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Home My WebLink AboutParcel Map 30180 Geotechnical Investigation (Mar.18,2003) I I I I I I i I I I I I I I I I I I I I KLEIN FELDER kq An employee owned company March 18, 2003 Project No. 25423 Mr. Brook Morris Rainbow Canyon Development, LLC c/o Prism Realty Corporation 151 Kalmus Drive, Suite M-2 Costa Mesa, California 92626 Subject: Geotechnical Investigation Proposed Rainbow Canyon Sbopping Center SEC and SWC State Highway 79 and Pechanga Parkway Temecula, California Dear Mr. Morris: Kleinfelder, Inc. is pleased to present this report of geotechnical investigation performed for the proposed Rainbow Canyon Shopping Center. The site is located south of State Highway 79, and on the east and west sides of Pechanga Parkway, Temecula, California. Pertinent data from a prior study conducted by EnGEN Corporation are discussed in this report. The results of our current geotechnical investigation, and our updated conclusions and recommendations for geotechnical design of the project, are presented in the attached report. A summary of the primary geotechnical considerations related to the development of the site is presented as an Executive Summary in the beginning of the report. The conclusions and recommendations presented in this report are subject to the limitations presented in Section 7. We appreciate the opportunity of providing geotechnical engineering services to you on this project. If you should have any questions or require additional information, please contact us. Respectfully submitted, KLEINFELDER, INC /;2:;;07/:'2.< . . ~/ '," '-'.h,_".,,:.,'''' ".',Y.:',-, /d//:' /"<:>~?l j. f;i~~:::>\ A' /Ji\7?/-!i3j~:;~:G ,o~(;~~.~i::~;'.L.. . ;..du..1i.j L./ l~\ B:;"z7;;'~'A F~: t.,/ J / \{~~1;:~;(>/' Timothy Slegers, P.E. ,,":c':-O> r:(\::',>\.. Project Engineer ~~,;:~:': .. cc: John S. Lohman / Kleinfelder 25423/DBA3R041 Copyright 2003, Kleinfelder, Jne l<~EI)\.:FELD::R Page ii of iv March 18, 2003 \ iJcD \'a!ie') \:is:;::. O;-iV2, ';u:te -::;C, :'12;-:)2;1:: ElZiL C,';'" 9- -;:3- G-;.:" ?::::.~.' :._-'- ~&~, 'C--'-. (S1C':', I I I I I I ; I I I I I I I I I I I I I , k.q KI EINFELDER TABLE OF CONTEl','TS Section Pa2e EXECUTIVE SUMMARY .........................................................,.......................................... ES-I I INTRODUCTION..............................................................................................................1 l.l PURPOSE AND SCOPE.........................................................................................1 1.2 PROPOSED PROJECT ...........................................................................................3 2 BACKGROUND ................................................................................................................4 3 SITE AND SUBSURFACE CONDITIONS ....................................................................5 3.1 SITE DESCRIPTION ............................................... ...............................................5 3.2 SUBSURFACE SOIL CONDITIONS ....................................................................5 3.2.1 General..... ........... ......... ............... .................. .......... ................. ....................5 3.2.2 Artificial Fill ...... ......... ....... ........ ................ ............ ...... ........... .... ............ .....6 3 .2.3 Native Soils ................ ...... ..... ......... ............ ..... .............................................6 3.3 SURFACE WATER CONDITIONS.......................................................................6 3.4 GROUNDWATER CONDITIONS .........................................................................7 4 GEOLOGIC CONDITIONS ............................................................................................8 4.1 REGIONAL GEOLOGY ........................................................................ .................8 4.2 GEOLOGIC HAZARDS ...........................:.............................................................8 4.3 FAULTING AND SEISMICITY ............................................................................9 4.4 NEAR-SOURCE SEISMIC ZONE .......................................................................1 I 5 CONCLUSIONS AND RECOMMENDA TIONS.........................................................12 5.1 GENERAL ............................................................................................. ................12 5.2 SEISMIC DESIGN CONSIDERATIONS ......................................:.....................14 5.2.1 Ground Shaking .........................................................................................14 5.2.2 Liquefaction. ............. ..... ......... ...... ....... .............. ....... .... ..... ............ ........ ....15 5.2.3 Seismically-Induced Settlement and Lateral Spreading ............................16 5.2.4 Other Geologic Seismic Considerations ....................................................16 5.3 MITIGATION OF LIQUEFACTION POTENTIAL ............................................17 5.4 EARTHWORK ..................................................... .................................................17 5.4.1 Site Preparation...................................... ....................................................17 5.4.2 Materials for Fill........................................................................................19 5.4.3 Excavation Conditions .... ...... .................... ........... ................................... ...20 5.4.4 Collapsible Soils... ..... .... ........... ..... ........ ................ ............. ........... ........... .20 5.4.5 Excavations and Temporary Slopes...........................................................20 5.4.6 Trench Backfill .......................................................................... ................21 5.5 FILL SLOPE CONSTRUCTION ..........................................................................21 5.6 DRAINAGE AND LANDSCAPING ................................................... .................22 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc March 18,'2003 Page iii of iv 1,,- I I I I I I I I I I I I I I I I I I I , It-q KLEINFELDER 5. 7 FOUNDATIONS ...................................................................................................23 5.7.1 Allowable Bearing Pressures .............,.......................................................23 5.7.2 Estimated Settlements................... ..... ..... ... ....... ................ ............... ......... .24 5.7.3 Lateral Resistance .................................................................................:....24 5.7.4 Slope Setbacks ..... ............ ...... ..... ............... ......... ............ ...... ........... ........ ..25 5.7.5 Construction/Design Considerations .........................................................25 5.8 RETAINING WALLS ............................................................................. ..............25 5.9 CONCRETE SLABS SUPPORTED-ON-GRADE...............................................26 5.10 PAVEMENT DESIGN .....................................................,...............................:....27 5.11 EXPANSION POTENTIAL..................................................................................29 5.12 CORROSIVITY ............................. ........... ........ ..... .... ......... ..... ................. ...... .......30 6 ADDITIONAL SERVICES .......,....................................................................................31 6.1 PLANS AND SPECIFICATIONS REVIEW........................................................31 6.2 CONSTRUCTION OBSERVATION AND TESTING ........................................31 7 LIMITATIONS ................................................................................................................32 8 REFERENCES.................................................................................................................33 PLATES Plate 1 - Site Location Map Plate 2 - Plot Plan . APPENDICES Appendix A - Exploratory Borings Appendix B - Laboratory Testing Appendix C - Calculations Appendix D - ASFE Insert Appendix E - Application for Authorization to Use 25423/DBA3R041 Copyright 2003, Kleinfelder, Ioe Page iv of iv March 18, 2003 ?? I I I I I I I I I I I I I I I I I I I It..~ KLEINFELDER EXECUTIVE SUMMARY Kleinfelder, Inc. (Kleinfelder) was retained by Raiobow Canyon Development, LLC to conduct a geotechnical investigation for the proposed Rainbow Canyon Shopping Center in Temecula, California. The site is located on the south side of State Highway 79, on both sides ofPechanga Parkway and extends to Jedediah Smith Road in the City of Temecula, Califomia. The project consists of a retail development with 13 proposed building pads, ranging in size between 2,165 to 35,000 square feet in plan on a total area of approximately 13.17 acres. Current topography and proposed grades were not available for our review at the date of this report. EnGEN Corporation previously performed a geotechnical study of the site and conducted geotechnical observation and testing during rough grading performed in 2001 and 2002. The western portion of the property (east of Pechanga Parkway) was overexcavated to depths of approximately 1.5 to 5 feet below original grades. Additional engineered fill was placed to achieve the current grades which are approximately 6 to 8 feet above the original site elevations. Soils along the toe of slope at the south property line were removed to a depth of approximately ] 0 feet below original grade and recompacted. The portion of the site west of Pechanga Parkway was not graded at that time. Although EnGEN observed the removals of the pre-existing undocumented fill and surficial native soils, observed the compaction of the replacement engineered fill. They still recommended to overexcavate the existing fill and native soils to depths of 10 to 15 feet below original grade to provide suitable building pads. Their recommendations for foundation design included a grid of grade beams in order to reduce the adverse effects of potential liquefaction. Kleinfelder drilled a total of]5 hollow-stem auger borings (B-1 through B-15) at the project site in January and March 2003 to depths ranging from approximately 6Yz feet to 5] Yz feet below existing grade. Fill soils, up to approximately 17 feet below current grade, were encountered in Borings B-2 through B-15 excavated for this report. Boring B-1 encountered fill toa depth of approximately 27 feet terminating at a 24-inch diameter sewer line maintained by Eastern Munic.ipal Water 25423/DBA3R041 Copyright 2003, Kleinfelder, Iue ES-I March 18, 2003 1\ I I I , I I , I I I I I I I I I I I I I k~ K LEI N FE L D E R District. This depth offill appears to be local due to the buried utility. The location of the boring was cleared for drilling by a representative of EMWD prior to excavation. The fill encountered consisted of engineered fill that was placed during grading in 2002 under the observation of EnGEN Corporation. The upper natural soils, in the eastern portion of the site that are covered by 3 feet or less of artificial fill, generally consist of medium dense to dense silty sands and sands. The upper native soils are considered to be moisture sensitive, meaning that the soils potentially become significantly weaker and more compressible when wet or saturated. The historical high depth to groundwater beneath the site appears to be within 10 feet below the existing ground surface (bgs). Based on our field exploration, laboratory testing and geotechnical analyses conducted for this study, it is our opinion that the following geotechnical related issues must be considered during design and construction of the proposed development. . Provided that the recommendations presented in the geotechnical report are incorporated into design and construction, it is our opinion that the proposed buildings may be supported on shallow spread foundations underlain by engineered filL . No remedial grading has been performed in the area west of Pechanga Parkway following the February 2000 geotechnical investigation by EnGEN. Boring logs indicate existing undocumented fill to depths up to 6.5 feet below existing grade and recent alluvium to a depth of approximately 20 feet below existing grade. Site preparation in this area should include overexcavation and recompaction of the existing fill soils. Where shallow fill, less than 4 feet, or native soils are encountered at the surface, we recommend overexcavation and recompaction to a minimum of 4 feet below existing grades. . The upper 1 to 17 feet of the onsite soils consists of previously placed artificial fills. The depth of fill near B-I appears to be utility backfill. It is our opinion that the engineered fill soils placed at the site in 2000 and 2001 are generally considered suitable for support of the proposed buildings in the western portion of the site shO\\1l as Pads 3 through 5 (east of Pechanga Parkway). In the eastern portion of the site where grading has not occurred (includes Pads 9 through 11, Shops 1 and Major A) the upper 10 to 15 feet of existing native alluvial soils appear to be moderately collapsible when subject to saturation by water. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc ES-2 March 18, 2003 ? I I I I I I I I I I I I , I I I , I !I I I k~ KLEINFELDER Accordingly, in the eastern portion of the site, site grading within building pad areas should include overexcavation of the upper 5 to ] 0 feet of soils beneath the existing grades. Engineered fill soils intended to support the proposed structures should be compacted to a minimum of 90 percent relative compaction. The upper 5 feet of soil within the footprint of proposed structures should be compacted to at least 93 percent. Where proposed buildings are located only partially in the previously graded area (Pads 7, 8, and 9), the entire building footprint should also be uniformly overexcavated and the soils recompacted. . We understand that cleanout of the easterly channel adjacent to Jedediah Srnith Road prior to placement of fill was not conducted and that placement of fill in this area was not observed. . The site is not located within a State or County designated Fault Rupture Hazard Zone. The site is located within the 2-km Near Source Fault Zone of the Elsinore Fault zone. Due to the site's proximity to the Elsinore Fault zone, relatively large site accelerations approaching O.68g are anticipated, based on a 10% probability of exceed;mce in 50 years. . The site is located within a County of Riverside designated ground subsidence zone. The site's vicinity is reported to be susceptible to ground fissuring due to withdrawal of groundwater and large seasonal fluctuations in groundwater levels. . The southem portion of the site is listed within a 100-year flood hazard zone by FEMA (FEMA, 2003). The flood hazard has been mitigated by rough grading to an elevation above the 100-year flood elevations determined by FEMA (approximately 1008 ft.). The site is within the floodplain of Temeeula Creek and downstream from the Vail Lake dam, the site may be subject to inundation from this reservoir should it catastrophically fail or be overtopped by a seich. . The site is located within a County of Riverside designated liquefaction hazard zone, The current data from the current borings indicate that the central and eastern portions of the property are susceptible to liquefaction at depths of approximately 10 to 30 feet below the surface, which may result in seismically-induced settlement on the order of 3 to 5 inches. Differential seismic induced settlement on the order of approximately 1 inch over a horizontal distance of 50 feet may result. Manifestation of the liquefiable soils at the surface in the form of sand boils or fissures may occur. Liquefaction may also result in lateral spreading near the descending slope along the south edge of the site. 25423/DBA3R041 Copyright 2003, K1einfelder, Inc ES - 3 March 18,2003 Cp I I I I I I ; I I I I I I I I I I I I I k~ K LEI N FE L D E R The liquefaction potential appears to impact current building pads 6 through 11, Shops 1, and Major A. The effects of differential seismically-induced settlement on buildings may be reduced by placing engineered fill at a minimum of 93 percent relative compaction, using grade beams to tie all foundation elements together within the buildings, and/or by placing 2 to 3 layers of a geogrid product such as TENSAR within the engineered fill of the building pads at vertical intervals of approximately 3 feet. Lateral spreading (lateral movement of earth towards open face slopes during liquefaction at shallow depths) is difficult to mitigate. Lateral deformation on the order of inches and feet can occur under similar conditions. Overexcavation of the site soils below the toe of the slope adjacent to Temecula Creek may significantly reduce the potential impact on the site due to lateral spreading. Laboratory testing indicates that the onsite soils are considered moderately corrosive to buried metals and mildly corrosive to concrete. The-owner may wish to consider having a competent corrosion engineer retained to evaluate the corrosion potential of the site soils relative to the proposed improvements, recommend further testing as 'required, and provide specific corrosion mitigation methods appropriate for the project. