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Report -0000( r J GENERAL CONTRACTORS 8 CONSTRUCTION MANAGERS 1 Mi 3330 E Louise Drive,Ste 300,Meridian,Idaho 83642 Phone(208)362-3040 FAX(208)362-3113 ENOINEEREO STRUCTURES IMO. www.esiconstruction.com OR Contractors License CCB#77160 LETTER OF TRANSMITTAL D038-37 Date:7/26/2013 Page 1 of 1 TO: PACLAND Project: WAL-MART#5935 TIGARD,OR 606 Columbia Street NW, Suite 106 7600 SW DARTMOUTH STREET Olympia,WA 98501 TIGARD,OR 97223 ATTN: Jared VerHey ESI Job Number: D038- Phone: (360)786-9500 Fax: (360)786-5267 Architect Project No. 10053 Email: jverhey @pacland.com Item Description Copies Status Remarks 02360-01 Ground Improvement 1 For Your _ Desi r n-Desi•n,QA/QC Plan Approval Notes >. KEViEweD 0 jtejei-TeL C.1 FURNISH WITH ❑ NO PART NOTED REVI51ONS SUPAARTAIS ❑ REVISE AND 0 NOT REQUIRED RESUBMIT FOR REVIEW Comments made on the shop drawings daring this review do not relieve Contractor from compliance with requirements of Contract Documents.This review it only for general conformance with the design concept and general compliance with the information given in the Contract Document. It does not include review of quantities.dimensions.weight(or gauges.fabrication processes. construction methods.coordination with the work of the trades. or construction safety precautions,all of which are the sole responsibility of the IraetOr I'ACI,AND Portia C �1/?//,8 Date /l Y For Your (CC: Signature Approved As Action Needed Dena Maxwell Delivery Method Project Coordinator Ship#: denamaxwell@esioonstruction.com "Experience... Service ... Integrity" LICENSES:AK,AZ,AR,CA,CO,ID,IN,IA,KS,KY,LA,MN,MO,MT,NE,NV,NM,ND,OK,OR,SD,TX,UT,WA,WI,WY CA#696242 NV#24265B AZ ROC 132139 OR CCB#77160 NM 488125 AK#27938 ID RCE-3108 July 31, 2013 llerracon PACLAND 6400 SE Lake Road, Suite 200 Portland, Oregon 97222 Attn: Mr. Shawn Nguy, PE Re: 02360 Specification Submittal—Ground Improvement Design Review 3 Walmart Store #5935-00 Tigard, Oregon Terracon Project No. 82131014 Dear Mr. Nguy: As requested, we have reviewed the documents Advanced Geosolutions, Inc. (AGI) submitted to Engineered Structures, Inc. (ESI) for the submittal titled, "Ground Improvement Design and Construction, Rev 2" dated July 26, 2013, with respect to the requirements stated in the specification section 02360 Ground Improvement Design and Construction of the Project Manual. Based on our review, it is our opinion that the ground improvement design meets the ground improvement project specifications. We recommend approving the design and providing approval to proceed. Sincerely, Terracon Consultants, Inc. r_ lr Eric J. Li P- , GE Kristopher T. Hauck, PE Geotechnical Department Manager Office Manager Terracon Consultants, Inc 4103 SE International Way,#300 Portland Oregon 97222 P [503] 659 3281 F (503]659 1287 terracon.com Geotechnical • Environmental • Construction Materials • Far ilities Advanced Geosolutions, Inc. 13 Orchard Rd.,Suite 105 05, Lake Forest, CA 92630 5,,,ctu.«.�.. P (310) 796-9000 F (310) 796-9001 oq:,": °'°"°'o rap July 26, 2013 Our Ref: 714177 Mr. Jeffrey Diehl Engineered Structures, Inc. 3330 East Louise Drive, Suite 300 Meridian, ID 83642 RE: Ground Improvement Design and Construction, Rev 2 Specification Section 02360 Submittal 001 Wal-Mart#5935 Tigard, Oregon Dear Jeffrey: This submittal incorporates comments received from Pacland/Terracon, per email communication sent by ESI. In accordance with specification requirements, Advanced Geosolutions, Inc. (AGI) is pleased to submit this design, quality assurance and quality control (QA/QC) plan, and installation procedures of Ground Improvement at the above referenced project. Concepts, calculations, means and methods in this design are deemed intellectual property of AGI, and shall remain confidential to Engineered Structures, Inc. (ESI), its design consultants working on this project, Owner's Engineer, and Building and Safety official tasked with review and approval of this project. AGI's design, and any other related information, shall not be made available to another party without the expressed written consent of AGI. AGI has performed this evaluation in a manner consistent with the standard of practice exercised by members of the geotechnical engineering community practicing in this field. We appreciate the opportunity to be of service. Please contact the undersigned if you have any questions regarding this submittal or require additional information. Sincerely, Advanced Geosolutions, Inc. (AGI) _SPED PROF-4;s, 4451 � N�F9/mot 80300PE r • gN/VAN6p' Juan I. Baez, Ph.D., P.E. EXPIRES: 1 A' ' Raul Verduzco, P.E., LEED AP Oregon License No 80300PE Design-Build Staff Engineer Chief Engineer Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard.Oregon 1. INTRODUCTION The proposed Walmart project will consists of two Retail Pads (12,000 SF) and a main store pad covering approximately 138,000 SF. The main retail pad is planned with a finished floor elevation (FFE) of+180FT, whereas the Retail 1 FFE is panned at +176FT and Retail 2 FFE at +186.5 FT. Current site grade elevations are in the +172 to +185FT range. Consequently, Fills are required to reach FFE for the areas in question. The site is subject to potential seismically induced liquefaction. Ground Improvements are designed to meet performance specifications in accordance with Section 3.1. A geotechnical report"Final Geotechnical Engineering Report Proposed Walmart Store#5935- 00, Tigard, Oregon" dated March 5, 2013 was prepared for the project by Terracon Consultants, Inc. Two issues have been identified in the Terracon report: 1) consolidation of the underlying compressible soils which will result in estimated static settlements in the order of 3 to 7 inches because of the additional loading from the fills and site grading operations required to achieve a finished floor elevation of 180.00 feet, and 2) liquefaction induced total and differential settlements across the building pad and outlot pads of the underlying sand and non-plastic silt soils. Ground improvement is recommended to improve the stiffness or density of the in-situ soils to provide the minimum required design and performance parameters provided below in accordance with Specification Section 02360 as well as to limit liquefaction related settlements for the proposed building footprint and building structural elements. AGI has selected a