 2:50:33PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 4.00 1.00 6.00 1.00 7.11 0.00 0.00 0.00 0.00 0.00 0.00 """ 4,300.00 psi 4.50 2.50 Layer SN 1.60 0.72 0.64 0.00 0.00 0.00 2.96 Fig. B9 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Flexible Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Flexible Pavement Design/Evaluation 2.96 187,200.00 Structural Number Design ESALs Reliability Overall Deviation 80.00 percent 0.45 Layer Pavement Design/Evaluation Layer Layer Material Coefficient Asphalt Cement Concrete 0.40 Crushed Stone Base 0.12 Granular Subbase 0.09 0.00 0.00 0.00 Wednesday, October 29, 2008 2:52:47PM Engineer: NWJ Soil Resilient Modulus Initial Serviceability Terminal Serviceability Drainage Layer Coefficient Thickness 1.00 4.00 1.00 5.00 1.00 8.44 0.00 0.00 0.00 0.00 0.00 0.00 L'>i' 4,300.00 psi 4.50 2.50 Layer SN 1.60 0.60 0.76 0.00 0.00 0.00 2.96 Fig. 810 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Rigid Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Rigid Pavement Design/Evaluation 4.08 inches Load Transfer, J PCC Thickness Design ESALs Reliability Overall Deviation Modulus of Rupture Modulus of Elasticity 62,400.00 80.00 0.45 500 percent psi Mod. Subgrade Reaction, k Drainage Coefficient, Cd Initial Serviceability Terminal Serviceability 3,375,000 psi Modulus of Subgrade Reaction lk-value) Determination Resilient Modulus of the Subgrade Resilient Modulus of the Subbase Subbase Thickness Depth to Rigid Foundation Loss of Support Value (0, 1 ,2,3) 4,300.00 0.00 0.00 0.00 0.00 psi psi inches feet Modulus of Subgrade Reaction 220.00 psi/in Wednesday, October 29, 2008 2:55:44PM Engineer: NWJ 3.20 220 psi/in 1.00 4.50 2.50 Fig. B11 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Rigid Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Rigid Pavement Design/Evaluation PCC Thickness 5.06 inches Load Transfer, J Design ESALs 156,200.00 Mod. Subgrade Reaction, k Reliability Overall Deviation Modulus of Rupture Modulus of Elasticity 80.00 percent Drainage Coefficient, Cd 0.45 Initial Serviceability 500 psi Terminal Serviceability 3,375,000 psi Modulus of Subgrade Reaction (k .. valuel Determination Resilient Modulus of the Subgrade 4,300.00 psi 0.00 psi 0.00 inches 0.00 feet 0.00 Resilient Modulus of the Subbase Subbase Thickness Depth to Rigid Foundation Loss of Support Value (0, 1 ,2,3) Modulus of Subgrade Reaction 220.00 psi/in Wednesday, October 29, 2008 2:57:12PM Engineer: NWJ 3.20 220 psi/in 1.00 4.50 2.50 Fig. B12 Win PAS Pavement Thickness Design According to 1993 AASHTO Guide for Design of Pavements Structures American Concrete Pavement Association Rigid Design Inputs Agency: Star Valley Enterprises Company: Contractor: Project Description: GEG Job No 3071 UNA Compressor Station Location: Parachutte, Colorado Rigid Pavement Design/Evaluation PCC Thickness 5.27 inches Load Transfer, J Design ESALs 187,200.00 Mod. Subgrade Reaction, k Reliability Overall Deviation Modulus of Rupture Modulus of Elasticity 80.00 percent Drainage Coefficient, Cd 0.45 Initial Serviceability 500 psi Terminal Serviceability 3,375,000 psi Modulus of Subgrade Reaction (k-valuel Determination Resilient Modulus of the Subgrade 4,300.00 psi o.oo psi 0.00 inches 0.00 feet 0.00 Resilient Modulus of the Subbase Subbase Thickness Depth to Rigid Foundation Loss of Support Value (0,1,2,3) Modulus of Subgrade Reaction 220.00 psi/in Wednesday, October 29, 2008 2:58:39PM Engineer: NWJ 3.20 220 psi/in 1.00 4.50 2.50 Fig. B13 APPENDIXC CONSTRUCTION RECOMMENDATIONS FOR FLEXIBLE AND RIGID PAVEMENT FLEXIBLE PAVEMENT CONSTRUCTION RECOMMENDATIONS Experience has shown that construction methods can have a significant effect on the life and serviceability of a pavement system. We recommend the proposed pavement be constructed in the following manner: 1. The subgrade should be stripped of organic matter, existing fill and deleterious materials, scarified, moisture treated, and compacted. Existing structures should also be removed completely. Soils should be moisture treated to within 2 percent of optimum moisture content and compacted to at least 95 percent of maximum standard Proctor dry density (ASTM D 698). 