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine ES-4 March 18,2003 '\ I I I I I I I I I I I I I I I I 'I I I k~ KLEIN FELDER 1 INTRODUCTION Kleinfelder, Inc. (Kleinfelder) was retained by Rainbow Canyon Development, LLC to conduct a geotechnical investigation for the proposed Rainbow Canyon Shopping Center in Temecula, California. Our services were performed in general accordance with our revised summary of scope and cost estimate dated December 9, 2002 that was accepted on December 19, 2002. Mr. Brook Morris of Prism Realty Corporation provided us with information about the project along with geotechnical reports prepared by others for the site and a proposed site plan for the project. The site is located on the south side of State Highway 79, on both sides of Pechanga Parkway, extending east to Jedediah Smith Road in the City of Temecula, California. The location of the site is shown on Plate I, Site Location Map. The proposed site layout is shown on Plate 2, Plot Plan, which uses the Site Plan provided by Nadel Architects, Inc., dated September 19, 2002 as a base map. Current topography and proposed grades were not available at the date of this report. EnGEN Corporation previously performed a geotechnical study of the site and provided results and conclusions in their reports dated February 3, 2000 and February 28, 2000. Observation of rough grading was summarized in their May 14, 2002 report. Background information regarding the investigation and subsequent grading is presented in Section 2 of this report. l.l PURPOSE AND SCOPE The purpose of this geotechnical investigation was to evaluate the subsurface soil conditions at the proposed site and provide design-level geotechnical recommendations for design and construction of the project. A description of the scope of work performed is presented below. Task 1 - Literature Review/Utility Clearance. We reviewed published and unpublished geologic literature in our files and the files of selected public agencies including publications prepared by the County of Riverside, California Division of Mines and Geology and the U.S. Geological Survey. We reviewed available appropriate seismic and faulting information including designated earthquake fault zones and our in-house database of faulting in the general site vicinity. We also reviewed the previous geotechnical reports for the project and the report of previous site grading by EnGEN Corporation. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc Page 1 of 34 March 18, 2003 ~ I I I I I I I I I I I I I I I I I I I k~ KLEINFELDER Prior to conducting the field investigation program. Each of our proposed boring locations was cleared for knOV>'ll existing utility lines and 'Nith the participating utility companies through Underground Service Alert (USA). During drilling of B-1, an existing sewer line maintained by EMWD was encountered. EMWD was contacted by Kleinfelder to report the event and EMWD acknowledged that they would repair the line at their expense since they cleared the boring location prior to being drilled. Task 2 - Field Exploration. A total of 15 hollow-stem auger borings (B-1 through B-15) were advanced in our current investigation at the project site to depths r,mging from approximately 6v, feet to 51 V, feet below existing grade. The locations of the current and previous borings are presented on Plate 2, Plot Plan. A Kleinfelder geologist supervised the field operations and logged the borings. Selected bulk, disturbed and relatively urldisturbed sainples were retrieved, sealed and transported to our laboratory for further evaluation. The number of blows necessary to drive a California-type sampler were recorded. A description of the field exploration and a Legend to the Logs of Borings is presented in Appendix A. Task 3 - Laboratory Testing. Laboratory testing was performed on representative relatively undisturbed and disturbed samples to substantiate field classifications and to provide engineering parameters for geotechnical design. Testing consisted of: . Moisture content and dry density . Grain size distribution - #200 wash sieve . Direct shear . Consolidation potential . Collapse potential . R-Value . Compaction Test . Preliminary Corrosivity Screening Tests The results of our laboratory testing are presented in Appendix B. Task 4 - Geotechnical Analyses. We evaluated the field and laboratory data in conjunction with the site plan and estimated building loads. We also evaluated potential foundation systems, lateral earth pressures, settlement, pavement design, and earthworks considerations. Potential 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc March 18,2003 C\ Page 2 of 34 I I I I I I I I I I I I I I I I I I I k~ KLEINFElDER geologic hazards were evaluated such as ground shaking, liquefaction potential, fault rupture hazard and seismically-induced settlement. Design recommendations DJr use with standard UBC (1997) seismic design were considered. Task 5 - Report Preparation. This report was prepared presenting our findings, conclusions and recommendations for earthwork and foundation engineering. Recommendations for foundation type(s), allowable bearing pressure, estimated settlement, passive resist,mce, lateral earth pressures for retaining structures, pavements, earthwork, and seismicity are presented. This report also contains a site map, logs of the borings and laboratory test results. 1.2 PROPOSED PROJECT Based on information provided by Prism Realty Corporation and plans for the development provided to us dated September 19, 2002, it is our understarlding that the project consists of a retail development with 13 proposed building pads, ranging in size between 2,165 to 35,000 square feet in plan on a total site area of approximately 13.17 acres. The site is divided into two parcels, A and B, with individual areas of 1.84 and 11.33 acres, respectively. Parcel A consists of the property west of Pechanga Parkway (Pads 1 and 2) and Parcel B consists of the property east of Pechanga Parkway extending to Jedediah Smith Road. The total building area will consist of over 100,000 square feet and the development ,,,,,ill include over 585 surface level parking stalls. Construction is anticipated to be masonry, wood frame, steel frame and/or concrete tilt-up buildings '""ith concrete slab on grade floors. We understand that no basement levels are planned for the buildings in the development. Detailed structural loads for all buildings on various pads are not available at this time. However, maximum colunm loads are anticipated to be approximately 120 to 160 kips for interior columns and approximately 40 kips for exterior columns. Continuous wall loads are anticipated to range between 2 to 6 kips per lineal foot. Slabs-an-grade are expected to support maximum floor loads of between 150 to 200 pounds per square foot. Site grading is anticipated to include cuts and fills up to approximately 2 to 5 feet. The western portion of the site east of Pechanga Parkway was previously graded as described in the referenced EnGEN Corporation report dated May 14, 2002. Details of the prior site grading are discussed in Section 2 of this report. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine Page 3 of 34 March 18, 2003 \0 I I I I I I I I I I I I I I I I I I I k.q KLEINFElDER 2 BACKGROUND EnGEN Corporation previously performed a geotechnical study of the site and submitted the results and conclusions in their report dated February 28, 2000. In the EnGEN (2000) report, they concluded that the existing soils were not considered suitable for support of structures and recommended that overexcavation of the existing soils should be performed to depths of IOta 15 feet below original grade. Site grading was performed in 2001 and 2002 and included shallow overexcavation in the western portion of the site east of Pechanga Parkway, as reported by EnGEN (2002). At- that time, building locations were unknown In general, the western portion of the property east of Pechanga Parkway was overexcavated to depths of 1.5 to 5 feet below original grades and to the limits shown on Plate 2. That portion of the site west ofPechanga Parkway was not graded at the time. Additional engineered fill was placed to achieve the current grades which are approximately 6 to 8 feet above the original site elevations. Soils along the slope at the south property line were removed to a depth of approximately IO feet below original grade and recompacted. The horizontal limits of the 10-foot removal extended from the toe of the fill embankment to approximately 25 to 30 feet inside the toe. Approximate limits are shown on Plate 2. According to EnGEN (2002), the maximum fill slope height is approximately 11 feet. We understand that cleanout of the easterly channel adjacent to Jedediah Smith Road prior to placement of fill was not conducted and that placement of fill in this area was neither observed nor tested by EnGEN. This area is noted on Plate 2. Although EnGEN observed the removals of the existing fill and surficial native soils and also observed the compaction of engineered fill, EnGEN maintained the original recommendations to overexcavate to a depths of IOta 15 feet below original grade. Their recommendations for foundation design included a grid of grade beams in order to reduce the adverse effects of potential liquefaction. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ioc Page 4 of34 March 18, 2003 ~ I I I I I I ; I , I I I I I I I I I I I I " '. k."I KlEINFElDER 3 SITE AND SUBSURFACE CONDITIONS 3.1 SITE DESCRIPTION The site of the proposed development is located south of State Highway 79, at the intersection with Pechanga Parkway in Temecula, California. The site is divided into two parcels with Parcel A (1.84 acres) on the west side ofPechanga Parkway, and Parcel B (11.33 acres) on the east side of Pechanga Parkway and extends east to Jedediah Smith Road. The location of the site is shown on Plate 2, Plot Plan. Parcel B was rough graded in 2001-2002 and'is currently vacant with some stockpiled soils. Based on EnGEN Corporation's geotechnical study report, the site was previously used by Eastern Municipal Water District for purposes associated with its water reclamation program. Structures associated with the Eastem Municipal Water Districts operations have been removed. Parcel A, west of Pechanga Parkway, appear to have approximately 3 to 6 feet of undocumented artificial fill at the surface. Parcel B east of Pechanga Parkway has documented engineered fill that is approximately 13 feet deep in the westem portion and shallows to a thin veneer in the eastern portion. TIle site is generally flat and covered with only minor shrub and grass vegetation. An existing sewer line easement traverses the westem portion of Parcel B, three natural gas easements traverse the westem half of Parcel B, and two Metropolitan Water District easements traverse the eastern portion of Parcel B. 3.2 SUBSURFACE SOIL CONDITIONS 3.2.1 General The following paragraphs summarIze the results of our field exploration. The boring logs presented in Appendix A should be reviewed for a more detailed description of the subsurface conditions at the locations explored. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ioe Page 5 of 34 March 18, 2003 \"V I I I I I i I I I I I ; I ; I I I I I I I I I I I o k~ KlEINFElDER 3.2.2 Artificial Fill Fill soils were encountered in the 15 borings excavated for this report (Boring B-1 - B-15) to depths of up to approximately 17 feet below current grade. Boring B-1 encountered fill to a depth of approximately 27 feet terminating at a 24-inch diameter sewer line maintained by Eastern Municipal Water District. The location of the boring was cleared for drilling by a representative of EMWD prior to excavation. The fill encountered consists of engineered fill that was placed during grading in 2002 under the observation of EnGEN Corporation. 3.2.3 Native Soils The upper natural soils, in the eastern portion of the site that are covered by 3 feet or less of artificial fill, generally consist of medium dense to dense silty sands and sands. The in-situ densities tested varied from approximately 83 to 121 pounds per cubic foot at moisture contents ranging from 2.0 to 30.3 percent. The upper native soils are considered to be moisture sensitive, meaning that the soils become significantly weaker and more compressible when wet or saturated. See Appendix A for a more detailed explanation of the field explonition and Appendix B for laboratory test results and methods. 3.3 SURFACE WATER CONDITIONS Surface water flow direction is to the south by sheet flow across the previously graded site into the adjacent unlined section of Temecula Creek. The southern portion of the site is within a I DO-year flood hazard zone listed as AE by FEMA (FEMA web site, 2003). The AE flood hazard zone indicates flood elevations of 1008 feet in the southeast portion of the site diminishing to elevation 1005 in the southwest portion of the site. The flood hazard has been mitigated by rough grading to an elevation above the 100-year flood elevations determined by FEMA (approximately 1008 feet). Due to the site's inland location, tsunamis are not considered a hazard to the site. The site is within the floodplain of Temecula Creek and downstream from the Vail Lake dam, the site may be subject to inundation from this reservoir should it catastrophically fail or be overtopped by a seich. 25423/DBA3R041 Copyright 2003, Kleinfelder, !nc Page 6 of 34 March 18,2003 \'?:> I I I I I I , I I I I I I I I I I I I I .., .. k.