combination of ground improvement techniques to address the two issues described in the Terracon report. In areas where liquefaction induced settlement are lower than the maximum calculated limit of 4 inches we will use the preload (by others) and wick drains to accelerate anticipated consolidation, to within allowable 1 inch limits, over a period of 5-10 weeks following the complete installation of the preload. Foundation footings will be supported on Stone Columns (Aggregate Piers), and areas of the site where liquefaction induced settlements exceed 4 inches will be treated with Stone Columns as well. 2. METHOD STATEMENT This submittal addresses the installation of wick drains and stone columns to achieve the performance criteria specified in Section 02360— Ground Improvement Design and Construction, Part 3.1. The planned ground improvement layout consisting of stone columns and wick drains for the main building and outlot buildings is shown in Appendix A. Stone columns, also referred to as vibro-replacement columns, is a ground improvement technique that uses purposed-built specialty vibroflots to reinforce and/or densify native soils. A typical stone column consist of a crushed rock column with a diameter ranging from 2 to 3 feet; all other things being equal, the diameter is a function of the stiffness of the confining soil; smaller diameter columns are produced in stiffer confining soils. Wick Drains are artificial vertical drainage paths consisting of a central plastic core, which functions as a free-draining water channel, surrounded by a thin geotextile filter jacket. A typical wick drain is approximately 4 inches wide, 1/8 inch thick, and comes in rolls up to 1,000 feet in length. To better define the limits of work assigned to the wick drain or stone column treatments AGI has undertaken an extensive CPT program consisting of an additional 27 explorations (AGI-1 thru AGI-27). The CPTs were performed at nominal 80ftx80ft spacings, 1 CPT per 6,400SF, which is in excess of the post-CPT area frequency (10,000SF) required by the specifications in A G I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon order to evaluate work after treatments. The locations of the AGI CPT supplemental exploration, as well as locations of Borings and CPTs performed by Terracon, are shown in the attached Appendix B. Based on the geotechnical information available to date, we anticipate that pre-augering of the top 7ft may be required at some locations. This will assist with vibroflot and wick drain installation unit penetration to the design depth. The installation process of stone columns consists of imparting energy by means of vibrations that are generated close to the tip of the vibroflot and are produced by rotating eccentric weights mounted on a shaft. An electric motor rotates the eccentric weights at high speed. The vibroflot is suspended from follower tubes which are used to lower the vibroflot to the design depth. To install a stone column, the vibroflot and follower tube arrangement is suspended from a crane or excavator. The vibroflot is lowered into the ground under the action of its own weight, vibrations and air jetting. Upon reaching the design depth the vibroflot is raised to allow stone to be expelled at the tip of the vibroflot. The height the vibroflot is raised varies between 2ft and 4ft and is a function of the soil conditions. In some instances it may be necessary to raise the vibroflot greater than 4ft to clear a stone blockage. Once a blockage has been removed, the operator will resume using 2ft to 4ft lift heights. Cohesionless soils are densified and reinforced by the construction of the stone column, while cohesive soils are reinforced by the installation of the column. At this site, there appears to be few cases of clean granular soil that would densify due to vibratory effects. Usual practice indicates that soils with fines content in excess of 15- 20% cannot be densified under the vibratory action of the vibroflot equipment. For liquefaction mitigation, the stone columns are installed on a grid pattern which is designed to reduce deformations to the design levels. For foundation support the columns are grouped under each footing and are sized and spaced to reduce expected settlements to design levels. Because of the silty and/or clayey condition of the site soils, improvements will be achieved as a result of replacement and/or displacement of part of the ground with the stiffer stone column. The design criteria calls for liquefaction settlement to be reduced to less than 4-inches and long-term static settlement to be reduced to less that 1-inch in accordance with the specifications. For the wick drain installation, AGI will be supported by the technical assistance and equipment resources of Menard, USA and its affiliated company U.S. Wicks (largest wick drain contractor in the country). The installation process of wick drains consist of a bottom drive static-vibratory wick drain installation unit connected to a mast through which the wick drain material, encased in a rectangular steel mandrel, is statically forced (constant load or constant rate method) into the soil. If stiff/dense layers are encountered, vibration can be induced to aid penetration. The wick drain installation unit will be mounted to either a CAT 330 hydraulic excavator or similar. Wick drains were developed primarily to speed up the consolidation of cohesive soils. They are normally installed on a regular grid pattern ranging from 3-feet to 6-feet on center depending on ground conditions. The drains accept water from the consolidating ground in the radial direction and transport it the vertical direction with as little hydraulic resistance as possible. In addition to their initial application, wick drains have proven to be very beneficial in aiding the vibratory densification of mixed soils. Traditionally soils that contain high fines have shown only limited densification improvement immediately after the installation of stone columns, with the full improvement not measurable for many weeks after the installation is complete. However, by installing wick drains before the stone columns, the effectiveness of the stone columns can be increased considerably, and the results of the improvement can be verified in a much shorter period of time. SAG I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon Following the completion