2. After final subgrade elevation has been reached and the subgrade compacted, the area should be proof-rolled with a heavy pneumatic-tired vehicle (i.e., a loaded 1 0-wheel dump truck). Subgrade that is pumping or deforming excessively should be stabilized. 3. If areas of soft or wet subgrade soils are encountered, the material should be subexcavated and replaced with properly compacted structural backfill. Where extensively soft, yielding subgrade is encountered, we recommend the excavation be inspected by a representative of our office. 4. Aggregate base course and aggregate subbase course should be laid in thin, loose lifts, moisture treated to within 2 percent of optimum moisture content and compacted to at least 95 percent of maximum modified Proctor dry density (ASTM D 1557, AASHTO T 180). 5. Asphaltic concrete should be hot plant-mixed material compacted to between 92 and 96 percent of maximum theoretical density. The temperature at laydown time should be at least 235 degrees F. The maximum compacted lift should be 3.0 inches and joints should be staggered. 6. The subgrade preparation and the placement and compaction of all pavement material should be observed and tested. Compaction criteria should be met prior to the placement of the next paving lift. The additional requirements of the Colorado Department of Transportation and Garfield County Specifications should apply. Job No. 3,071 Fig. C-1 RIGID PAVEMENT CONSTRUCTION RECOMMENDATIONS Rigid pavement sections are not as sensitive to subgrade support characteristics as flexible pavement. Due to the strength of the concrete, wheel loads from traffic are distributed over a large area and the resulting subgrade stresses are relatively low. The critical factors affecting the performance of a rigid pavement are the strength and quality of the concrete, and the uniformity of the subgrade. We recommend subgrade preparation and construction of the rigid pavement section be completed in accordance with the following recommendations: 1. Subgrade areas should be stripped of organics, existing fill and deleterious materials. Existing structures should also be completely removed. The pavement subgrade shall be compacted within 2% of optimum moisture content to at least 95% of maximum standard Proctor dry density (ASTM D 698). Moisture treatment and compaction recommendations also apply where additional fill is necessary. 2. The resulting subgrade shall be checked for uniformity and all soft or yielding materials should be replaced prior to paving. Concrete should not be placed on soft, spongy, frozen, or otherwise unsuitable subgrade. 3. The subgrade shall be kept moist prior to paving. 4. Concrete should not be placed in cold weather or on frozen subgrade. 5. Curing procedures should protect the concrete against moisture loss, rapid temperature change, freezing, and mechanical injury for at least 3 days after placement. Traffic should not be allowed on the pavement for at least one week. 6. A white, liquid membrane curing compound, applied at the rate of 1 gallon per 150 square feet, should be used. 7. Construction joints, including longitudinal joints and transverse joints, should be formed during construction or should be sawed shortly after the concrete has begun to set, but prior to uncontrolled cracking. All joints should be sealed. 8. Construction control and inspection shall be carried out during the subgrade preparation and paving procedures. Concrete shall be carefully monitored for quality control. The additional requirements of Garfield County and The Colorado Department of Transportation Specifications should apply. 9. Deicing salts should not be used for the first year after placement. Job No. 3,071 Fig. C·2