~ KLEINFELDER 3.4 GROUNDWATER CONDITIONS Groundwater was encountered in boring B-12 at a depth of approximately 29 feet, but was not encountered in any of the other borings excavated to depths of approximately 50 feet. According to the State of Califomia (2003), the historical high depth to groundwater beneath the site appears to be within 10 feet below the ground surface (bgs), and seasonally at the ground surface (Kennedy, 1977). Since this information is from 1977, and the site has subsequently been graded with placement of up to 10 feet of additional fill, we conclude that historic high groundwater is estimated at 10 feet below current grade and the Kennedy, 1977 reference to ground surface is the pre-graded surface of 2000. Additionally, the groundwater flow direction beneath the site appears to be towards the west (USGS, 1990). Fluctuations of the groundwater level, localized zones of perched water, and soil moisture content should be anticipated during and following the rainy season. Irrigation of landscaped al'eas on or immediately adjacent to the site can also cause a fluctuation of local groundwater levels. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc Page 7 of 34 March 18,2003 \A. I I I I I I I I I I I I I I I I I I I 1..."1=1 KLEINFElDER 4 GEOLOGIC C01\'DITIONS 4.1 REGIONAL GEOLOGY The site is located near the southern end of the Temecula Valley, at the confluence of Wolf and. Pauba Valleys, within the Peninsular Ranges Geomorphic Province of California. The Temecula Valley is an approximately 1 mile wide, tectonically active graben valley bordered on either side by the Willard Fault on the west and Wildomar Fault on the east, both of which are major splays of the Elsinore Fault Zone (Shlemon, 1992). The Peninsula! Ranges are a northwest-southeast oriented complex of mountain ranges and valleys and are characterized by sub..unit blocks separated by similarly trending strike slip faults. The site is regionally mapped as underlain by surficial alluvial sediments of Holocene-age from both Wolf and Pauba Valleys, consisting of silt, sand and gravel derived from the local Pechanga and Temecula Creeks (USGS, 1966). Both undocumented fill and engineered fills (EnGEN, 2002) mantel the site on the order of 3 to 17 feet deep, and locally occur as utility line backfill to a depth of 25 to 27 feet below existing grade. According to prior work on site by others (EnGEN, 2000) the fills are underlain by the valley floor alluvium reported to extend to an approximate depth of 20 feet bgs. Underlying the Holocene alluvium is the Pleistocene non- marine sedimentary Pauba Formation. 4.2 GEOLOGIC HAZARDS The site is located in the Temecula / Wolf Valley area of Fiverside County, in an area with a potential hazard of ground fissures and the recently identified Wolf Valley Fault. Although the site is not located within a State of California designated Earthquake Fault Rupture Hazard Zone for active surface faulting (Hart and Bryant, 2000), it is closely located to Fault Rupture Hazard Zones for both the Wildomar Fault to the northeast and the Wolf Valley fault to the south. The Willard fault to the west of the site is currently unzoned. Since the site is located in a relatively flat area, we do not consider landslides or other forms of natural slope instability to represent a significant hazard to the project. The elevated inland location of the site is not situated near any impounded bodies of water; therefore, tsunamis are not considered a potential hazard to the project. Flow for seiches in the Vail Lake may be 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc March] 8, 2003 v5 Page 8 of34 I I I I I I I I I I I I I I I I I I I k~ KLEINFElDER considered a potential hazard to the project. Also the site is located within the Floodplain of Temecula Creek, downstream from the Vail Lake Dam and may be subject to inundation should this structure catastrophically fail. Additionally, the site is within a Liquefaction Hazard Zone as designated by the County of Riverside (1997). In our opinion, the most significant geologic hazard to the project is the potential for moderate to strong ground shaking resulting from earthquakes generated on the faults within the vicinity of the site. In the vicinity of the site, approximately 31 knovv1l active faults have been mapped within a 62-mile (100-kilometer) radius of the site. This is followed by lesser potentials for liquefaction, ground fissuring, or surface mpture from previously unknown faulting. 4.3 F AUL TING AND SEISMICITY We consider the most significant geologic hazard to the project to be the potential for moderate to strong seismic shaking that is likely to occur during the design life of the proposed project. The project site is located in the highly seismic Southern California region within the influence of several fault systems that are considered to be active or potentially active. An active fault is defined by the State of California as a "sufficiently active ,md well defined fault" that has exhibited surface displacement within the Holocene time (about the last 11,000 years). A potentially active fault is defined by the State as a fault with a history of movement within Pleistocene time (between 11,000 and 1.6 million years ago). These active and potentially active faults are capable of producing potentially damaging seismic shaking at the site. It is anticipated that the project site will periodically experience ground acceleration as the result of moderate to large magnitude earthquakes. Faults identified by the State as being either active or potentially active are not known to be present at the surface of the site. The site is not located within a State of California designated Earthquake Fault Rupture Hazard Zone for active surface faulting (Hart and Bryant, 2000). We have listed within Table I, Significant Faults, the known faults in the region that in our opinion, could significantly impact the site. 25423/DBA3R041 Copyright 2003, KJeinfelder, Inc Page 9 of34 March 18, 2003 \(p I I I I I , I I I I ; I. I i ; I I . I I I I I I I k.~ KLEINFELDER We have performed a computer-aided search of the known active and potentially active faults within a 62-mile (lOO-kilometer) radius of the site and researched available literature to assess the expected maximum magnitude earthquakes to be generated on each fault. Table 1 summarizes these parameters for 3 of the 31 known active and potentially active faults within the searched radius of the site that in our opinion may have the greatest impact upon the site. Selection of the faults was based on their proximity to the site and their potential to generate moderate to strong ground motion on the site. Table 1 was generated using, in part, the EQFAULT computer program (Blake, 2000), as modified using the fault parameters from DMG Open File Report 96-08 and the 1997 UBC fault maps (ICBO, 1998). This table does not identify the probability of reactivation or the onsite effects from earthquakes occurring on any of the other faults in the region. The site is located within the USGS 7'-'2' Temecula and Pechanga, California Quadrangles, at Latitude 33.47450N and Longitude 117.12560W, at approximately the 1,012 foot elevation (MSL). Table 1 Significant Fanlts Elsinore - Temecu1a segment 0.6 (0.4) San Jacinto - Anza segment 35.1 (21.8) Newport-Inglewood 44.1 (27.4) 'As defined by the !CBO (1998) and CDMG (OFR 96-08). 6.8 7.2 6.9 B B B A number of moderate to strong earthquakes have occurred in the vicinity of the project site in the past years. The parameters used by the EQSearch program (Blake, 2000) to define the limits of the historical earthquake search include geographical limits (within 100 km of the site), dates (1800 through 2000), and magnitude (magnitudes above M 4). A summary of the results of the historical search is presented below. Time period (1800 to 2000) Maximum Magnitude within 62.1 mi. (100 km) radius (12/16/1858) Approximate distance to nearest historical earthquake, > M4.0 Maximum Calculated Historic Site Acceleration during period Number of events exceeding magnitude 4 within the search area 201 years M7.0 3.6 miles 0.16g 626 25423/DBA3R041 Copyright 2003, Kleinfelder, Jne Page 10 of34 March 18, 2003 \'\ I I i I I I J I , ; I , I I I I I I I I I I I k.~ KLEINFELDER Under the current understanding of regional seismo-tectonics, the largest maximum magnitude event to impact the site may be generated by the Elsinore Fault (Temecula segment) having a moment magnitude ofM6.8. Utilizing the Bozorgina et al attenuation relationship in the FRISKSP program (Blake, 2000) indicates a 10% probability of exceedance in 50 years for an acceleration of 0.68g for alluvial sites within this area. The site is located in Seismic Zone 4 of the 1997 edition of the Uniform Building Code (UBC). Structures should be designed in accordance with the values and parameters given within the UBC. 4.4 NEAR-SOURCE SEISMIC ZONE In addition to the determination of fault activity, faults are also type classified as an A, B, or C for Near-Source Zone ground motion (Ca, Cv, Na and Nv) by both the State, and ICBO (in the UBC, Table 16-U), according to parameters of known slip rate, and maximum earthquake magnitude. A "Type A" seismic source fault has a magnitude b'Teater than or equal to 7.0 and slip rate greater than or equal to 5mm/yr. A "Type B" seismic source fault has a magnitude greater than or equal to 7.0 with a slip rate <5mm/yr.; or magnitude <7.0 with a slip rate >2mrn/yr.; or a magnitude greater than or equal to 6.5 with a slip rate <2mrn/yr. A 'Type C" seismic source fault has a magnitude M<6.5 and a slip rate less than or equal to 2mm/yr, or is unrated under the current knowledge. The site is located at 0.4 km (within the 2-km) Active Fault Near-Source (Seismic) Zone for the Elsinore Fault (Temecula Segment). The Elsinore Fault is a Type B fault as designated by the UBC (ICBO, 1998). Please note that the fault distances presented in Table I, Significant Faults, indicate the distance from the site to the nearest location where the fault trace is mapped at the ground surface. The Near Source Zone Map distances are based on the shortest distance from the site to the fault piane projection to the ground surface, from a depth of 10-km. In some cases the Near Source Zone Map distance may differ from the map distance shown in Table 1, because the site may be closer to or further from the fault plane projection than the surface trace of the fault. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc Page 11 of 34 March 18, 2003 \~ I I I I I I ; I I I I I I I I I I I I I k~ KLEINFELDER 5 CONCLUSIONS AND RECOMMENDATIONS 5.1 GENERAL Based on our field exploration, laboratory testing and geotecJmical analyses conducted for this study, it is our opinion that the following geotechnical related issues must be considered during design and construction of the proposed development. . Provided that the recommendations presented in the geotechnical report are incorporated into design and construction, it is our opinion that the proposed buildings may be supported on shallow spread foundations underlain by engineered fill. . No remedial grading has been performed in the area west of Pechanga Parkway following the February 2000 geotechnical investigation by EnGEN. Boring logs indicate existing undocumented fill to depths up to 6.5 feet below existing grade and alluvium to a depth of approximately 20 feet below existing grade. Site preparation in this area should include overexcavation and recompaction or the existing fill soils. Where shallow fill less than 4 feet or native soils are encountered at the surface, we reeommend overexeavation and recompaction to a minimum of 4 feet below existing grades. . The upper 1 to 17 feet of the onsite soils consists of previously placed artificial fills. The depth of fill near B-1 appears to be utility backfill. It is our opinion that the engineered fill soils placed at the site in 2000 and 2001 are generally considered suitable for support of the proposed buildings in the western portion of the site shown as Pads 3 through 5 (east of Pechanga Parkway). In the eastern portion of the site where grading has not occurred (includes Pads 9 through ll, Shops 1 and Major A) the upper 10 to 15 feet of existing native alluvial soils appear to be moderately collapsible when subject to saturation by water. Accordingly, in the eastern portion of the site, site grading should include overcxcavation of the upper 5 to 10 feet of soils beneath the existing grades. Engineered fill soils intended to support the proposed structures should be compacted to a minimum of 90 percent relative compaction. The upper 5 feet of soil within the footprint of proposed beneath structures should be compacted to at least 93 percent. Where proposed buildings are located only partially in the previously graded area (Pads 7, 8, and 9), the entire building footprint should also be uniformly overexcavated and the soils recompacted. 25423/DBA3R041 Copyright 2003, Kkinfelder, Inc Page 12 of 34 March 18,2003 \'\ I I I I , I ~ I I I I I I I I I I I I I k.~ KI.EINFElDER · We understand that cleanout ofthe easterly channel adjacent to Jedediah Smith Road prior to placement of fill was not conducted and that placement of fill in this area was neither observed nor tested by EnGEN. . The site is not located within a State or County designated fault hazard zone. The site is located within the 2-km Near Source Fault Zone of the Elsinore Fault zone. Due to the site's proximity to the Elsinore Fault zone, relatively large site accelerations approaching 0.68g are anticipated, based on a 10% probability of exceedance in 50 years. . The site is located within a County of Riverside designated ground subsidence zone. The site's vicinity is reported to be susceptible to ground fissuring due to withdrawal of groundwater and large seasonal fluctuations in groundwater levels. . The southern portion of the site is listed within a 100-year flood hazard zone by FEMA (FEMA, 2003). The flood hazard has been mitigated by rough grading to an elevation above the 100-year flood elevations determined by FEMA (approximately 1008 ft.). The site is within the floodplain of Temecula Creek and downstreanl from the Vail Lake dam, the site may be subject to inundation from this reservoir should it catastrophically fail or be overtopped by a seich. . The site is located within a County of Riverside designated liquefaction hazard zone. The current data from the prior and current borings indicate that the central and eastern portions of the property are susceptible to liquefaction at depths of 10 to 50 feet below the surface, which may result in seismically-induced settlement on the. order of 3 to 5 inches. Differential seismic induced settlement on the order of approximately 1 inch over a horizontal distance of 50 feet may result. Manifestation of the liquefiable soils at the surface in the form of sand boils or fissures may occur. Liquefaction may also result in lateral spreading near the descending slope along the south edge of the site. The liquefaction potential appears to impact current building pads 6 through 11, Shops 1, and Major A., The effects of differential seismically-induced settlement on buildings may be reduced by placing engineered fill at a minimum of 93 percent relative compaction, using grade beams to tie all foundation elements together within the buildings and/or by placing 2 to 3 layers of a geogrid product such as TENSAR within the engineered fill of the building pads at vertical intervals of approximately 3 feet. Lateral spreading (lateral movement of earth towards open face slopes during liquefaction at shallow depths) is difficult to mitigate. Lateral deformation on the order of inches and feet can occur under similar conditions. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc March 18, 2003 Page 13 of34 'lP I I I I I I I I I I I I I I i , I I , I I I I I k~ KLEINFElDER Overexcavation of the site soils below the toe of the slope adjacent to Temecula Creek may significantly reduce the potential impact on the site due to lateral spreading. Laboratory testing indicates that the onsite soils are considered moderately corrosive to buried metals and mildly corrosive to concrete. The ov-mer may wish to consider having a competent corrosion engineer retained to evaluate the corrosion potential of the site soils relative to the proposed improvements, recommend further testing as required, :md provide specific corrosion mitigation methods appropriate for the project. 5.2 SEISMIC DESIGN CONSIDERATIONS The site is located in a seismically active region and the proposed new structure can be expected to be subjected to moderate to strong seismic shaking during its design life. Potential seismic hazards include ground shaking, localized liquefaction, ground rupture due to f:mlting, and seismic settlement. The following sections discuss these potential seismic hazards with respect to this site. 5.2.1 Ground Shaking Because this site is located in the seismically active Southern California region, we recommend that, as a minimum, the proposed development be designed in accordance with the requirements of the latest edition of the Uniform Building Code (UBe) for Seismic Zone 4. We recommend 1hat a soil profile factor ofSD be used with the UBC design procedure (Table 16-1). Near source seismic coefficients for acceleration and velocity, Na, Nv, Ca, and Cv (UBC Tables 16-S and 16-T) should be used for calculating the design. The site is located at 0.4 km (wi1hin the 2-km) Active Fault Near-Source (Seismic) Zone for the Elsinore Fault, a Type B Fault as designated by the 1997 UBC (ICBO, 1998). A summary of the seismic parameters is presented below. 25423/DBA3R041 Copyright 2003, KJeinfelder, Ioc Page 14 of34 March 18,2003 ~\. I I I I I I I , , I I I I I I I I I I I I 1997 UBC Seismic Design Parameters Design Fault Els Fault Type Seismic Zone 4- Soil Profile Factor (Table 16-1) Near-Source Distance Na (Table l6-S) Nv (Table l6-T) Ca (Table l6-Q) 0.44 (Na) Cv (Table l6-R) 0.64 (Nv) 5.2.2 Liquefaction k'l KI.EINFELDER re Fault B = 0.4) , D km ..3 .6 .57 .02 mo (z S <2 ] 1 o 1 Liquefaction is a phenomenon associated with shallow groundwater, in combination with the presence of loose, sands or silts within a depth of about 50 feet below grade or less. Liquefaction occurs when these soils are subject to strong ground shaking resulting from earthquake induced ground motion. Liquefaction typically causes these soils to lose a portion or all of their shear strength. This strength is typically regained sometime after the shaking stops. Soil movements (both vertical and lateral) have been observed under these conditions due to consolidation of the liquefied soils and the reduced shear resistance of slopes. Liquefaction potential decreases with an increase in clay and gravel content and a decrease in grain size. However, the potential increases with an increase in the duration of the earthquake induced ground shaking. The site is located within a County of Riverside designated liquefaction hazard zone. Based on our research, the reported depth to historical groundwater appears to be approximately 10 feet below existing grade. Due to the depth to historic high groundwater at the site, the presence of granular soils, and the relatively low penetration resistance of the soils in the eastern portion of the property, the potential for liquefaction occurrence in the eastern approximately 2/3 of the site is considered to be high. 25423/DBA3R041 Copyright2003, Kleinfelder, lne Page 15 of34 March 18,2003 z,.'Y I I I I I I I I ; I I I I I I I I I I I k.~ KLEINFELDER 5.2.3 Seismically-Induced Settlement and Lateral Spreading Seismically-induced settlement is surface settlement caused by densification of non-saturated soils due to earthquake-induced ground shaking and liquefaction. Based on our field data and utilizing procedures proposed by Tokimatsu and Secd (1987), we estimated seismically-induced settlement to be on the order of 3 to 5 inches. Differential seismically-induced settlement is anticipated to be on the order of 1 inch across a distance of 50 feet. Settlement of dry sands above the assumed groundwater level is estimated to be negligible due to recommended remedial grading resulting in approximately 10 feet or more of engineered fill. Calculation for liquefaction and seismic settlement are presented in Appendix C. 5.2.4 Other Geologic Seismic Considerations The site is not located within a State of Califomia or Riverside County designated Earthquake Fault Rupture Hazard Zone for active faulting. The likelihood for ground surface rupture due to primary faulting from known faults is considered to be low. This is followed by lesser potential for ground fissuring. Based on the materials encountered at this site during our field exploration, the eXlstmg topographic conditions, the potential for saturated soil conditions at shallow depths, and the proposed site improvements, we consider the liquefaction potential to be high. Due to the low topographic relief of the site we consider the potential for seismic slope instability to be low, the low potential for slope instability is related to the potential for lateral spreading resulting from liquefaction involving the creek bank along the south margin ofth.e property. The elevated inland location of the site is not situated near any impounded bodies of water; therefore, tsunamis are not considered a potential hazard to the project. The southern portion of the site is listed within a 100-year flood hazard zone by FEMA (FEMA, 2003). The flood hazard has been mitigated by rough grading to an elevation above the 100-year flood elevations determined by FEMA (approximately 1005 feet). The site is within the floodplain of Temecula Creek and downstream from the Vail Lake dam, the site may be subject to inundation from this reservoir should it catastrophically fail, or be overtopped by a seich. 25423/DBA3R041 Copyright 2003, KleinfeJder, Inc Page 16 of34 March 18,2003 ~ ~ I I I I I I I I I I Id I I I I I I I I k'l KlEINFELDER 5.3 MITIGATION OF LIQUEFACTION POTENTIAL The liquefaction potential appears to impact current building pads 6 through 11, Shops 1, and Major A. As discussed above there is a potential during the DLE for total and differential settlements due to liquefaction on the order of 3 to 5 inches and 1 inches over 50 feet. This settlement, should it occur, is calculated to occur from a depth of approximately 10 feet to 20 feet and 25 feet to 30 feet below grade and may manifest at the surface. Because there will be an estimated 8 to 10 feet of non-liquefiable soils below the at-grade structures, the potential for a loss in bearing capacity is considered to be low. It is our opinion that mitigation of dynamically induced settlement prior to construction of the proposed structures is geotechnically feasible at the site. Typically, liquefaction is mitigated by either using deep foundations such as driven piles and a rigid pile cap to support the structures on the deeper dense, non-liquefiable soils or by using ground improvement/modification techniques to densify the soils and thereby reducing the liquefaction potential. Other methods such as permanent lowering of groundwater levels and overexcavation ,md recompaction of liquefiable soils are not considered to be feasible. The effects of differential seismically-induced settlement on buildings may be reduced by increasing the minimum relative compaction to 93 percent, using grade beams to tie all foundation elements together within the buildings and/or by placing 2 to 3 layers of a geogrid product such as TENSAR BX11 00 or equivalent within the engineered fill of the building pads at vertical intervals of approximately 3 feet. Lateral spreading (lateral movement of earth towards open face slopes during liquefaction at shallow depths) is difficult to mitigate. Lateral deformation on the order of inches and feet can occur under similar conditions. Overexcavation of the site soils below the toe of the slope adjacent to Temecula Creek may significantly reduce the potential impact on the site due to lateral spreacling. 5.4 EARTHWORK 5.4.1 Site Preparation Site preparation and earthwork operations should be performed in accordance with applicable codes and the recommendations included herein. Based on our field investigation and review of previous geotechnical reports, the following recommendations are presented. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine Page 17 of34 March 18, 2003 ']..I\. I I I I I I I I I I I I I I I I I I I kq Kl.ElNFElDER East Parcel B (Pads 6-11, Shops 1, Maior A) The upper natural soils in the eastern portion of the site at a depth of about 10 to 16 feet below existing grade are susceptible to potential hydroconsolidation. The moisture sensitive soils have a moderate probability to experience significant loss in strength and increase in compressibility when wet. Potential differential settlement can be reduced by constructing a thick layer of engineered fill beneath the foundations. The soils in the proposed building pad areas should be overexcavated to depths of 5 to 10 feet as follows: Buildings 6-9: Building 10: Building 11: Shops 1: Major A: 8 feet below existing grade 5 feet below existing grade 8 feet below existing grade 8* feet below existing grade 8* feet below existing grade *Please note in Section 5.3, to mitigate the potential for adverse impacts of liquefaction, recommendations are provided to construct the building pad with engineered fill reinforced with geogrid layers. The upper 5 feet of engineered fill in the building pad areas should be compacted to a minimum of 93 percent relative compaction to further reduce the potential adverse effects of the collapsible soils. The excavation beneath the building pads should extend at least 8 feet laterally beyond the building footprints. Parcel A (pads 1 and 2) Site preparation in the area west of Pechanga Parkway ,:hould include overexcavation and recompaction of the existing fill soils ",cithin the building pad areas. Where shallow fills less than 4 feet or native soils we encountered at the surface, we recommend overexcavation and recompaction to a minimum of 4 feet below existing grades. West Parcel B (pads 3 through 5) Engineered fill soils in the western portion of Parcel B we considered suitable for support ofthe proposed buildings and additional shallow fill placement. Due to weathering of the surficial soils, we recommend that the surface should be scarified to a minimum depth of 10 inches, L6 25423/DBA3R041 Copyright 2003, Kleinfelder, Ioe Page J8 of34 March 18, 2003 I I I I I , I i I I I I I I I . I I I I I I k.~ KlEINFElDER moisture conditioned to zero to 3 percent over optimum moisture content, and recompacted to a minimum of 90 percent relative compaction. Parcel Area In the area where surface paving is planned, the depth of overexcavation may be reduced to about 2 feet below existing grade. Localized areas requiring deeper fill removal should be anticipated. Following the over-excavation of the upper loose soils, the exposed subgrade should be inspected for all unsuitable soils, rubble, and debris and the excavation deepened if necessary. The exposed subgrade should then be scarified to a depth of 6-inches, brought to near optimum moisture content and rolled with heavy compaction equipment. Removal bottoms should be compacted to at least 90 percent of maximum dry density as determined by ASTM Test Method D-1557-91. F allowing the sub grade preparation, the removed soils should be replaced in loose lifts of not more than 8-inches thick, brought to within 0 to 3 percent above optimum moisture and be mechanically compacted using heavy equipment. All soils should be compacted to at least 90 percent of maximum dry density as determined by ASTM Test Method D1557-91. The upper six inches of the pavement sub grade should be compacted to a minimum of 95 percent relative compaction. All earthwork operations should be observed and tested by a representative of this firm. 5.4.2 Materials for Fill The onsite soils, less any debris or organic materials may be used for any required fill soils. All imported soils should be granular in nature and be relatively non-expansive with an expansion index of less than 35. The imported soils should however contain enough fines to provide a stable sub grade and maintain low to medium permeability characteristics. Import soil should be sampled, reviewed, and approved by the project geotechnical engineer prior to delivery to the site. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc Page 19 of34 March 18,2003 2fo I I.' I . I I I I I . I , I I . . I . I I k~ KI.EINFELDER 5.4.3 Excavation Conditions The borings advanced at the site were advanced using a truck-mounted, hollow-stem auger drill rig. Drilling was completed with slight to moderate effort through the subsurface soils. Conventional earth moving equipment is expected to be capable of performing the excavations required for site development. 5.4.4 Collapsible Soils Based on our laboratory testing and the results of previous explorations at the site by others, the upper natural soils at the site to a depth of about 5 to 10 feet have a moderate collapse potential. Collapsible soils (or moisture sensitive soils) are defined as a soil with a potential for a significant decrease in strength and increase in compressibility when wet or saturated. The collapsible soils should be overexcavated and recompacted as properly compacted-engineered fill during the earthwork operations. As discussed in Section 2, the soils in the vicinity of Building Pads 3 through 6 and portions of Pads 7 and 8 were overexcavated and recompacted during grading in 2001-2002. 5.4.5 Excavations and Temporary Slopes Excavations deeper than 4 feet deep should be sloped back at I: 1 (horizontal to vertical) or be shored or braced for safety. Excavations eA1:ending below a 1 \1,:1 (horizontal to vertical) plane extending down from any adjacent footings should be shored for safety. All excavations should be observed by a representative of the geotechnical engineer during construction to allow any modifications to be made due to variations in the soil conditions. During wet weather, earthen berms or other methods should be used to prevent runoff water from entering all excavations. All runoff water and/or groundwater encountered within excavations should be collected and disposed outside the construction limits. All excavations must comply with applicable local, state, and federal safety regulations including the current OSHA Excavation and Trench Safety Standards. Construction site safety generally is the sole responsibility of the Contractor, who shall also be solely responsible for the means, methods, and sequencing of construction operations. We are providing the infonnation below solely as a service to our client. Under no circumstances should the information provided be 25423/DBA3R041 Copyright 2003, Kleinfelder, Joe Page 20 of34 March 18, 2003 z.i I I' I I I I I I I I I I I- I I I I I I I I k~ KlElNFHDER interpreted to mean that Kleinfelder is assuming responsibility for construction site safety or the Contractor's activities; such responsibility is not being implied and should not be inferred. The Contractor should be aware that slope height, slope inclination, or excavation depths (including utility trench excavations) should in no case exceed those specified in local, state, and/or federal safety regulations (e.g., OSHA Health and Safety Standards for Excavations, 29 CFR Part 1926, or successor regulations). 