of the ground improvement installation, the upper soils will become loose and "fluffed". In accordance with the specifications, the GC is to re-instate the disturbed depth (upper 1 to 2 feet of the profile) in accordance with the specification requirements for Engineered Fill. 3. EQUIPMENT Stone Column Equipment The equipment required for the installation of the stone columns consists of a down-hole electric vibroflot, which will be suspended from a 120 ton crawler crane or, at AGI's discretion, CAT 365 or equivalent, an electric generator to supply power to the vibroflot, a front end loader (or high reach loader)to supply crushed stone to the vibroflot, an air compressor to push gravel through the follower tube, and a small excavator mounted drill for pre-drilling approximately top 7ft, if necessary. Figure 1 and Figure 2 depict the essential equipment components and setup of the stone column system mounted on a crane and mounted on an excavator, respectively. At AGI's discretion, a down-hole electric vibrator with the following specifications will be used: Crane Mounted Vibrator Excavator Mounted Vibrator Model V-330 V-23 Motor size 130kW 130kW Eccentric Force 230kN 240 kN Voltage 480V 440V Frequency 60Hz 60Hz Freely Suspended Amperage 50-100Amps 75-85 Amps Max Amperage —100 Amps over freely — 85 Amps over freely suspended amperage (up to 2 suspended amperage (up to seconds) 2 seconds) Weight* 2.7 tons 2.3 tons Length* 11 ft 11 ft Diameter* 1.4ft 1.16ft(w/o wear parts) Amplitude 0.8— 1.0 inch 0.8 -1.0 inch *The weight,above exclude the extension(follower)tubes required to reach a particular depth. The vibroflot is fitted with a follower tube to reach the design depth of nominal 25 feet below existing grade. Follower tubes are marked with lines at 1ft increments and with numbers at 5ft increments. The vibroflot is controlled by the crane or excavator operator from the cab of the crane or excavator where the operator can view the power(amps) being used by the vibroflot at all times. A second amp meter located outside the crane or excavator is readily viewable by the inspector at all times during the stone column construction process. The vibrator will be powered by a 200-400kW diesel powered mobile generator. An air compressor (900 to 1,600 CFM) will be used to pressurize the follower tube and push the gravel to the tip of the vibroflot. A front end loader (2 to 4 yard capacity) will be used to supply rock material from the on-site stockpile to the actual stone column location. An excavator mounted drill will be used to MAGI Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon perform pre-drilling at each stone column location to an approximate depth of 7 feet below working grade. : • Q �f ¢z Im1 +peen.cb.nib.lJ =_-. uInI■II■■I� obe Figure 1.Typical AGI Crane Mounted Bottom Feed Vibro-Replacement(Stone Column)Equipment. AGI Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935—Tigard,Oregon Base or carrier unit Hanger coupling Hopper unit � - f ' / ° Closing ,r ` ti;,f 1 '>> ' mechanism A i I "'ir-1'/� Transition tank L ` it Upper silo tube r liPm* Lower silo tube i ERR , 111 II 1111111 f) 3- Vibroflot r -- -I' - Figure 2.Typical AGI Excavator Mounted Bottom Feed Vibro-Replacement(Stone Column)Equipment. Wick Drain Equipment Installation of the vertical wick drains will be accomplished by using a bottom drive static- vibratory wick drain installation unit. The unit consists of a mast through which the wick drain material, encased in a rectangular steel mandrel, is statically forced (constant load or constant rate method) into the soil. If stiff/dense layers are encountered, vibration can be induced to aid penetration. The wick drain installation unit will be mounted to either a CAT 330 hydraulic excavator or similar. Carriers of this size will enable it to achieve its full pushing force. MAGI Ground Improvement Design and Construction July 26.2013 Submittal 001,Rev 2 Wal-Mart 415935-Tigard,Oregon The mandrel is rectangular in section, measuring 5 inches by 2 inches, with rounded corners to ease penetration. The pushing mechanism is a pair of sprockets that grab washers that are welded on to the two wider outside faces of the mandrel. The washers are spaced approximately 5.5 inches on center along the mandrel. The outside and inside diameters of the washers are 3-3/16 inches and 2.0 inches, respectively. The washer thickness is 1/2 inch. The wick drain installation unit is rated at 25 tons static down force, and 1,100 inch-pound eccentric moment. The mandrel length will be setup with a length of approximately 48 feet, capable of installing drains to a maximum depth of approximately 40 feet, depending on ground conditions. The vertical wick drain material to be installed will be Colbond CX1000, manufactured by Colbond, Inc. The technical data sheet for this material has been included with our previous submittal for the wick drain areas. t ,n: -4� ' ' a, i• .C:-•ice.. 4174.—. ��+ /III , "- 1 - ■• • isi .• ,.._ , F _ ;,..t f it '''‘ ■ A .,.. .. . , ,__ imp 4-1. ..... _ Figure 3.Typical Mandrel(left)and Typical AGI Excavator Mounted Wick Drain Installation Equipment(right). 4. DESIGN BASIS AND IMPROVEMENT PROGRAM AGI has performed their analysis based on information obtained from the geotechnical report prepared by Terracon Consultants, Inc. Our design indicates that installation wick drains to a depth of 20 feet and limited area of stone columns to a depth of 25 feet BGS, would satisfy the specification requirements to reduce hazards related to the following issues: • Bearing Capacity • Long-Term Static Settlement • Liquefaction Induced Settlement Parameters for the design are as follows: • Allowable Bearing Pressure: 3,000 psf • Building Foundations Allowable Long Term Total Static Settlement: 5 1 inch. • Building Foundations Allowable Long Term Differential Settlement Over 40 feet: <_ 0.53 inch • Slab Allowable Long Term Total Static Settlement: <_ 1 inch • Slab Allowable Long Term Differential Settlement Over 40 feet: <_ 0.96 inch • Allowable Liquefaction Settlement: 5 4 inches • Allowable liquefaction Differential Settlement over 40ft: 5 2 inches • Design Ground Water Depth: 3 feet • Design earthquake magnitude: Mw 6.8 A G I • Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935—Tigard,Oregon • Design peak ground acceleration: 0.27g Building Foundation Static Settlement Improvement Static settlement improvement calculations for building foundations areas are based on the pre- improvement settlement based on the in-situ soil information and the consolidation test results performed on representative samples of the fine-grained soils encountered at the site and provided in Terracon's report. The amount of settlement improvement is a function of the value of anticipated settlement in the absence of any improvements. In accordance with the standards of practice, the improvement in settlement reduction will depend on the portion of the soil replaced (area replacement ratio) by the improved ground, as well as the material properties of the ground improvement product. The improving effect of stone columns on static settlement under building foundations was analyzed in general accordance with the method proposed by Priebe (1995), which determines an improvement factor based on area replacement ration and the friction angle of the backfill material. Our static settlement analysis with pre- and post-stone columns under the building foundations is included in Appendix C of this submittal, which indicates that a stone column program with an area replacement ratio (Ar) ranging from 28% to 39%, depending of footing type, is adequate to meet the intended settlement performance criteria. Note that this analysis is conservative in the since it neglects any additional consolidation settlement that will occur during the surcharge program. Slab Static Settlement Improvement Static settlement improvement calculations for slab areas are based on the pre-improvement settlement based on the in-situ soil information and the consolidation test results performed on representative samples of the fine-grained soils encountered at the site and provided in Terracon's report. The amount of settlement improvement is a function of the value of anticipated settlement in the absence of any improvements based on the anticipated surcharge load program. In accordance with the standards of practice, the improvement in settlement reduction will depend on the horizontal coefficient of consolidation of the in-situ soils, as shown on the table below, and the wick drain spacing that will accelerate the consolidation settlement during the surcharge program. Note that results from in-situ dissipation tests via CPTs, performed by AGI prior to bid, indicate that horizontal coefficients of consolidation are higher than those measured from lab testing. Nonetheless, for design a value of Ch = 35m^2/yr has been assumed. Summary of Coefficient of Consol Calcs: Coefficient of Consol Test Depth Cv Ch Ch Ch LL (ft) (ft^2lday) (ft^2lday) (cm^2/sec) (m^2Iyr) B-1.S-4 29 7.5 0.35 1 33.9 B-3. S-5 10 0.4 1.1 37.3 B-101, S-8 31 0.5 1.35 45.8 B-102, S-9 55 35 0.15 0.4 13.6 AGI-02 16 1 3154 AGI-02 20 1 3154 A G I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon The improving effect of wick drains on static settlement under the slab areas was analyzed in general accordance with methods proposed by Barron (1948). Based on a 2 foot surcharge above FFE that is to be maintained for a minimum of 5 weeks our calculations, included in Appendix D, show that a 20 foot deep wick drain program with 6 foot triangular spacing in areas where up to 5 feet of fill are required to achieve FFE and with 5 foot triangular spacing in areas where more than 5 feet of fill are required to achieve FFE would be adequate to meet the intended static settlement criteria under the slab areas. However, given that the Ground Improvement program is likely to be completed ahead of the 10 week schedule allowed for in the scope of work between AGI and the GC, AGI reserves the right to extend the preload program beyond the indicated 5 weeks in the event that it becomes necessary without incurring penalties for delay so long as the overall program of ground improvement installations and preload duration are within the allowed 15 week program. Geotechnical Bearing Capacity Improvement The bearing capacity of the improved in-situ soil has been determined based on long established bearing capacity equations utilizing the composite shear strength parameters of the stone column reinforced soils. The composite shear strength of the stone column reinforced soils is computed using the conventional method of calculating the weighted average of the shear strength components of the stone column element and the matrix soil materials (FHWA 1999) based on an area replacement ratio (Ar). Our bearing capacity analysis, included in Appendix E, shows that the area replacement ratio provided for each footing type is adequate to meet the allowable bearing pressure of 3,000 psf under the building foundation areas. Liquefaction Settlement Improvement Liquefaction analyses were undertaken in general accordance with procedures outlined by Youd and Idriss NCEER 1997 and Idriss and Boulanger 2008. While procedures from these 2 standards of practice publications are well established for liquefaction evaluations in sands and silty sands, they are not well established in conjunction with the use of high fine content silty sand, sandy silts, or silts, which are the conditions at the Sherwood Walmart site. There are 2 primary issues of concern and subject of debate: 1) potential for liquefaction of silt soils, and 2) compressibility (volumetric strain)calculations for silt soils. This is because fines corrections for silt content alone do not necessarily capture the compressibility characteristics of a silt or sandy silt. In practical terms, we know from decades of years of experience with vibratory ground improvement techniques that soils containing in excess of 20% simply do not reconstitute (undergo significant volume compressibility change) as well as clean soils, and in fact, little void ratio changes are effectively introduced in spite of significant vibratory strain energy imparted to the soil. As noted by professor Ray Seed et.al., (2003) "It appears likely that, as vibrodensification works by essentially liquefying and densifying the soils, the limits of"treatable" soil types is at least somewhat coincident with the types of soil that are "liquefiable", an thus in need of treatment." Therefore, evaluation of liquefaction potential of silt soils and its consequences (settlement) need to be viewed in an overall context of various methods, parameters, and empirical experience. For this site, it is our opinion that a