5.4.6 Trench Backfill All required trench backfill should be mechanically compacted in 8-inch (maximum) layers with mechanical compaction equipment. Jetting and flooding is not recommended. We recommend all backfill be compacted to at least 90 percent of maximum dry density based on ASTM Test Method D1557-91. The moisture content of compacted backfill soils should be within 0 to 3 percent over the optimum at the time of compaction. Some settlement of the backfill may be expected and any utilities within the trenches should be designed to accept differential settlement. If imported material is used for pipe or trench zone backfill, we recommend it consist of fine-grained sand. In general, coarse-grained sand and/or gravel should not be used for pipe or trench zone backfill due to the potential for soil migration into the relatively large void spaces present in this type of material and water seepage along trenches backfilled with coarse-grained sand and/or gravel. Recommendations provided above for pipe zone backfill are minimum requirements only. More stringent material specifications may be required to fulfill local building requirements and/or bedding requirements for specific types of pipes. We recommend the project Civil Engineer develop these material specifications based on planned pipe types, bedding conditions, and other factors beyond the scope of this study. 5.5 FILL SLOPE CONSTRUCTION Based on our field observations and the limits of overexcavation and recompaction presented by the previous consultant (EnGEN, 2002), it appears that the proposed southem slope near the center of the site (south of Pads 6 through 8) will be constructed as a fill slope. The existing 25423/DBA3R041 Copyright 2003, Kleinfe1der, Ine Page 21 of34 March 18, 2003 ~2> I I I I I I I I I I I I I I I I I I I k~ KLEINFElDER slope also has experienced erosIOn and gullying and vl'ill require remedial grading. We recommend that a keyway be excavated at the toe of the slope to support the fill soils. The keyway excavation should expose firm native soils or bedrock and should be at least equipment width (minimum 10 feet). The keyway should be at least 2 feet deep at the toe of the slope and should slope down toward the heel at least one foot. Fill soils should be placed as described above and should be benched into competent existing soils. Fill slopes should be overfilled a minimum of two feet horizontally from the slope face. The surface of the overfilled slope should be backrolled at regular intervals to provide the required compaction. Upon completion of filling, the slope should be trimmed to finish grade so that the compacted core is exposed at the slope face. As an alternative, fill slopes may be constructed at grade as long as compaction of each lift extends to the face of the ' slope. Fill slopes should be backrolled at intervals not exceeding four , feet in height or as recommended by the project soils engineer during grading. Care should be taken to avoid spillage ofloose materials dovvn the slope face during grading. At the completion of mass filling, the project soils engineer should evaluate the slope surface. Should additional compaction be required, the slope should be moisture conditioncd to slightly above optimum and compacted with a vibratory sheepsfoot roller and finished with a grid roller operated from it sideboom tractor until the compaction of the slope face is achieved. Landscaping of the slope should proceed as soon as possible to reduce the potential for erosion and deterioration of the slope surface. Proper moisture control should be incorporated into the landscape design in order to minimize the potential for surficial slope saturation. Irrigation should be minimized and water should not be allowed to flow over the face of the slopes. The civil engineer should include methods to prevent erosion and scour of the slope face. An ongoing program to control rodent infestation should be initiated to protect slopes from moisture infiltration and promote long term stability. 5.6 DRAINAGE AND LANDSCAPING It is important that positive surface drainage be provided to prevent ponding and/or saturation of the soils in the vicinity of foundations and concrete slabs-an-grade. We recommend that the site be graded to carry surface water away from the proposed buildings and that positive measures be 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine March 18, 2003 Page 22 of 34 1,0... I I I I I - I i I I I I I I I I I I I I I k~ KLEINFELDER implemented to carry away roof runoff. The upper soils at the site are moderately collapsible when saturated with water. The recommended overexcavation is intended to mitigate the collapse potential of the upper soils. Poor perimeter or surface drainage could allow migration of water beneath the building or pavement areas, which may result in distress to project improvements. The following supplemental suggestions are also provided if it is desirable to further reduce the potential for migration of water under the building pad: When possible, we suggest that planters adjacent to buildings be placed at least I 0 fi~et from the building footprint. If planted areas adjacent to the structure are desired, we recommend that care be taken not to over-irrigate and to maintain a leak-free sprinkler piping system. If possible, we suggest that planters be sealed. In addition, it is recommended that planter areas next to buildings have a minimum of 5 percent positive fall away from building perimeters to a distance of at least 5 feet. Drain spouts should be extended to discharge a minimum of 5 feet from the building, or some other method should be utilized to prevent water from accumulating in planters. Landscaping after construction should not promote ponding of water adjacent to structures. 5.7 FOUNDATIONS 5.7.1 Allowable Bearing Pressures The proposed buildings may be supported on shallow spread footings founded over at least 5 feet of properly compacted engineered fill soils. Continuous and isolated spread footings should have minimum widths of 18 inches and be embedded at least 18 inches below the lowest final adjacent sub grade. Within this report, the lowest adjacent grade refers to the finished exterior grade for the perimeter footings and the finished pad grade for interior footings. Footings established as recommended may be designed using an allowable bearing pressure of 2,500 pounds per square foot for dead plus sustained live loading. The allowable bearing pressure provided above is a net value; therefore, the weight of the concrete may be assumed to be 50 pounds per square foot. The weight of the soil backfill may be neglected when computing dead loads. The allowable bearing pressure may be increased by one-third for short-term loading due to wind or seismic forces. Footings may experience an overall loss in bearing capacity or an increased potential to settle where located in close proximity to existing or future utility trenches. Furthermore, stresses imposed by the footings on the utility lines may cause c.racking, collapse and/or a loss of 25423/DBA3R041 Copyright 2003, KleinfeJder, Ine Page 23 of 34 March 18, 2003 ?P I I I I I I I I I I I. I I I I I I I I kq Kl.EINFELDER serviceability. To reduce this risk, footings should extend below a I: 1 plane projected upward from the closest bottom comer of the trench. Footings for minor structures (loading dock walls, minor retaining walls, free standing walls, etc.) that are structurally separate from the building can be designed using an allowable bearing pressure of 1,000 pounds per square foot at a minimum depth of 1 \/, feet below the lowest adjacent grade. Such footings can be established in the properly compacted fill soils. 5.7.2 Estimated Settlements Based on anticipated loading conditions, we estimate the total static settlement for the proposed buildings supported in the manner reconunended to be on the order of \/,- to I inch. Differential settlements between adjacent columns are estimated to be on the order of \/'-inch. Settlement due to liquefaction is estimated at 3 to 5 inches with differential settlement on the order of 1 inch over a 50-feet distance. Seismically induced dry settlement is expected to be negligible following grading. The seismically induced settlements and liquefaction induced settlement are in addition to the static settlements presented above. Static settlement of all foundations is expected to be primarily elastic and should be essentially completed shortly after initial application of structural loads. 5.7.3 Lateral Resistance Resistance to lateral loads (including those due to wind or seismic forces) may be provided by frictional resistance between the bottom of concrete foundations and the underlying soil and by passive soil pressure against the sides of the foundations. A coefficient of friction of 0.35 may be used between cast-in-place concrete foundations and the underlying soil. Passive pressure available in engineered fill may be taken as equivalent to the pressure exerted by a fluid weighing 250 pounds per cubic foot. The passive resistance of the subgrade soils will diminish or be non-existent if trench sidewalls slough, cave or are overwidened during or following excavations. If this condition is encountered, our firm should be notified to review the condition and provide remedial recommendations, if necessary. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine Page 24 of 34 March 18, 2003 ~\ I I, I I I I I I I , I I ; I. I I I I I I I I k~ KLEINFELDER 5.7.4 Slope Setbacks Foundations located near descending slopes should be setback from the top of slope at least 10 feet due to the potential for lateral spreading caused by potential liquefaction. Footings located within 10 feet from the top of slope must be deepened to provide a minimum of 10 feet from the edge of the footing bottom to the slope face. 5.7.5 Construction/Design Considerations Prior to placing steel or concrete, footing excavations should be cleaned of all debris, loose or soft soil, and water. Footing excavations should be observed by the project Geotechnical Engineer just prior to placing steel or concrete to verify the recommendations contained herein are implemented during construction. We recommend that all reinforcement be designed for the specific loading conditions by the project structural engineer. 5.8 RETAINING WALLS Retaining walls may consist of standard reinforced concrete arld masonry block construction. Retaining walls may be supported on spread foundations fOlmded in the properly compacted engineered fill soils. For the design of retaining walls, where the backfill surface is level; the wall may be designed assuming that the drained soils will exert a lateral pressure equivalent to a fluid with a density of 30 pounds per cubic foot. The recommended lateral earth pressures assume that drainage is provided behind the walls to prevent accumulation of hydrostatic pressures. Walls should be provided with backdrains to reduce the potential for the accumulation of hydrostatic pressures. Backdrains may consist of a 2-foot wide zone of Caltrans Class 2 permeable material located immediately behind the wall, extending to within I foot of the ground surface. Weep holes should be provided or a perforated pipe (Schedule 40 PVC) should be installed at the base of the backdrain and sloped to discharge to a suitable collection facility. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine Page 25 of34 March 18, 2003 ~z. I I I I I i I I I I I I I , - I I I I I I k~ KLEINFELDER In addition to the recommended earth pressure, retaining walls adjacent to areas subject to vehicular traffic shall be designed to resist a uniform lateral pressure of 100 pounds per square foot, which is a result of an assumed 300 pounds per square foot surcharge behind the shoring due to normal street traffic. If the traffic is kept back at least 10 feet from the wall, the traffic surcharge may be neglected. Retaining walls should be designed for lateral surcharges imposed by any adjacent existing foundations. Additional loads on retaining walls may be imposed by surcharge. An additional horizontal wall load equal to 50 percent of the surcharge load should be applied uniformly over the entire height of the wall. 5.9 CONCRETE SLABS SUPPORTED-ON-GRADE It is our opinion that concrete slab-on-grade floors may be used for the proposed structures. Slah-on-grade floors may be supported on engineered fill prepared as described in this report. Concrete slab-on-grade floor slabs should have a minimum actual thickness of 4 inches. All slabs should be designed for any specific loading conditions by the stmctural engineer, A modulus of suhgrade reaction of 150 pounds per cubic inch may be used for preliminary design. Surficial soils should be uniformly moisture-conditioned to near optimum moisture content and compacted to a minimum of 95 percent of the laboratory maximum dry density. Subsurface moisture and moisture vapor naturally migrate upward through the soil and, where the soil is covered by a building or pavement, this subsurface moisture will collect. To reduce the impact of this subsurface moisture and the potential impact of future introduced moisture (such as landscape irrigation or precipitation) the current industry standard is to place a vapor retarder on the compacted crushed rock layer. This membrane typically consists ofvisquene or polyvinyl plastic sheeting at least! 0 mil in thickness. It should be noted that although vapor barrier systems are currently the industry standard, this system may not be completely effective in preventing floor slab moisture problems. These systems typically will not necessarily assure that floor slab moisture transmission rates will meet floor-covering manufacturer standards and that indoor humidity levels be appropriate to inhibit mold growth. The design and construction of such systems are totally dependent on the proposed use and design of the proposed building and all 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc Page 26 of 34 March 18, 2003 ~~ I I I I I ; I I I I , I I I i I I I I I I I kq KLEINFELDER elements of building design and function should be considered in the slab-on~grade floor design. Building design and construction may have a greater role in perceived moisture problems since sealed buildingslrooms or inadequate ventilation may produce excessive moisture in a building and affect indoor air quality. Various factors such as surface grades, adjacent planters, the quality of slab concrete and the permeability of the on-site soils affect slab moisture can control future performance. In many cases, floor moisture problems are the result of either improper curing of floor slabs or improper application of flooring adhesives. We recommend contacting a flooring consultant experienced in the area of concrete slab-on-grade floors for specific recommendations regarding your proposed flooring applications. Special precautions must be taken during the placement and curing of all concrete slabs. Excessive slump (high water-cement ratio) of the concrete anlor improper curing procedures used during either hot or cold weather conditions could lead to excessive shrinkage, cracking or curling of the slabs. High water-cement ratio and/or improper curing also greatly increase the water vapor permeability of concrete. We recommend that all concrete placement and curing operations be performed in accordance with the American Concrete Institute (ACI) Manual. 