reasonable approach to evaluating liquefaction and mitigation uses the following procedure: MAGI Ground Improvement Design and Construction Jul■26.2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon a. Evaluate side-by-side CPT and SPT soundings, along with available laboratory data on fines content, moisture, and Atterberg Limits to test potential for liquefaction: • Definition of potentially liquefiable soils per Idriss and Boulanger, 2008 based on laboratory tests and shear wave velocity • Associated CPT calculated Soil Behavior Type, Ic, Index. Use correlated Ic"flag" to define liquefiable vs. non-liquefiable soils. • Available shear wave velocity test data and potential for liquefaction per Andrus and Stokoe 2000 (also cited in Idriss and Boulanger, 2008). b. Calculate liquefaction settlement by 4 procedures: Idriss and Boulanger 2008 (largely based on Ishihara and Yoshimine 1992); Tokimatsu and Seed 1984/1987; Zhang et al (2002)and NCEER (Robertson 1997,1998). Note the commercially available computer software CLiq V1.7 has capability to calculate 3 of the 4 procedures (other than Tokimatsu and Seed). Use an average of the 4 methods. c. Knowing that fines content generally exceed 20% fines, estimate improvement by calculations of reduction in shear stresses redistribution within the soil matrix per Baez, 1995 and a reduction in settlement based vertical stress using area replacement ratio. Implementing a stone column program that will introduce a replacement/displacement ratio greater than the estimated non-treated volumetric strain. On this basis, evaluate total and differential seismic settlements following installed stone column quantities. d. Evaluate post improvement CPTs within areas treated by stone columns. Note areas not treated by stone columns have already been tested with the AGI-series CPTs. These will be submitted with the post-improvement CPTs as part of the as-built information package. Based on the above procedure the following are our findings: a. There are 5 cases of"side-by-side" CPTs-SPTs at the site, namely: CPT Number Corresponding Boring Number CPT-01 B-101 AGI-06 B-1 AGI-19 B-5, WB-7 AGI-21 B-3 AGI-22 MW-1, PW-1 For each case, the following laboratory and corresponding Ic value are available. Note that the laboratory data for each sample is meant to be representative for an 18" interval that constitutes and SPT value. Therefore the Ic is an average value for the corresponding 18" at the same depth as the SPT sample. SAG I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon Pair: CPT-01 and B-101 Liquefiable(Idriss and Boulanger, Depth Fines Ic(Ave 18") LL PI 2008) ft 3.0 5.0 7.5 11.0 16.0 21.0 26.0 31.0 95 2.35 NP NP Yes 32.5 36.0 41.0 Pair: CPT(AGI-06)and B-1 Liquefiable(Idriss and Boulanger, Depth Fines Ic(Ave 18") LL PI 2008) ft 3.0 5.0 7.5 10.0 87 2.61 29 9 No 15.0 20.0 25.0 Pair: CPT(AGI-19)and WB-7 Liquefiable(Idriss and Boulanger, Depth Fines Ic(Ave 18") LL PI 2008) Depth Content FS ft 3.0 5.0 2.68 35 13 No 7.5 10.0 15.0 20.0 25.0 SAG I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon Pair: CPT(AGI-21)and B-3 Liquefiable(Idriss and Boulanger, Depth Fines Ic(Ave 18") LL PI 2008) ft 3.0 2.57 33 9 No 5.0 7.5 10.0 15.0 20.0 Pair: CPT(AGI-22)and MW-1, PW-1 Liquefiable(Idriss and Boulanger, Depth Fines Ic(Ave 18") LL PI 2008) ft 3.0 5.0 88.8 2.82 45 22 No 7.5 10.0 80.2 2.58 NP NP Yes? 15.0 20.0 The above data set indicates that an Ic of 2.6, or greater, would not include potentially liquefiable soils. Therefore, the data indicates that the usual divider Ic of 2.6 applies to this site. The context of liquefaction potential for the silt soils is complemented by evaluating the corrected shear wave velocity and comparing to the liquefaction vs. non-liquefaction data base by Andrus and Stokoe 2000 (Idriss and Boulanger 2008). Seismic shear wave velocity measurements are available for CPTs 01 and 02 as shown in the Figure below. A G I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon Shear Wow Velocity,Vs(m/sec) 100 150 200 250 300 350 0 0g10• —o—CAr-01, ur Vet 20 �Cpt-02.Measasu Vi Val —Req Val 30 ao 50 60 For ease of reference, the Andrus and Stokoe 2000 (Idriss and Boulanger 2008) data set for liquefaction vs. non-liquefaction case histories is reproduced below. 06 AntLu.and Stokoe 12000) • Uncemented Holocene soils. Average V0,&a,,,values. • • MSF&r,by Idnss(19991 • 35 20<5 Fmes CRR curves are for • Content 1%) • M=75.n',w=1 atm. I U 04 ` • •• a.I t • t I O • • •G 0 .�.. • iv • r t* '..F.� o 0 2 — - Fines • • ■ U L NL Content •■a ■/7 ■ <5% •a a "- / • 4. 6-34% elk. i / • ?35% !3 • u L.-liquefaction - NL=nonitq �n�r 9 0 .!! 0 100 200 300 Corrected shear wave velocity. Vc, (m/s) The data base indicates that there are no cases involving liquefaction when silty sands (fines >35%) exceed a corrected shear wave velocity (Vs1) of 180m/sec. Shear wave velocity, Vs1, values at the Tigard site indicate that in all measured cases, the corrected shear wave velocity exceeds 180 m/sec below a depth of 25-30ft bgs. Accounting for some transitional material, on gAGI Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon the basis of shear wave velocity measurements, we considered liquefaction potential below 35ft to be low and not contributing to significant liquefaction settlements. b. AGI performed 27 CPT exploration soundings throughout the areas of concern. PDF output files as well as data files are included in Appendix F. Following a calibration for soil that may be deemed potentially non-liquefiable based on laboratory tests data and supplemental shear wave velocity test data, each of the pre-improvement CPTs was evaluated using the commercially available software program CLiq V1.7 (latest version). Four seismic settlement methods were used and given the nature of soils (silts and highly silty sands) it was deemed appropriate to use an average of the 4 methods to evaluate compliance against specifications. For brevity, we are submitting attached under Appendix F, the Cliq output files for the NCEER Robertson (1997. 