5.10 PAVEMENT DESIGN An R-value test was performed on a selected sample to provide data for the design of paving. .The test result, presented in Appendix B, indicates the R-value of the sample tested to be 5, which is considered relatively low. For design of the pavement structural section including aggregate base, we have utilized an R-Value of 30, based of the presence of predominantly granules soils at the surface. If fine-grained soils are placed at the surface in pavement areas, pavement design may need to be modified. We recommend that a minimum 4-inch layer of aggregate base be placed beneath pavements. The R-value of the sub grade soils should be evaluated by the geotechnical engineer of record following subgrade preparation to access the applicable final pavement section to be used. Pavement sections are provided for Traffic Index (TI) values of 4.0 through 8.0 for the parking areas and access lanes. We have developed the following preliminary recommendations for asphalt pavement (Table 4), and rigid Portland concrete cement pavements (Table 5). 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine Page 27 of34 March 18, 2003 ?;A. I I I I I I I I I I I I I I I I I I I k~ KlEINfELDER Table 4 Recommended Asphalt Concrete Pavement Sections '#'"", 'lilt 4.0 5.0 6.0 6.5 7.0 7.5 8.0 3.0 3.0 3.5 4.0 4.0 4.5 5.5 4.0 6.0 7.5 8.5 9.5 10.5 13.0 'CMB - Crushed Miscellaneous Base Table 5 Recommended Portland Cement Concrete Pavement Sections 5.0 or less 5.1-6.0 6.1 - 8.0 R-value = 30 6.5 7.0 7.5 Pavement sections provided above implemented during construction. are contingent on the following recommendations being . We recommend pavements be underlain by 24 inches of engineered fill outside the area of previous grading, the upper 24 inches of pavement sub grade be overexcavated and recompacted prior to placement of the structural section. Prior to fill placement, the exposed subgrade should be scarified to a depth of 6 inches, uniformly moisture conditioned to within o to 3 percent above the optimum moisture content, and compacted to at least 90 percent relative compaction. The upper six inches of the pavement subgrade should be compacted to a minimum of 95 percent relative compaction. In areas previously graded, the exposed sub grade should be scarified, moisture condition as mentioned above, and compacted to at least 95 percent. . Subgrade soils should be in a stable, non-pumping condition at the time aggregate base materials are placed and compacted. 25423/DBA3R041 Copyright 2003, Kleinfelder, lne Page 28 of 34 March] 8,2003 7;i5 I I ' I I I I I I I I I I I I I I I I I I k~ KLElNFELDER . A compressive strength of 4,000 pounds per square inch has been assumed for the design of the Portland cement concrete paving section. . Aggregate base materials should be compacted to at least 95 percent relative compaction. . Adequate drainage (both surface and subsurface) should be provided such that the sub grade soils and aggregate base materials are not allowed to become wet. . Aggregate base materials should meet current Caltrans specitications for Class 2 aggregate base. . Crushed miscellaneous base (CMB) material should meet current requirements of the Standard Specification for Public Works Construction (Greenbook). . Asphalt paving materials and placement methods should meet current Caltrans specifications for asphalt concrete. Pavement sections provided above are based on the soil conditions encountered during our field investigation, our assumptions regarding fmal site grades, and limited laboratory testing. In the event actual pavement subgrade materials are significantly different than those tested for this study, we recommend representative subgrade samples be obtained and additional R-value tests performed. Should the results of these tests indicate a significant difference, the design pavement sections provided above may need to be revised. 5.11 EXPANSION POTENTIAL Expansive soils are characterized by their ability to undergo significant volume change (shrink or swell) due to variations in moisture content. Changes in soil moisture content can result from rainfall, landscape irrigation, utility leakage, roof drainage, perched groundwater, drought, or other factors and may cause unacceptable settlement or heave of structures, concrete slabs supported-an-grade, or pavements supported over these materials. Depending on the extent and location below finished sub grade, these soils could have a detrimental effect on the proposed construction. 25423/DBA3R041 Co?yright 2003, Kleinfelder, !nc Page 29 of 34 March 18,2003 ~ I I I I I I I I I I - I I I I I I I I k~ KLEINFELDER The project site is generally underlain by granular soils which, based on soil classili.cation, are not anticipated to have a significant expansion potential. Laboratory testing performed on representative soil samples indicates a "very low" to "low" expansion potential as described in UBC Table 18-I-B. Following grading of the site, we recommend that finish grade soils be sampled at randomly selected locations and tested to identifY areas where additional steel reinforcement may be required in the foundatIons. 5.12 CORROSIVITY Two samples of the near surface soils were tested for corrosion potential to concrete and reinforcing steel. The sample was sent to AP Engineering and Testing, Inc. for testing of pH, resistivity, soluble sulfates and soluble chlorides. The sample was tested in general accordance with California Test Methods 643, 422, and 417 for pH and resistivity, soluble chlorides, and soluble sulfates, respectively. The test results are as follows: We have provided the above corrosion tests as requested by the client. These tests are only an indicator of soil corrosivity for the samples tested. Other soils found on site may be more, less, or of a similar corrosive nature. Although Kleinfelder does not practice corrosion engineering, the corrosion values from the soil tested indicate moderate corrosivity to buried ferrous metals and rnild corrosivity to concrete elements. Based on guidelines provided in the UBC, Table 19-A-4, cement types or maximum water-cement ratios are not specified for these concentrations. We recommend that corrosion mitigation for the site improvements be consistent with the level of corrosion potential identified above. The proposed concrete mix design should be submitted to a qualified materials engineer for approval. Based on the above results, the owner may 'wish to consider having a competent corrosion engineer retained to evaluate the corrosion potential of the site soils relative to the proposed improvements, recommend further testing as required, and provide specific corrosion mitigation methods appropriate for the project. 25423/DBA3R041 Copyright 2003, Kleinfelder, Joe Page 30 of 34 March 18, 2003 ,?1 I I I I I i I I I I I I I I I I I I I I k"ll KLEINFElDER 6 ADDITIONAL SERVICES 6.1 PLANS AND SPECIFICATIONS REVIEW We recommend that Kleinfelder conduct a general review of final plans and specifications to evaluate that our earthwork and foundation recommendations havt: been properly interpreted and implemented during design. In the event Kleinfelder is not retained to perform this recommended review, we will assume no responsibility for misinterpretation of our recommendations. 6.2 CONSTRUCTION OBSERVATION AND TESTING We recommend that all earthwork during construction be monitored by a representative from Kleinfelder, including site preparation, placement of all engineered fill and trench backfill, construction of slab and roadway subgrades, and all foundation excavations. The purpose of these services would be to provide Kleinfelder the opportunity to observe the soil conditions, encountered during construction, evaluate the applicability of the recommendations presented in this report to the soil conditions encountered, and recommend appropriate changes in design or construction procedures if conditions differ from those described herein. 25423/DBA3R04! Copyright 2003, Kleinfelder, Joe Page 31 of34 March 18,2003 p~ I I I I I I I , I I I I- I I I I I I I I k.~ KLEINFELDER 7 LIMITATIONS This preliminary report has been prepared for the exclusive use of Rainbow Canyon Development, LLC and their agents for specific application to the proposed Rainbow Canyon Shopping Center retail development in Temecula, California. The findings, conclusions and recommendations presented in this report were prepared in accordance with generally accepted geotechnical engineering practice. No other warranty, expressed or implied, is made. We should review the final location map and grading plans to verify that our borings were properly located, and to develop recommendations for additional exploration, if appropriate, and to provide additional information. The scope of our geotechnical services did not include any environmental site assessment for the presence or absence of hazardousltoxic materials in the soil, surface water, groundwater or atmosphere, or the presence of wetlands. The client has the responsibility to see that all parties to the project, including the designer, contractor, subcontractors, etc., are made aware of this report in its entirety. This report contains information, which may be useful in the preparation of contract specifications. However, the report is not designed as a specification document and may not contain sufficient information for this use without proper modification. This report may be used only by the client and only for the purposes stated, within a reasonable time from its issuance. Land use, site conditions (both on site and off site) or other factors may change over time, and additional work may be required with the passage of time. Based on the intended use of this report and the nature of the new project, Kleinfelder may require that additional work be performed and that an updated report be issued. Non-compliance with any of these requirements by the client or anyone else will release Kleinfelder from any liability resulting from the use of this report by any unauthorized party. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc March 18, 2003 ~ Page 32 of 34 I I I I I I ; I I I I I I I I I I I I I k'll=) KlEINFElDER 8 REFERENCES Blake, Thomas F., 2000, FRISKSP, EQFAULT and EQSEARCH, v 3.00, Computer Programs. California Department of Water Resources, 2003, Historical Data by Well (Web Site), State Well No.08S02W20E001S, Historical High Measurement on October 30,1948, well located 8000 feet east of site, up gradient, within Temecula Creek Drainage. California Division of Mines and Geology, 1966, Geologic Map of California, Santa Ana Sheet. California Division of Mines and Geology, 1990, State of Calif ami a Special Studies Zones Map, Pechanga Quadrangle. California Division of Mines and Geology, 1990, State of California Special Studies Zones Map, Temecula Quadrangle. California Division of Mines and Geology, 2000, Digital Images of Official Maps of Alquist- Priolo Earthquake Fault Zones of California, Southern Region, DMG CD 2000-003. City of Temecula, Public Safety Element, November 9,1993. EnGEN, 2002, Geotechnical Report and Compaction Test Results, Rough Grading Operations, Pala Rainbow Development, South Side of Highway 79 South, East of Existing Pala Road, City of Temecula, County of Riverside, California, Project Number: T1956-C, dated May 14, 2002. EnGEN, 2000, Geotechnical/Geological Engineering Study, Proposed Structures, South Side of Highway 79 South, East of Existing Pala Road, City of Temecula, County of Riverside, California, Project Number: TI956-C, dated February 28, 2000. FEMA, 2003, Map Service Center (web site), Map Panel 0607420010B.P. January 20, 1996. 25423/DBA3R041 Copyright 2003, Kleinfelder, Inc Page 33 of 34 March 18,2003 Ao I I I I I i I I ! * I I I. I il I .' il I I I I I k~ KLEINFELDER Hart, Earl W., and Bryant, William A., 2000, Fault-Rupture Hazard Zones in Califomia: Alquist- Priolo Earthquake Fault Zoning Act with Index to Earthquake Fault Zones Maps, California Division of Mines and Geology, Special Publication 42, supplemented through 1999, as in CDMG CD 2000-03. International Conference of Building Officials, 1997, Uniform Building Code, Volume 2. International Conference of Building Officials, 1998, Maps of Known Active Fault Near-Source Zones in the State of California and Adjacent portions of Nevada, for the 1997 Uniform Building Code. Kennedy, Michael P., 1977, Recency and Character of Faulting Along the Elsinore Fault Zone in Southern Riverside County, California Division of Mines and Geology, Special Report 131. Riverside, County of, Transportation and Land Management Agency, 1997, Environmental Hazards Map, June 10, 1997. Shlemon, Roy J., and Davis, Paul, 1992, Ground Fissures in the Temecula Area, Riverside County, California, pps 275-288, in Pipkin, Bermard W. and Proctor, Richard J. Eds., Engineering Geology Practice in Southern California. Ziony, Joseph 1., and Jones, Lucile M., 1989, Map Showing Late Quaternary Faults and 1978-84 Seismicity of the Los Angeles Region, California, U.S. Geological Survey Miscellaneous Field Studies Map, MF-1964. 25423/DBA3R041 Copyright 2003, Kleinfelder, Ine Page 34 of 34 March 18, 2003 A \ :'~~~:~-:~:t~'::tl?j~:' :'.~,~~!~',:'.~ .~~.,., lJ ,<<,', ,', :;lt~~ ~~1~~~ ~{ ::~f~\: ff - .> ,,-.. :'2 ; ;:, "< :, .",,; ., ,',' ',." ", ; ,;,> .;,{~~~~: ,. ,. 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'~~~,J l'2.'F--..h~J'#.-,:"= "'--J"<:h~ 'r="~. ;,f/I/i:c';:0..')j~1 I l' ~ '1l' \ ,;". .~' '---,7' '-,~ :"~./ .~-_,'"c;l~i.;0'!IrY'~?l))~~.c!.ps:{,i'?,/<(~';f,\'-!i<i(;.> .I /l\" (1l~~,\ ~ ~ \,', 1, '-,--,-l~;- ~.%..': \,0--'t,2!,,~1l~\~I:{,m,~~\u~\g':.'ft>if(.~...~~;:,"}.d(-" ~ ~ ~\(q;;'\ \, ~, ' I ~ I '-i' I ,.....-~'\:t>o r:7-'<::i~~ - '; "l1~~I~~i*j(.~i\?)~1c~)(~<::::~ 'l-::) / 'i;d ),<~'),o:,~;:.!/ ff ,~ ) ~ "~_~"\~" .\~'v'f j ,\ j'.~" r,:1" . - L', \j'\ ~)J!I{~:~IJ;?:::?~.....d;1i '~-.l ..:..~,-.t.~-...;\v:.,. {r \-l "",.'11',<',: \ ',0\, . \. z, ~ '1' e' + ,- _.- < ~ " '_' 1'.tV(".Fi:'f-",~Li1"~:Jc/"')/',' (';S{\l)p^~~cJ!f' '/',. ~~~, ^ , , j'" -t - . :-...,L.~ - ~. A'J " ~~~ ~ l' (1lj:~' \.....)I'-.,~"-) ,\1'1 17.' '.;}.(f!.-;}jr;,......~ :1\.... ,~- ',,'\,:l.:.......~.::,~t :/:< [,~~_ '-'" I "',"'-~--' I!fS '~""-~~~/~f.l\Si:r'~r~).~- 0':=::~r~1-~' <.... /~~-.. ./ k;~~ ...~, -2~~\ ~;' ...., :-)~;.., - J' --e7,':<!,'" '--, i ~~~~ 'i v.:-;;=-t-,~';lj'~. h/f~?5~J'f. ;,/ '~""""".6f'. ''--, ,.....-' ~Xi:"\-211'-':.,-{...:::::..~,~~lJJC _~ ~- . 4 ~ )1 .......~ \....~J/',....r:=:,::~i9~r-r.;..<v~.>;o.... ,,~., ~ ~ ~'.\\ '::;";1 ;, '1,"'1,.' . .' ",' I ~A, /0<;:- t, (!/'<:-..........., '~<x~~~T:0~~t/({!'::J.~ !:-- --. . .y',{<~,,~ ;/, ~ ,\ 'II ',BM 014 ~ '- 1-__ ~ I .. Jf' .~~ . _ : ,,-.r'~/}\ \ .~~~ .~!j-:%:;a:d.::- ~ / - ~.\:.,,\l.' "'~,j"." ,__r__~ t:"~~" Ir"'-~- ....... ,," "1"i'-':....'" 00.-'< ~)'I~~r", ~-~ ...