1998) method. Calculation of liquefaction settlement for each of the CPTs, using the 4 methods mentioned, with an lc "flag" at 2.60 and a limited depth of 35 ft, indicates that pre- improvement settlements are primarily in the 1-3.5 inch range, with the exception of the area surrounding CPT AGI-17 (See Appendix F). c. The above calculations indicate that the area on, and around, CPT AGI-17 exceed allowable seismic settlement requirements while remaining areas are within compliance. Installation of stone columns ground improvement is therefore tailored to mitigating the area surrounding AGI-17. Reduction in liquefaction settlements by means introduction of the stone column at 10ft regular squared grid using a nominal 3ft diameter column provides a coverage of 7.1%. Using Baez, 1995 methods the shears tress redistribution with a stress concentration of 2.7 would effectively reduce the cyclic stress within the soil to a factor, Kg, of 0.78, or 22% reduction. The liquefaction analyses are then repeated with a lower pga to account for the presence of the stone columns. Reduction of seismic settlement follows similar principles as that for static stress distribution, that is to say, as the ground liquefies and pore pressure begin to dissipate distribution of the vertical load will be concentrated in the columns because they are stiffer than the surrounding ground. To that end, improvements can be approximated by following Priebe 1995 and 1976 guidelines. Reduction of seismic settlement of silt soils using reinforcement has been demonstrated via centrifuge test (Adalier et al 2003). For the given area replacement ratio, the seismic improvement factor is calculated at 1.4. AGI-17 also indicates the presence of slightly cleaner sands where some changes in tip resistance might be expected. Therefore, after shear stress distribution, partial improvement, and vertical settlement reinforcement we calculate with a stone column to a 25 ft depth, the post-improvement liquefaction settlement estimates at AGI-17 is on the order 3.62 inches (average of 4 settlement methods). As previously noted, the boundaries of the Stone Column treatment area is shown in the attached shop drawing (Appendix A). Our evaluation of differential settlements including the partial stone column area and non-stone columns areas indicate that differential settlements would be within allowable 2inch in 40ft. In particular around the areas of treatment and no- treatment the following differential settlements are calculated: SAG I Ground Improvement Design and Construction July 26.2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard.Oregon AGI-17 Post 3.62 in Differential Settlement Estimates: _ Differential Diff over From To Distance Settl(in) 40' AGI-17 AGI-12 113 2.55 0.90 AGI-17 CPT-1 68 0.27 0.16 AGI-17 AGI-13 113 2.05 0.72 AGI-17 AGI-16 80 1.60 0.80 AGI-17 AGI-18 80 1.72 0.86 AGI-17 AGI-21 113 0.32 0.11 AGI-17 AGI-22 80 1.77 0.89 The procedure evaluates the estimated liquefaction settlement within non-stone column areas and compares it to the estimated settlement within stone column areas, or alternatively within non-stone column areas only. For areas other than those surrounding AGI-17 the Tables included in Appendix F illustrate the calculation of differential settlement elsewhere. This includes transition areas between stone columns and non-stone columns. As indicated in the matrix of calculations, in all cases the differential settlement would meet the allowable seismic settlement of 2 inches or less over 40ft. Regarding differential static settlement between areas of footings supported on stone columns and slab areas in non-stone columns, the slab settlement will be controlled by the preload program with total remaining settlement at less than 1 inch. As noted in our static settlement analysis included in Appendix C of this submittal, the post improvement static settlement for footing locations would be less than 1-inch. Therefore, even at the extreme cases the differential settlements would be within the allowable 0.96 inches over 40ft. In our opinion, no single seismic settlement method is robust enough or has enough verified track record in silt soils, to stand out as a preferred method with the most reliability. As such, AGI has utilized a statistical basis consisting of the average of 4 seismic settlement calculation methods. In comparison to the other 3 methods, the Idriss and Boulanger method appears as an outlier with none of the other methods indicating that the total settlement exceeds 4 inches. As such, we believe the probability of exceeding is low and an averaging basis is an adequate for evaluation of settlements. d. With the exception of a few cleaner layers at AGI-17, given that the majority of soils have fines contents in excess of 20%, together with a design basis that relies on area replacement ratios and depth of improvement, it is our opinion that the CPTs are unlikely to show significant changes in tip resistance. Nonetheless, the required CPTs will be conducted and evaluated for measured changes and review against design assumptions within the area treated with Stone Columns. Other areas not receiving stone column installation will not be altered and thus the extensive supplemental AGI CPT program performed prior to installations will serve as the verification testing program required by the specifications. A G I Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935—Tigard,Oregon 5. QUALITY ASSURANCE AND QUALITY CONTROL Stone Columns Quality control is performed to ensure the stone columns are built according to the plans and specifications. As part of our quality control procedures we will monitor and record the following information for every column: • Footing location and stone column number • Pre-augered depth • Unusual soil conditions • Stone column depth • Tip and top elevation of stone columns • Average lift thickness • Average energy usage • Volume of aggregate used in each stone column • Average column diameter • Any unusual conditions encountered • Rig number and operator Average diameter of the column is calculated based on the stone volume utilized for the construction for that column. The volume of rock used is measured based on the design capacity of the loader bucket. Stone backfill to be used in the stone columns shall consist of hard, durable, clean, crushed rock or concrete. Specifications for the stone column backfill material are included in Appendix G. The depth of the column is measured using the markings on the side of the vibroflot follower tube. All this information will be compiled on a log sheet for each stone column. These log sheets will be reviewed by AGI's project manager on a daily basis and submitted to the owner's representative by the