- ,":>"',)1 f('(:\'~Gi~ -'~' ;?',' 'f! '-<~~, ',':,<__JU'>A'~:""'~"i rV------ ' ..-<- r..l.J(l~~-, --:<- 'eo . f J".i' . -"""'-~l I IlN:'-..' .~~).>=-?--- , I ~ / \' f{\ ~~:.~'~~~~0.:::Zr-,~ ~tatro, . '\~ g -';'-.:s~~ ;;,:J -,I ........",,-....r-~~--~. , _.,..~....- " , , "=., _'_ ' /,ck 0 ~'l!T-,--,L! ~~~- ~"-. / -','\' :::"'~",":;-v'''' -....._.:--... \' 7 '''\-. '" 'f" -,; I!--=-=-:;----~----'- -~ "I ~~""~.........~....,~\', ~:...\ '.r "'"",----"""", I, -;:.... "till, .; j ,:;->:::....../ \ ,..-....---; ...- ~.~' \:.~,'~~":.~,}";,~=~~X' ,~......., .'\ ':-' _~4-S!I-F~ ~A >nJ '-'ill: r:, ...- .~~.....,.,.... ,/ i./I'-;.;?-- - , ,,"ll('O."%.,~,~ ~\,,\I', ( "~ 1 lie ~,I ,; f ~--=- \ r ......-'7 p~~ ;>:~~';1S/~: "$\~~i{~\ \~i} ;=~'--'f'~t~ ~~ .~-,:~,;;, -~~' ~ .,\.t-.(.:'>;;':<~' /' j'~~~~- "S~. .f:p:~~~6 \Y~\\"i ~(,:; '. ~...__...f--..' '\"r>-_~ ,,.~ ];1 lJ'gc~~! : 1,"1 ",'~\ C. _ ''';:7" r: \~""""'/,.J \~~..~;j!,!:S%P-l ..... \'.' /J1:?;;:_ I ......,-~..,,.,~""_ BM:>'Jj~;' ~JJ~:~-''''!g,~:::~___L__/'>'7- .. ':"- .-' ::.- C~~: ~~r~\':'-'~r~""" . -:.-C-.... I '-..:~1lz '-"'fOOa~'_' './-- r,,:~j..Q~-:'-:~"~\~r-.::--.---neme('JU.~oJ..-:":_---~' 'f ,..- ~sit\8e;:S-:'j~~ \ ~-~~la .</ ,'\OfP Ii ;Q -_....~\ "'-";/ ..----;::.;.'.- -.!,'~~-~~. .:if ~; f~ ~''';:~''''-o/ 1-- -.- I~ 11::>: 1<: r----;/~'" "'_ ,-,;.?;;'Y""';9- ~3!f(-~":-;..r' I---}-"G~f ),,1 Iii ,p^", ';;0 /0 ~~\' '\. (I It -"'~ :.i~'f{f~ ,,~:~ 7' ' 1 r1'O""~ , l,f~). ~' \i.c;,~ '>"t;< ffii~tt?,~ ~ J \, Course ~v ,.;1 I! ~ ~ l" lii,<< \( ~:~I,i~~ ~f! (e ':I (Q\ I C1l!/ If' r:.__~~__'" ".-t _,,~,=-- /' '\ \... r ..:::;" ~ ~fI-:l.... ~ ~ l ~ E it P LY . "F ]~".--~~~ - /' ~*t~~s-:2.~ 1----;: }\ ~", ?I,f~ II ~1!T: t: ~. ,,61:, / 'fON~'( \ -'_IN -...... ' ""'----~!, Ii ,q';,. { ". h" I ffi: ~ I' ',., '''''~'' " "~"" ,~,' /I '\,.; e"_~'-< 'jl .......~ .-, ....,.}~, 1"1 "'0<;' _" ... Il I ~....'-...... t',.' ~r-~~ ~:>..a..\.A-\ -m ',,-'t~1 -71i'l-O i~ ',.well / 1--~ I ">-zc--- .,(',>1; ~ +~~."q.._, _ ~ ~~ "I. II 11,g-t-~. p"",-, + / ,,*' / ~ ~~"l~ "t' '-, -~~~ ~r !~\ !l it/) t '//)<: *~ I .....}"", ~ l\\'~-:'- Golf ,t~=,,;l/ _ / I ,1 I I, ::y;' ' , ",' ,r., f"\ , ,~.--=r..: <>""",- / 'V I f,,),._~, It," ::,- \'31'.---==:::::::,.-.....---"". ,," " '\' ,-~ "'<.:,- I - 1;1/ ... 't~;--'- ~_........ & I"':;, "fDl~l" '" '" -- 't "1 ~ 1~.(,'''''_IO"O '. 11,>/ Ii! 1_;~~~2~'~1' t _JcK~rs::-~, ,....IF ",~IJ:~..l' \'.... ~:::y.... X.,,-/O/F p ~ ['~'!' "'"~ I, -~" _ ~ ,=- I "I::.... '-c"-1A' \' '\ ' V '" >,!-(,::;" .. - \",~-,--- '--1- ,~'~~r -", -./' \ / '" ~-\, \ ;.-J:-:::__- :,,~ ,'~, \I/~l'-\ ' ~- 'L '" '," \' .... ~-'I ' ~ J ',\ ~.' '-,n.:.,,"" 1 .""d,_",'0"7'",,~'\i::" ,,,,,,,,./, ~" , .<' "\): 1~;jYf-'~'i.;'?:";(;--&.! _,.,.......~)- 'j1/ l.t:; " Pc_ - \ -,'" J<.- 'y ,..-\c.r~ ( . -.~ -, ~~' /r'.'t:'!2. I ~~~ .'.....' J/!i::'" ~P!~.x. (\ -:- 1:!f..(lr..... ...~....J{\~(,. . \./ J,,-,,-,.,::-_,I .,.' 'e>-' ?f;iji~"";"0:'d~)~J;:--:-:~:V"~~)? - , '" V ,'). '-~i~'t"("--\r$..~\\\Jlt,- ' f ~t'lrll~l<'-'f~_~~'_ .... ~:, 7 ~(l~':..:.,=- :;___~:/!-(f::Ii..../ ,11[-';',:S:-~')U:.-' ~) (/'--N,. ,'i......- , ''--,---- ' '--"___~'~.,. 'r'::::s...,____=-,,_v-:-,'-<l> -.' '"7 ~Y ,~^iJ : "rtr'\I' _ /_;,,- .. J<<, __~.-, , / , " -'-,~' ~:;:~-:.q 1)~;-iJ~';.zt..--, ~.r~~'~~tl;~,-; ~~~ A \ I '__, ~.,~~ ,~~~~':0~~t~;j"~;\I~'~~~ ./ "- rv'-~;"f4f~~-:::'\ ~~'- - ~~~~~>'-l\..\'ti"~"''-L( ~ '" ~ \~~ ,~:ftj::::.~'~[,~q!.iJiz~~:- (~~~~~"~"~'~~1.2)-?{ ~~'~2E'\", )/"".::) - "J, ,?,",--' . ,',;-- ~ ~::"";_,~~,,--, ~"~",--r----:-- ',', 11,0 __ ,. __,)i!J,Ij,~ ,~ ,~,,,..~=~--,_,,~_,,,,,_ -~J ,-, ""0,[, I / kf. fc; \// / /, /' ,~10 ..., ..b .. t I I I I I 1 l I i , I \ ~. I I I I <' ", . - ~ / I I SOURCE: U.$.G.S. 7.5' topographic series. Temeculo and Pechenga. California quadrangle doted 1968, photorevised 1975. o I FEET , 2.000 I KLEIHFELOER Project: 25423 February 2003 c: I PROPOSED RAINBOW CANYON SHOPPING CENTER SEe and SWC Pechenga Pkwy. and State Hwy. 79 Temeculo, California LOCATION MAP OJ? ---_._~------------- ----~~ I en ~ rT{ ~ o c: rT{ ~ I ~ ) ~;I //1- - I ~'.A __>-_00 I - - I "'J V:> - ~! . 0 1$/ ~/ I / - / / I ff m_'!2~ ~~Gl_ ~~~ mijiGl ~o o z ., -"'1l ~~ "". .,. <-. ~ - ~ ~ -~~ ~~~ ml;fGl go I 0 z - arO& HJ.iivs~a3r~__ _ ::::-- , -- --------- -- -, C) c: rl\ z o s: Z m o~ <0 > ~fr"lJ ~b~~ ,,0-<0 >:--lU)x ~OO~ -fir'-< ~"lJ rr1 lJ 0.> .., (j CD - - OJ - lJ 0.> .., (j CD - o~ ~o >- ;t]lrlJ ~b~~ Q~vI~ lioo~ ::j~"'TJ'-I o'il m Z ~, I I '" m I I I I ..... ...... f'T1 N 111 X l-o-~~ z c \) )>. }> ~ :u '1J -t i;j ';; :lJ - o 0 0 o c X Z ." Ul ~ rr1 VI ~ Z 0 m <i) - - .-- VI .~ CD Q m 0 .-- '" '" m - OJ o Z 0 <i) '" ~ r Z r= 0 <i) " m ~ 5 Z 0 " ~ z ~ 7- 8 ~ Z ' ~ (j) .- o m ^ ~ .Z Ej '" Z '0 M g 5 ~ m -'" '" o o "" -0 ITS ~ -~ II,,',' .; ;u m M ;u m Z " !OJ '1J ~-o OJ .9. 0::0 rn ~ DO rr1 n 0 1l rt 0.0 ~ VI > tv UlrTl '1J y;, ~o L) ",,,~ ;0 (A -f~Z ~ (tin OJ 0 30'0 m ~ g::e 0 ,fj-"J 5l ~ o;?~ z ~~ E; _. m QoV) r 5'~8 ?o 1l " 3: ~Jl ::!: o 0 Z -I ..., ......(;1 fT1 n. " :r IO ijj t5 ~~~ ~- o' Z \..<..I;j .r r 0 " ~ o o '" '- '" '- o '" ~ ^ M z -., f'l 5 f'l '" -u r- o -i -U !j;: Z ./ ~ - I , I \ I i I I ! , I I ; I ~ I i I I i I, I ! I I l I i , i ~ I , - i I I I k~ KlEINFElDER APPENDIX A EXPLORATORY BORINGS The subsurface exploration program for the proposed project consisted of the excavation and logging a total of fifteen hollow-stem auger borings with a truck-mounted drill rig. Borings' B-I through B-Il were drilled on January 10, 2003 and borings B-12 through B-15 were drilled on March 10, 2003. The drill rig was furnished by Cal Pac Drilling of Calimesa, California. The borings were advanced to depths ranging from approximately 612 to 51-v:' feet below existing grades. All borings were backfilled using the soil from cuttings and tamped when the drilling and excavating was completed. Plate 2 presents the approximaTe locations of the borings. , The Logs of Borings are presented as Figures A-2 through A-16. An explanation to the logs is presented as Figure A-I. The Logs of Borings describe the earth materials encountered, samples obtained and show field and laboratory tests performed. The logs also show the location, boring number, drilling date and the name of the logger and drilling subcontractor. The borings were logged using the Unified Soil Classification System. The boundaries between soil types shown on the logs are approximate because the transition between different soil layers may be gradual. Bulk and intact samples of representative earth materials were obtained from the borings. A California Sampler was used to obtain relatively undisturbed samples of the soil encountered. This sampler consists of a 3-inch O.D., 2A-inch LD. split barre[ shaft that is driven a total of 12- inches into the soil at the bottom of the boring. The soil was retained in one-inch brass rings for laboratory testing. An additional two inches of soil from each drive remained in the cutting shoe and was usually discarded after visually classifying the soil. For borings B-1 through B-ll, the sampler was driven using a 140-pound down-hole hammer falling 30-inches, For borings B-12 through B-15, an auto hammer was used to drive the sampler. The total number of hammer blows required to drive the sampler the final 12-inches is termed the blow count (N) and is recorded on the Logs of Borings. Bulk samples of the surface soils were obtained directly from the auger blades and the test pits. 25423/DBA3R041 Copyright 1003, Kleinfelder, Inc A-I March ] 8, 2003 f>lo I I I I - I i , - ! I I i I I - I I I I I I I I Date Drilled: Water Depth: Drilled By: Date Measured: Drilling Method: Reference Elevation: Logged By: Datum: 0 ~ '" 1> ~ c~ 0 t-i: z ::>~ -' GEOTECHNICAL DESCRIPTION 'iij ~ "0 c 0- c "'~ 0 '" .!l! 0--""" .~ AND '" LC C :'::;___.l:: a. '" .32 0 Q. ;0;0 .c Cl~ :;:.(() o~~ E E Q. CLASSIFICATION - .~ t: .-~ > '" 0. 0.2 0 CO "0", "''''''' 0 0 -(0 L Cl~ 00 "0", w~ Vl Vl ClJ~ 0 ::;;0 <0- 1 6 108 10 OS, SE .~. ." ,,' 2 12 .' GS 5 (1 ) (2) (3) (4) (5) (6) (6) (7) 10 NOTES ON FIELD INVESTIGATION 1. SAMPLE Split Spoon Drive Sample Bulk Sample Tube Sample - Graphical representation of sample type os shown below. St(mdord Penetration Test Sample (SPT) - California Sample (Col) - Obtained by collecting cuttings in 0 plastic bog - Shelby/Pitcher Tube Sample !TIll IDIII~ o 2. 3. SAMPLE NO. - Sample Number BLOWSjFT - Number of blows required to odvan~ sampler 1 foot (unless 0 lesser distance is specified). Samplers in general were driven into the soil at the bottom of the hole with 0 standard (140 Ib) hammer "dropping 0 standard 30 inches. Drive somples collected in buck.et auger borings may be obtained by dropping non-standard 'lI'eight from variable hei9ht~. When 0 SPT sampler is used the blow count conforms to ASTM 0-1586. SCRjRQO - Sample Core Recovery (SCR) in percent (X) ond Rock Quality Designation (ROD) in percent (Yo). ROD is defined os the percentage of core in eoch run which the spacing between naturol fractures is gre<lter thon 4 inches. Mechonical breok:l of the core ore not considered. GRAPHIC LOG - Standard symbols for soil cnd rock types, as shown on plate A-.l b. GEOlECHNICAL DESCRIPTION Soil - Soil classifications are bosed on the Unified Soil ClassifICation System per ASTM D--2487, and designations include consistency, moisture, color and other modifie~. Field descriptions ho....e been modified to reflect results of laboratory ornllyses where deemed appropriate. Rod - Rock c1ossificalions generally include a rock type. color, moisture, minerol constituen~, degree of weathering. alteration, ond the mechanical properties of the rock. Fabric, lineotions, bedding spacing, foliotions, and degree of cementation ore olso presented where appropriate. Description of soil origin or rock formation is placed in brackets ot the beginning of the description where applicable, far example, Residual Soil. DRY DENSITY, MOISTURE CONTENT: As estimated by laboratory or field testing. 4. 5. 6. 7. properties other than the above): SG - SpecifIC Gravity HA - Hydrometer Analysis AI.. - Atterberg Limits FN - R-Value CN - Consolidation CU - Consor.dation Undrained Trioxial CO - Consolidated Drained Triaxial ADOrrlOt-tA.L TESTS - (Indicates sample tesled for MAX - Maximum Dry Density GS - Groin Size Distribution SE - Sand Equivalent EI - Expansion Index CHEM - Sulfote and Chloride Content, pH, Resistivity PM - Permeability UU - Unconsolidated Undrained Triaxial pp - Pocket Penetrometer WA - Wash Analysis OS - Direct Shear CP - Collop:;e Potential UC - Unconfined Compression T - lorvone 6. ATITIUDES - Orientation of rock discontinuity observed in bucket auger boring or rock core, expressed in strike/dip and dip ongle, respectively, preceeded by 0 one-letter symbol denoting nature of discontinuity os shown below. 8: Bedding Plane J: Jointing c: Contact F: Fault s: Shear In. KLEINFELDER PLATE EXPLANATION OF LOGS A-1 CA1 I I I I i , I , I I I i I I I , i I I , I I I I I I I ::< ~ ~iO g ~n:~ 8 <,t=:Vi z zS~ ~ ::<~in ~ ~~o lQ ~s~ ~ OQ::'" o ,,~ u ~ J ~ Oaw : ~~" z :ZVl~ ~ ~"': w ~"Ig ~ 03"- "jji ~ ,,~~ ~~ffi ?=~i e UNIFIED SOIL CLASSltlCATION SYSTEM (ASTM 0-2487) SECONDARY DIVISIONS PRIMARY DIVISIONS GROUP SYMBOLS ow 00 '=> WELl GRADED GRAVELS, GRAVEL-SAND MIXTURES, UTTlE OR NO FINES 0.0.0. ~ ziQ~:< ~."-z'" ~~8~FG < Wl...;: 15Vl ~gjO~~:, :<~L..:S ;l' CLEAN GRAVELS (LESS 'THAN) 5% FlNES GRAVEl WT1H FlNES CLEAN SANDS (USS THAN) 5" FlNES SANDS WT1H FlNES GP .~.~.~ POORLY GRADED GRAVELS OR GRAVEl-SAl'40 MIXTURES, 1J1TLE OR NO FINES ~ SILlY GRAVElS, GRAVEL--sp.ND-SILT MIXTURES 7.17~ CLAYEY GRAVELS, GRAVEL-SAND-CLAY t.AlxnJRES w ::<iQ~:< Vlx8;i:~ O~ O~- zl.<,J1.....j::. Vl ~c::O~ ~ o ~ ' :::E~l.o.~ ;l' o ::<~ 1'!:5 ~u in o 91- U11l) ~:::;:lflVl~ o~-w :J~ ~ GM GC sw WELl GRAD(() SANDS, GRAVEllY SANDS, LITTLE OR NO nNES POORLY GRADED $.ANDS OR GRAVEllY SANDS. UTTLI OF: NO FINES o ::<~ 1'!:5 ~u in Qt:: ~g 5a~i5~ :J~ ~ " SP SM SC ....' " ..... HIGHLY ORGANIC SOILS S6.NDSTONES SILTSTONES ClAYSTONES Ul.lESTONES SHALE ML SILTY SANDS. SAND-SilT ~~[XTURES ClAYEY SANDS, SANr-ClA''f MIXTURES INORG.'IN1C SILTS, VERY FlNE smDS, ROCK flOUR, SILTf OR CLAYEY FINE SANDS INORGANIC CLAYS OF LOW TO MEDIUM PlASTICITY, GRAVEl.lY ClAYS, SANDY CLAYS, SilTY CLAYS, lEAN CLAYS ORGANIC SilTS AND QRG.ANIC SILT-CLAYS OF lOW PlASTlCTTY INORG.A.NIC SILTS, MICACEOUS OR DIATOMACEOUS FINE SANDS OR SILTS, ElASTIC SilTS INORGANIC CLAYS OF HIGH PlASl1crTY, rAT ClAYS CL OL I I I MH CH OH ///://f;(/o /f//fdf/ ORGANIC ClAYS OF MEOIL1M TO HIGH PlAST1C1TY, ORGANIC SILTS PEAT, MUCK AND OTHER HIGHLY ORGANIC SOILS PT SS SH II ~ cs LS SL CONSISTENCY CRITERIA BASED ON FIEL.D TESTS ~. CONSISTfNC'(- TORVANE POCKET .. RElATIVE DENSITY - COARSE - GRAIN SOIl FINE-GRAIN SOll PENETROMErER . NUMBER OF BLOWS OF 140 POUND H.lMMER UNDRAINED UNCONFINED rAUJNG 30 INCHES RELAlNE SPT . REtATM SPT TO DRrv'[ A 2 INCH 0.0. DENSIT'( (I blows/tt) DENSITY (X) CONSISTENCY (I blows/ft) SHEAR COMPRESSIVE (1 Jl8 INCH \.0.) STRENGTH (hf) STRENGTH (hf) SP BARREl SAMPLER Very Loose o - 15 Very Soft (ASTt04-1586 STANDARD <4 <2 <0.13 <0.25 PENETRATION TEST) Loose 4 - 10 15 - 35 So" 2 - 4 0.13 - 0.25 0.25 - 0_5 .. UNCONFINED l.4edium Stiff 4 - 8 0.25 - 0.5 0.5 - 1.0 COt.4PRESSlVE l.4i!Klium Dense 10 - 30 35 - 65 STRENGTH IN Stiff 8 - 15 0,5 - 1.0 1.0 - 2.0 TONS/Sa.FT. Dense 30-50 65 - B5 READ FROM POCKET Very Stiff 15 - 30 1.0 - 2.0 2.0 - 4.0 PENETROMmR Very Dense >50 85 - 100 Hard >30 >=~.O >4.0 DESCRIPTlON Dry Moist Wet MOISTURE CONTENT FlElD TEST Absence of moisture, dusty, dry to the touch Damp but no visible water CEMENTATION DESCRIPTION FlELD TEST Weakly Crumbles or breaks with hondiing or slight finger pressure ~oderately Crumbles ar breaks with cons:derable finger pressure Visible Iree woter, usually soil is below water table Strongly Will not. crumble or break with finger pressure IOIIKLEINFELDER PLAIT EXPLANATION OF LOGS A-1B Ao~ 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 Date Drilled: Excavated By: Drilling Method: Logged By: 1/10/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Depth Date Measu Elevation: Reference I ~ SOIL DESCRIPTION ~ ~~ ...., '" AND ..., 0 0 " " 0 H 0 ... z "'" CLASSIFICATION ." 0'- 0 ..., ~ ~ u . ." . ..., '" .... .-< ~ '" > ...., ~ ~ ~ 0 '" ~ . '" 0'-< . .... '" . ....'" " ., -Q '" '" , "'- " 1010 5 1000 7 40/6" 39 1005 2 10 3 28 50/5" 15 4 24 995 20 5 27 990 25 6 23 985 30 ARTIFICIAL FILL (An: Silty Sand (SM): brown, moist, fine to me some coarse gramed sand, dense. -- Abrupt color change to gray, increase, in sand, mIcaceous, -- Fine grained, trace medium to coarse gr -- Mottled brown and dark gray-brown, tra grained sand and clay, , , -- At 25 feet a sanitary sewer line belong in Municipal Water District was encountered ALLUVIUM ~ Sand (SP): lig t gray-brown, wet, [me to rained trace coarse rained sand. ve!Y..ill: Total depth 30.5 feet. Boring terminated due to encountering uti Boring left open and barricaded to allow r III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING Drafted by:~Re\'iewed by: Explanation To Logs On Plate A-I >30.5 red: 1/1 0/03 1012 )atum: MSL ..., '" '" ." ~ ~ - ~ '" .... ~ . ~'" ...,- . " 0'- ." '" " ..., o II} fJl S " 0 " " ..-1 +J 01 P 8 ..., . +l ll) 1j 04 . ..., ..-1 1Il...-t >. ." " '0 ... . ~ o 0 '0 ." Q :>:u .; "' dium grained, fine grained 124 10.1 ained sand. 96 10.2 ce coarse 109 lOA g to Eastern medium 'nse. lity. epair by EMWD. yon S'hopping Center PLATE a Pkwy and Highway 79 A-2 B-1 A.~ I , I I I I ~ I i I , I , , I i I i i , I , I , I I I I I I Date Drilled: Excavated By: Drilling Method: Logged By: 1/10/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference k SOIL DESCRIPTION m .:iJ m ~ "' AND ~ " .... 