end of the following day after construction of the column. Acceptance of the stone column work will be based on the results of Cone Penetration Tests (CPT'S)which will be performed approximately one week after the stone columns have been installed. Seismic settlement analysis of the CPT data will be performed based on the procedures described herein. Wick Drains The wick drain quality control will be completed by monitoring the settlements attained during the 5 weeks of the surcharge program by installing settlement plates and surveying them twice a week. The surcharge program consists of a 2-foot fill placed above FFE for a minimum of 5 weeks. In a similar manner to the quality control for stone columns, we will record the following information for every wick drain: • Wick drain number • Pre-augered depth • Unusual soil conditions • Wick drain depth • Rig number and operator AGI Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon Included in Appendix H are AGI contractor qualifications for stone columns and wick drain projects completed in the past five years as well as resumes for the project's Senior Project Manager, Project Manager and the Superintendent. 6. CONCLUDING REMARKS This ground improvement design is submitted to address the geotechnical concerns regarding the construction of the proposed main building pad and the outlot building pads. The design uses vibro-stone column at all spread footing locations and in a limited area within the main building pad that showed excessive liquefaction settlement after an extensive investigation with 27 CPTs. Other areas requiring static settlement improvement are being address by means of wick drains and a preload program. Stone columns will be installed in the top 20 feet under building footings to reduce static settlement, and increase the bearing capacity of the in-situ soils. In the limited area within the main building subject to excessive liquefaction settlement the stone columns would be installed to a 25ft depth. Wick Drains will be installed in the top 20 feet under building slab areas to reduce the static settlement anticipated due to the placement of fill required to achieve FFE. The combination of ground improvement technologies has been designed to meet the project geotechnical acceptance criteria at the proposed main building pad and the outlot building pads. This ground improvement design is based on pre-improvement settlement estimates determined by soil parameters provided by Terracon in their geotechnical report. The layout of our ground improvement program is presented in AGI's drawing No 714177-01 included in Appendix A. The layout consists of nominal 3 ft diameter stone columns on a typical spacing of 10ft center to center square grid pattern under the areas required to reduce the seismic settlement to less than 4 inches. Stone columns consisting of 3ft diameter columns will also be installed under the building foundations to achieve the require area replacement needed to satisfy the design requirements. The wick drain layout consist of a typical spacing of 6ft center to center triangular grid pattern in areas where up to 5 feet of fill are required to meet the FFE and a typical spacing of 5ft center to center triangular grid pattern in areas where more than 5 feet of fill are required to achieve FFE. Areas where stone columns are installed will be re-tested with a CPT program in accordance with the specifications. Following the completion of the ground improvement installation, the upper soils will become loose and "fluffed". In accordance with the specifications, the GC is to re-instate the disturbed depth (upper 1 to 2 feet of the profile) in accordance with the specification requirements for Engineered Fill. The conclusions and recommendations presented in this design are based on the geotechnical characterization and soil parameters recommended by Terracon (geotechnical engineers of record), as well as load requirements indicated in the project drawings and the Specifications Section 02360. This design was conducted in a manner consistent with the level of care and skill ordinarily exercised by members of the geotechnical engineering profession currently practicing under similar conditions and in the same locality. No warranty is made or implied. AGI Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon We appreciate your interest in our services. Please contact the undersigned with any questions regarding this document. Sincerely, A?,ED PROFFSs �' NEF iG, cr �80300PE9 y� •-1 er. qN IVAN el" Juan I. Baez, Ph.D., P.E. Raul Verduzco, P.E., LEED AP Oregon License No 80300PE Design-Build Staff Engineer Chief Engineer AGI Ground Improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935—Tigard,Oregon REFERENCES: Baez J.I. and G.R. Martin (1993) "Advances in the Design of Vibro Systems for the Improvement of Liquefaction Resistance," Symposium of Ground Improvement, Vancouver Geotechnical Society,Vancouver,B.C. Baez J.I. (1995) "A Design Model for the Reduction of Soil Liquefaction by Vibro-Stone Columns,"Ph.D.Dissertation,University of Southern California. Barron, R.A. (1948), "Consolidation of Fine-Grained Soils by Drain Wells," Trans ASCE, 113, 718-742. Reprinted in A History of Progress, Vol. 1,pp. 324-348,2003 (ASCE: Reston, VA). Federal Highway Administration (1999) "Ground Improvement Technical Summaries, Volume II" Demonstration Project 116.Publication No.FHWA-SA-98086. Priebe, H.J. (1995) "The design of Vibro Replacement," Ground Engineering, London, December, 1995. Tokimatsu, K., and H.B. Seed (1984) "Simplified Procedures for the Evaluation of Settlements in Clean Sands," Report No. UCB/GT-84/16, Earthquake Engineering Research Center,University of California,Berkeley. Youd, T.L and I.M. Idriss (1997) "Proceedings of the NCEER Workshop on Evaluation of Liquefaction Resistance of Soils,"NCEER Technical Publication 97-0022. MAGI Ground improvement Design and Construction July 26,2013 Submittal 001,Rev 2 Wal-Mart#5935-Tigard,Oregon APPENDIX A AGI • REVISIONS • REV I DESORPTION I DATE I MYRDNED ............... ................... ......................... ......................................................................... ......................................................................... ................................................................................. e•�•••e•e a••e•o•o•e•e 0 • • • • - - • ' - - - O .R .':�0::. :. .:'.'?.'.':.'.'..':.'D.::.':.::.':.'D.'.'.'::..b".V':SS:.O'.4'.V'.V':BSD'.'A..'..:.,.•......•'.' WIN :::' ':':'::............................................ Z RETAIL BUILDING 1 i::::.::.:.: ::.:.: :.:..:'''''':': :....:.:.::::::: ;' :':.:.:;::::::::::::: : SCALE I•.20'-O. \I •. .....................................................................................•a•.;• •a •.;;,a••••• v..•v-4•.. ..v v:d4.. - -••-•"RiPP.•-•o vvrrvvvr rvrJVD• •. • . c O .. ...... .... ....... . ... ................ . .. •.A... ..•••n••••p6••••p...•0.•..•.A.•p6••p• _ NORTH ••q•.•6•.•.•.••.•.•.•.•.•.•.•.•.•.•••••••••••••. OMAIN STORE PAD 1 ;.o..... ........... .......:. SCYL 1 .30-O. AO NOTES. I> • BAY RAP IS DRANK FILE 00545 TO BE RROTALLE BY E4 M ARE 3.TN A • •051 DAMNS THE S A COLUMNS TO B[NSTA)LSE TN ACCORDANCE RTH AO'•ON THE NIL-LOAD M GROUND AND SUBMITTAL DATED 0 j=6,1013. • ••66••66••. . .• • • 6666•• PLATY BY OTHERS A ON D LY T'ASIVE ITIL SETTLEMENT PRE-LOAD A AS SHORN q R A 010 LOAD IN qRO-LAD IS EITASCPUN D TT1.E THE L TES SHA PlETES SHALL BB DOERS..ON BY K DIS BA IIY 1NIE ELC ' ORATES 10 T ESi(WR 10 A AYSY EBE WB THE E ETT MENT L NPLETE. IS REACHED ONCE TIM PRE-LOAD IS ESTABLISHED SETTLEMENT PLATES SHALL BE SURVEYED.BY OTHERS. ON K DAILY BASS PR1 TI.E FIRST TIC• IMO TOES(WRY TWO DAYS T VANES UNTIL CENTEME 11 IS LACEDE E • THE•4/154 ESTIMATED TOTAL SEEKS PAST VARIES q ID M 1391 02 TILL PLACED REPINED TO AND REACH THE RESEED NADIR ELEVATION AND AHE AOOTTANAL RR D ED TO O FOR A. LYSSCOTE THE OV_L PRIOR TO REMOVAL.OVNiAOED FM [AL A E DRAT A 5 REEKS PAST ERE LOADE ID T OT RSI A 000554 4 T E POOL AND 01[ lot 0(TNL PLATES SURKO 11 MT0 SHALL H LL1 BR AT E AO TA SF(2 ALT AD)AP•ROVA•101 0AYSI TO • PAL IC DRAIN AREAS SHALL BE MAROADED(BY OTHERS),AS UNTIL SE 04 OI PROJECT RUNS O D NET PPTOVAL P FROM AGO.IME CE A D SHALL K Or LEAST 1b PY(2 n MN)rq A ANNUM DURATION q 5 WEEKS PAST ME HORIZONTAL ROLM STR T1 REEK AID 011 EVERYV010(0 ROW AS O IIMOL THEIDRASN S 050 00TE 100 THE OUND•AD OR OLO NI[ N AND TO • D.B STOP qA/LAID OUT NET OTHER ROW AS SHOWN ON M[DRAWINGS WO NAKED TO THE WOUND ANO/q COVERED NTH SANG TO YWRC M PLACE ALL VERTICAL NCR DRAINS TO RE CONNECTED r0 STRIP NORTH MAIM IN NA E C MA/OR STAPLING THE MM TOGETHER AS T SHOWN INSTALLATION M TON MERMG R NTT_N5215 • AOUwNC MC TN THE WON RI THE GROUND NESTS FOR SCARLEDTgL ENE UPPER SODS 00 N SPE LOOSE AY ANO SECTION 0"NUNED" M WRFR T TO 1 ES SHALL ERE NNICDE PUCK Y FURBED ED ONO OSE RE-COMPACTED IN O RETAIL BUILDING 2 •RE-ESTMKE RO ERE SRECMHA AA RE Y THEOTH[q CNE GEED 1 AT C OCCONRONCC SIBL SFORIOCAOq 011001.10.EHC y0RANS P00/ BE P TORT D OI I SIRE DISTURBED D.ONO LOOSE SORT TO RE-ESTABLISH HIE TTII[RIIM SUBMOM•BY THE 01w[RS. NE 155 AND OR ICE HORIZONTAL IS RESPONSIBLE W 0 FOR PROTECTION CALL BE IA NE 0LT REPORTED TE GRANS AN D/011 GENERAL NER L CON TR C$TRIP MANS WRMG M[R[-[STOpUSITY[MT Of SCALt T•.p'-0' THE OWEN/SUERTICAL DAMAGE TO THE KERnOA RCN DRAINS AND/OR THE HORIZONTAL STRR DRAINS SHAD BE INOEOITLY REPORTED TO AO. THE GENERAL CDNTRACTOR 5 RCSPONOBLE FOR TIRE RESTORATION AND REPAIR Of ALL VERTICAL Mq MANS AND/OR HORIZONTAL STRIP DRAINS DAMAGED WRING TIRE RE-EST■BLISHMENT OF THE ON'[Nw SUBMAOE• LENGENDS O STONE COLUMNS FOR BUILDING POUNDATIONS,20 ALT DEEP OP O STONE COLUMNS TOR UoUEEACnq YTICADON,TO ALT SPACING RECTANGULAR PATTERN,25 ALT DEEP M ▪ RICK DRAM,5 ET SPACING TRMNGUW PATTERN.10 ALT DEEP TYR O PROPOM. *AMP ADV ANGlD Dan REV ❑CM REMCR AND COMMENT ENGINEERED STRUCTURES.INC. NCR DRAIN,6 FT SPACING TRIANGULAR PATTERN,10 FT DEEP TYP. ' �l I 6FOSOlYCIONS Inc.01/ZE/YOi] 0 _ •SAW TOR WAR N& TIRE: 'TO 1000000 ROOD.PLATE 106 DRC NO HONIORK STRIP DRAM,MP. ' ❑RFSIIB 0[q APPRO/A GROUND IMPROVEMENT PLAN LAKE FOREST CALIFORNIA NM TTA1)T.O-01 0 551E TOR c■AwADI.TNN P 11101 OO6.RD00 •0101 T664001 OLMS fNS REV I DESCWn00 I WtE -7-0° 7:J'.' :.'J!.l1.:,____ ••••••••••••••• ::5:• «.«.w^7..........04.1,1.4.#4,04, 7 ?M •NNNNNb^ab.^aN^. a^a^.A MN".'.'.J". g .'J 111.'.'.: ::.'.'.:O.'l.'.:�:.'.'.'':.'.::' ar i■r ///IIIIIIIe'MSS //I//I//II%///// r III/////MIDI/// i IMMIMMMM/%rM M I/III / I/III//I WD II//m. i �� 1 :KW,:glIgiitil sii6altatarimmizz7r762;24:524gt 1 "i""":43Z.:45:4k*a*E4641M&A,43iii::433imt NDRM O RETAIL B-UD ILDING 1 ! 2 EO �♦ srxc,• \I .f::_47;72:53%3:44:164:74taammtrmscrarmtevigy .:kt::"*jigftA:';:::L:;:flrkkgtgSkqtft:rg=iGzi:e::_::.:::::6:;fg:tv;:1 rr a. ... ----- a i a. iii! iii a O MAIN STORE PAD .:i iii u / .. AO NOBS . .0 MAO R 1.lOtf Ott T ID P00-L D 401!!II Cl ON Llti.SDIi NDIIIN SEE AOpnpµwp DRUM•xD nRE-low NOBS aN AO DR•IND NO O RETAIL BUILDING 2 SCUL,..SD'-0• IENQRO0 Q NKx dMN.5 n SNKND,RRND,K•R 007TC0,3o rt DEEP m. Q RKic OIMN.2 n:::T.710(0RAR ponop•ED rt DEEP m. NONZpRK SDRP . ` '1;1 E011 IRMEP Uq CONNDD SNP ENGN000(0 STRUCTURES INC. AG I ADVANCID D•/ - 5UBIM Epl MN,NDAI GEOSOIO,lON3 M. Or/36/30,3 0 � D.�NO. •," ❑ CC"""" d-NICK pEUN LAVOUT PUIiF Si.0 F(3ME t,•,»-a-Ol 3 or E REVISIONS REV I DESCRIPTION I DATE I APPROVED 0 4 p®® p ® o Q o 0 o Q ------ ' I ✓� a 1 I B -- i�Fq t • all } F _ L .11-mat- ti• -"1 e, yy p m m m o 0 0 o m m _ .tr_ ZS' Arca: tbd air lae II A riTtr 0 Ai AA avilloasta ti,4 P i - J I I ' • ' 0 �.. .� !A 1 mamm nmmm +a m. w . , o NDREN.. az T . fitly m..a +eP l — ��1 O RETAIL BUILDING 1 Ik R"s:. ..�:�5 Z t BCE I•.20'-D \/ W 3 ' p A a 204ey v s a _ i, � R fm P:: o- ;wr m w3N !m mA a� ..x...� i .1.. . . a .awlesn a 1 . _O rte. 7, Rirw, r EVAAggle■tt , ; 0 r WEIN -,:r. �O I I i I I I ( ',, I IM o o v v m v v m o yyn„ 1 !` i ." t. o e a 0 0 o ` b o o / NORTH a l --. ..`21� 'i -- .144, O MAIN STORE PAD _ 1N / I , d, I' 1 • / 01 3 v T. II --- "'`il1k ;m r 1,,, 1 ' 'k. II, I y: 1 ^E .,0..,•._$,,; j .'14 0 9 ACT NOTES: • BASE MAP FOR THE MAN STORE PAD IS FOUNDATION PLAN DRIVING 51 NORM • BAST:MAP FOR THE RETAIL BUILDING PADS 1 AND 2 IS FOUNDATON RAN DRAPING 52.01 • SEE ADDITIONAL NOTES w Itl DRAPING NO)14177-tl-DI O RETAIL BUILDING 2 SCNE r ro'_D. Era LENGENDS: O STONE COLUMNS FOR BUILDING FOUNDATIONS.20 FT DEEP TYP. O STONE COLUMNS FOR LIQUEFACTION MITGATON.10 FT SPACING RECTANGULAR PATTERN.25 FT DEEP TIP. �� . DPAOPOYL PENT: AGE DALE REV ENGINEERED S7RUCNRES.INC. EV_ ADVANCED ��I D FOR RENEW AND CONEM GEOSOlUT1OMS Ine.D)/2B/10/J 0 - i.'� �SDBMR FOR APPRD.A RILE. TS ORCHARDROAO.SUITE IOB DWG NO. _-fir ORESUBMIT FOR APPROVA p_STONE COLUMN LAYOUT LAKE FOREST.CMSORNIAY2RDo D ISSUE FOR CONSTRUCTION P(JTOIT79.001 EA000 F(J10)TO001 714177-GI-DS