0 0 " " 0 .., 0 " z "'" CLASSIFICATION .rl 0--" " .... :iJ", m m u . .rl . '" .-< ~ '" > m.... 0. 0. ~ 0 Ii' m mo. . . 0'-< .-< '" m . . .-<.!l k '" -0 " <Il "'- " ]010 5 ]005 3 53 43 ]0 2 37 1000 15 ARTIFICIAL FILL (At): Silty Sand (SM): brown, moist, fine to III sand, some coarse sand, trace gravel, dens -- Increase in fine grained sand, micaceou asphalt debris. ALLlNJUM (Qal): Silty Sand (SM): brown, moist, fine grain hard. Total depth 16,5 feet. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: >16.5 ured: 1/10/03 1012 Datum: MSL .... '" "' .rl " m m l< .. .-< m - . k" ....- m " "--.. .rl '" k.... o II) C1J e " " " " .rl .... 0. DE; .... m +I ell "O~ ..... .,.,j Ql..-i :>. .rl d '0 " m k o 0 '0 .rl 0 :>:u <( .. edium grained e. s, gravel sized 118 9.7 ed, micaceous, 96 16.1 WA, CP 12l 8.7 yon Shopping Cent"r PLATE a Pkwy and Highway 79 A-3 B-2 ~C Drafted by:_Reviewed by: Explanation To Logs On Plate A-1 I I I \ I , I ; \ , I ; - , I I I I i I , , , I I . i I \ , I I I , I I I Date Drilled: Excavated By: Drilling Method: Logged By: 1/10/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION ~ m:iJ ~~ '" AND .., 0 0 a a 0 H 0 E-< Z ~'" CLASSIFICATION 'M 0..... 0 .., ..'" ~ ~ u m 'M ~ .... .... . '" > ~.., ~ ~ . 0 '" ~ ~'" 0.... ~ .... "'~ ....,Q " .. -0 to to 1Il- " 1010 X ~ .f ~ -- 5 57 1005 ]0 1000 6 5013" 3 36 15 4 44 995 20 5 39 50/3" 990 25 ARTIFICIAL FILL (Ai): Silty Sand (SM): brown, moist, fine to m some coarse gramed sand, dense, -- Some gravel. -- Slightly mottled - brown and gray-brow -- Dark brown, increase in fine grained sa ALLUVIUM (Oal): Silty Sand (SM): gray-brown, moist, fine Sand (SP): light gray-brown, moist, mech some coarse grained sand, dense. ) \ -- Light olive, medium to coarse grained, iron oxide staining, occasional silty lense -- Li ht a -brown. Total depth 25.5 feet. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: >25.5 ured: 1/10/03 1012 Datum: MSL .., '" '" 'M a ~ - ~ s: ~ .... ~ ~ ".. ..,~ ~ a 0..... 'M '" ".., o CIl tr.l a a 0 ~ a 'M .., '" p.!;< .., ~ +' In "0 Ol ..., .ri Ql..-i >< 'M a "'E-< ~ " o 0 ~ 'M 0 :>:u .. edium grained, WA,DS,MAX n. 124 10.1 nd. 102 6.9 grained, dense. 109 6.8 . ilm grained, - - - - seams of heavy 107 4.0 s, trace fine roots. r yon Shopping Center PLATE a Pkwy and Highway 79 A-4 B-3 5\ Drafted by:--Reviewed by: Explanation To Logs On Plate A-1 I I ., I I I I ; I I - i I ! I I I I I I ! I I I I I Date Drilled: Excavated By: Drilling Method: Logged By: III 0/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION ~ ~~ .+> '" AND +> 0 0 " " 0 H 0 H Z "'" CLASSIFICATION ." 0'- u +> . ~ u . ." ~ +>.c rl rl ~ .c > ~+> 0, 0, ~ 0 0, ~ ~ 0, s ~ Orl ~ rl '" . ~ rl'" " ., -Q <Il '" "'- " 1010 5 ]005 50 10 2 36 1000 15 3 30 995 20 :'.>'., 4 30 50/5" ARTIFICIAL FILL (At): Silty Sand (SM): brown, moist, fine to me trace coarse grained sand, micaceous, dens -- Darker brown, increase in silt. ALLUVIUM (OaI~ Sandy Silt (ML): rown, moist, stiff, tra grained sand. Sand (SP): light brown, moist, medium g coarse grained sand, very dense. Silty Sand (SM): brown, moist, micaceol trace cia . ve dense. Total depth 21.5 feet. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING Drafted by:_Reviewed by: th: >21.5 ured: III 0/03 1012 Datum: MSL +> .c '" ." " . - . :< '" rl . ~ "'" +> - . c u'- ." '" " +> o r1J t/] e " u " " ." +> 0, p~ +> . +J II) '00-4 .+> .,-l 4I.--t >< ." " " H . " o 0 " ." Q :>:u <( .. dium grained, e. 112 7.7 109 3.2 WA,CP ce medium 102 15.1 WA,CP ----------- rained, some -----------. IS, fine grained, ,t yon Shopping Cent"r PLATE a Pkwy and Highway 79 A-5 B-4 ~z., Explanation To Logs On Plate A-I I I l ~ I , I , i I ! I , , I, I - I I I i I . I I I , I i I I I , I I I Date Drilled: Excavated By: Drilling Method: Logged By: 1/l0/03 Ca1 Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION . · 'i! m" '" AND g; , " 0 0 " " 0 ,., 0 .. z ,,, CLASSIFICATION 'j 0'- " Z" . . u m ... . .... .... . " > ." ~ ~ . 0 '" . . '" 0.... . .... " . ....'" " '" -Q m " "'- " 1010 5 1005 43 10 2 28 50/5" . 1000 15 3 61 995 20 4 55 990 25 5 23 985 ,', 30 6 30 50/3" .... ARTIFICIAL FILL (Af): Silty Sand (SM): brown, moist to very m medium gramed, some coarse grained san medium dense. -- Some gravel, nail in tip of sampler. -- Bit chatter. -- Gravel sized asphalt debris. -- Color change to gray, -- Dark gray, moist, fine grained, micaceo ALLUVIUM tOal): Sand (SP): hg t gray-brown, moist, med trace coarse grained sand, very dense, Clay (CL): green-gray, moist, with silt, \ SaDd~p~l~ht~ow~moG(meilillint very dense, Total depth 31 feet. Groundwater not encountered. Boring backfilled with soil cuttings. HI KLEIN FELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: >31 ured: 1/10103 1012 Datum: MSL " .<: '" ... " . - . t'< '" .... . . "'" ,,- . " "'- ... " "" o 0'1 rn e " -~ ' C .r-i ~ Ol D_ " . +J III 'OJ).. m" ..-l Ql.-i i:i' ... c " ... . o 0 " ... Q :>:u <( '" oist, [me to d, trace gravel, 122 6.2 liS, very dense. 109 12.4 , ium grained, 106 2,3 ------------ 83 30.3 'ery stiff. ------------ o coarse grained, yon Shopping Center PLATE a Pkwy and Highway 79 A-6 B-5 :5~ Drafted by:~1Zeviewed by: Explanation To Logs On Plate A-1 I ; -!,. I ! I I I , I ! I i [ I , , I i I i I , , * i , I [ I , I I I Date Drilled: 1/1 0/03 . Excavated By: Cal Pac Drilling Drilling Method: Hollow Stem Auger 8" Logged By: D. Hasham Water Dep Date Meas Elevation: Reference ~ SOIL DESCRIPTION G ~~ . " '" AND .... 0 0 " " 0 " 0 H :>; "" CLASSIFICATION ." 0'- 0 " "'" G G U . ." ,. .... .... . .a > G.... '" '" . 0 '" G G '" ~ ~ 0.... ,. .... " G .....Q ~ ., -0 U) U) lll- " - - ]010 - - - 511 1005 - - - 10- 2 ARTIFICIAL FILL (AD: Silty Sand (SM): brown, moist, fine to m some coarse gramed sand, trace gravel, m ALLUVIUM (Oal): Silty Sand (SM): dark gray, slightly m micaceous, carbonate filaments, dense. ; , 52 44 '{ -- Gray, dense, decrease in silt as boring d -1000 - - - 15 . ,------------------------- :1':::< Sa~d (SP): gray-brown mottled with iron ':: ,:< gramed, mIcaceoUS, dense. 3 39 ,'...: Total depth 16.5 feet. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING OIS th: >16.5 ured: 1/10/03 1012 Datum: MSL " .a '" ." " . - . t<, '" .... . ,. ~'" ,,- . " 0-... ." " ~.... o C1 tI) I'! " 0 " " o..t ~ ~ ::>~ " . +l Ul "'Cl~ ..... .rl Ql rl " ." " 'tl H G ~ o 0 ~ ." 0 :>:u "' , edium rained, edium ense. t, fine grained, 114 9.5 WA,CN epth increases. 98 14.2 .----------- oxide, fine 98 10.3 yon Shopping Center PLATE a Pkwy and Highway 79 A-7 B-6 5L\ Drafted by:_Reviewed by: Explanation To Logs On Plate A-I I I I I I - i I I I I I l i I I i I , i I , * , I I I I Date Drilled: Excavated By: Drilling Method: Logged By: III 0/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION . ... · 1l '" AND ~ " .., 0 0 a a 0 ., 0 .. z " '" CLASSIFICATION ." 0'- " .... ..'" . . u . ." " .... .... ~ '" > ..., 0. 0. ~ 0 0. . . 0. e ~ 0'" " ... '" . . .....0 " ., -0 " <Il "'- t'J 1010 5 1005 31 10 3 39 : " JOOO : " : .' : , 15 4 69 ARTIFICIAL FILL (An: Silty Sand (SM): brown, moist, fine to m trace coarse grained sand and trace gravel ALLUVIUM (Oal): Silty Sand (SM): tan, moist, fine grained gramed sand, medium dense. -~AJg~ffi~t_________________ Sand (S1'): gray brown, moist, fine graine dense. -- Medium grained, trace coarse grained s Total depth 16.5 feet. Groundwater not encountered. Boring backfilled with soil cuttings. IfI KLEINFELDER Proposed Rainbow Ca SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: >16.5 'ured: 1/10/03 1012 Datum: MSL .., '" '" ." a ~ - . ~ .... . " ~.. ....- . a 0'- ." '" ~.., o III CflES a " " a ." .., 0. ::>~ .., . +l Cll '0 0.. . .., .ri al r-l >< ." a -00< . ~ o 0 ~ ." 0 :<:u "' edium grained, , medium dense. , trace medium 94 3.7 WA,CN EI 101 8,9 ----------- d, some silt, and. 109 3.2 I nyon Shopping Center PLATE a Pkwy and Highway 79 A-a -5 B-7 S Reyiewed by: Explanation To Logs On Plate A-I Drafted bY' I i .' I I - , I , I ! I , , I I I I , I I I ! I i I I I I Date Drilled: Excavated By: Drilling Method: Logged By: III 0/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION . ~~ .., '" AND ., 0 0 c C 0 H 0 .. z "" CLASSIFI CATION .e 0-'" " ., ",c . . u . .e .. ... ... ~ ,C > .., ~ ~ ~ 0 0. . .0. 0'" .. M ". M.Q " ., -Q '" '" lIl- t!> ]010 5 34 1005 , .' " 10 , 2 37 , .' " ] 000 , " " , .. 15 , .. 3 61 ARTIFICIAL FILL (An: Silty Sand (SM): brown, moist, fine grain ramed sand and avel medium dense. ALLUVIUM COal): Silty Sand (SM): gray-brown with iron ox slightly moist, fine grained, micaceous, m Sand (SP): gray-brown with iron oxide st fme grained, dense, -- Increase in coarse particles. -- Light gray-brown, fine to medium grain -- Medium to coarse grained. Total depth 16.5 feet. Groundwater not encountered, Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: >16.5 ured: 11l0/03 1012 Datum: MSL .., ,C '" .e C . . ~ ... M . - ~ "'" ..,- . "-... .e " " .., o OJ Ul E C " " C .rt +J III D~ .., . +J III .tH4 . .., ... . M '" .e C " .. . " o 0 " .e Q :>:u -: .. ed, trace coarse ide nodules, edium dense. 98 5.0 WA,CP ------------ aining, moist, 95 7.0 ed. 103 11.4 F yon Shopping Cent"r PLATE a Pkwy and Highway 79 A-9 B-8 ,~ Drafted by:_Reviewed by: Explanation To Logs On Plate A-I I I I i I - I i I I I - ; I I , I I , I i , I I I I I Date Drilled: Excavated By: Drilling Method: Logged By: III 0/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Measl Elevation: Reference " SOIL DESCRIPTION ~ ~~ . .., '" AND .., 0 0 " " 0 H 0 '" z """ CLASSIFICATION .rl 0..... 0 .., ~ ~ u . .rl .. ..,'" .-\ .-\ ~ '" > ~.., 0. 0. ~ 0 0. ~ ~ '" ~ ~ 0.-\ .. .-\ "" ~ .-\,Q " '" -0 '" '" lll- " ?:.1 1010 ~ ~, oF ~ 5 1005 22 2 30 10 3 ARTIFICIAL FILL~An: Silty Sand (SM): dar broviIl, moist, fine coarse grained sand and ravel medium d ALLUVIUM (Oal): Silty Sand (SM): brown, moist, fine grain \ dense. S-andy siir(KIL):-brown- withiron -ox[(ie S moist, fine grained, carbonate filaments, ill stiff. -------------------------- Sand with Silt (SP-Sl\f): brown to gray- fine grained sand, medium dense. Total depth 11.5 feet. Groundwater not encountered. Boring backfilled with soil cuttings. HI KLEINFELDER Proposed Rainbow Ca SEC and SWC Pee hang Temeeula, California PROJECT NO. 25423 LOG OF BORING th: >11.5 Ired: III 0/03 1012 Datum: MSL .., '" '" ... " ~ - ~ il: ... .-\ ~ .. ".. .., - ~ " 0..... ... "" " .., o D'l [I) i:: " 0 " " .rl .., 0. ::>8 .., ~ +I 11l "00. . .., ..-4 (D M >< ... " 'tl '" ~ " o 0 'tl .rl 0 :>: u .; .. grained, trace r ense. ed, medium WA, MAX I ,_________.J 90 16,0 ~ains, slightly Icaceous, very .------------ brown, moist, 94 12.6 nyon Shopping Center PLATE a Pkwy and Highway 79 A-10 B-9 '"51 Drafted by~Reviewed by: Explanation To Logs On Plate A-I I .' I I I ( - ~ - I I i I I I I I i I I ; i - I ! I I I I Date Drilled: Excavated By: Drilling Method: Logged By: 1/10/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham WaterDep Date Meas Elevation: Reference ~ SOIL DESCRIPTIO N C .:;J . ~ '" AND +J 0 0 a ~ ~ a 0 .., 0 .. z ~" CLASSIFICATION .rl 0..... 0 +J C C U . .rl . +J.c ... .... . .c > C+J 0, 0, . 0 0, C C 0, e ~ 0.... . .... " . . ....'1 " ., -Q " tIl 1Il- l!I -x 1 -I{ -" -x 1000 5-:: n 2 20 - - - 995 10 3 59 - - - ARTIFICIAL FILL (At): Silty Sand (SM): dark brown, moist, fine gram ed, with coarse grained sand and grav '\ dense. \-- Decrease in gravel to trace. ALLUVIUM (Oalt. Clayey Silt (ML): brown, moist, pin pore filaments, stiff to very stiff, ------------------------. , Silty Sand (SM): brown with iron oxide s " ' fine grained, medium dense. Sand (SP):Ii"ght-brown-with-sTIgh'tTroil ox moist, medium to coarse grained, very den Total depth 14 feet. Boring terminated due to refusal. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEIN FELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: >14 ured: 1/1 0/03 1005 Datum: MSL +J .<: '" .rl a C - C l3' ~ .... C . ~.. +J - . a 0..... .rl " " +J o tll t1l E a 0 ~ a ..-1 +l 04 D~ +J . +l GI 'd ~ . +J '" C .... >. .rl " 'l:l .. C " o 0 'l:l .rl Q :>:u .; .. to medium el, medium I RV S and carbonate 111 16.3 ------------ tains, moist, .----------- 109 2.0 -ide staining, se. I I yon Shopping Cent"r PLATE a Pkwy and Highway 79 A-11 B-10 ~ Drafted by~Reviewed by: Explanation To Logs On Plate A-I I I I I I I ! I I ~ I i I , i I 1- , I , i , , I ! I I ! I I , j I ; I i I I Date Drilled: Excavated By: Drilling Method: Logged By: 1/10/03 Cal Pac Drilling Hollow Stem Auger 8" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION . ~~ ..... l> AJ\'D .... 0 0 a a 0 ,., 0 .. z ~'" CLASSIFICATION ." 0'- 0 .... ~.<: . . " . ." . .... .... . .<: > ..... '" '" . 0 '" . . '" ~ ~ 0.... . .... '" . .....a " ., -co CIl CIl ..- '" - !~111 ARTIFICIAL FILL (An: Silty Sand fSM): brown, moist, fine to - trace rave, medium dense_ - -- Cob les encountered. - , f- ]000 5 2 44 , Total depth 6.5 feet. Boring terminated due to refusal. Groundwater not encountered, Boring backfilled with soil cuttings. HI KLEINFELDER Proposed Rainbow Car SEC and SWC Pechang Temecula, Caiifornia PROJECT NO. 25423 LOG OF BORlNG m th: >6.5 ured: III 0/03 1005 Datum: MSL .... .<: '" ." a ~ . '" .... . - . "'" .... - . a 0'- ." '" " .... o 0'1 tI] a a 0 ~ a ." .... 0. D~ .... . +J D) "tI ~ . .... ..-1 C1l M >1 ." a '0.. . " o 0 '0 ." co ;,:" .; .. edium grained, 'yon Shopping Center PLATE a Pkwy and Highway 79 A-12 B-11 ~ Drafted by:_Reviewed by: Explanation To Logs On Plate A-l I I I I I i I ; I I I , I I I , I I I I I I I I I Date Drilled: Excavated By: Drilling Method: Logged By: 3/1 0/03 Cal Pac Drilling Hollow Stem Auger 6" D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION ~ ~:iJ ~ il t> AND g; ~ .... 0 0 a a 0 H 0 E< Z ~" CLASSIFICATION ,~ 0..... 0 .... :iJ.<: ~ ~ u ~ .~ . .... .... ~ .<: > ~.... ~ ~ ~ 0 Po ~ .Po 0.... . .... " . ......0 " ., -Q OJ OJ 01- t!l - 1010 - - - 5- - ~1005 - - - 10-"" 1 -j" 1000 - - - 15-, 2 -~ 995 - - - 20-~ 3 -~ 990 - - - 25-" 4 -~ ~985 - - !: - 30-... 5 -~ ~980 - - 13 31 30 55 " ARTIFICIAL FILL (AD: Silty Sand (SM): brown, moist, fine gram sana and gravel, micaceous, medium dens ALLUVIUM (Oa)): Sandy Silt (ML): grayish brown, moist, \ micaceous, pedogenic carbonate nodules, rootlets, stiff to very stiff. , Sand with Silt (SP-SM): brown, slightly , medium grained, micaceous, dense. , -- Rock fragments at 15.5 feet. ------------------------' Silt (ML): brown, moist, with very fme-gJ trace coarse sand and clay, micaceous, ve ~----------------------- Silty Sand (SM): brown, moist, fine gr , medium to coarse sand and clay, dense. -- Fine to coarse grained. ------------------------ , Sand (SP): grayish brown, wet, medium 56 ,.':' grained, very dense. - III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: 29 feet ured: 3/10/03 1012 Datum: MSL .... .<: '" .~ a ~ . i3: '" .... ~ - . ".. ....- ~ a 0..... .~ " " .... o ell CIl E a 0 " a -Pi"" ill DE! .... . .;J III "do. ~ .... -Pi lD r-l >< .~ a 'tl E< ~ " o 0 'tl .~ Q :>: u -: r- ed, trace coarse e. 'ery fine grained, some fine ,------------ WA moist, fme to .----------- 'ained sand, ry stiff to hard. ------------ ,ed, trace ------------- 10 coarse yon Shopping Cent<>r PLATE a Ph-wy and Highway 79 A-13a B-12 ~O am Drafted by:-..Reviewed by: Explanation To Logs On Plate A-1 I I' i I I , , ! I , ; I i I , ! , ; I i I i , I I ! - i I ; i I I I I I I .., .0 " SOIL DESCRIPTION '" . ." ." " U '" AND . - . .., 0 0 :< ~ .-< . " '" " " 0 H " "'" 0 ,. z "" CLASSIFICATION .., - m " 0___ ." 0___ 0 ..... 4-l ~ +l o CIl (I] ~. .., . . u . ." ~ tJ ::l c: ." .., a. " "'.0 .-< .-< . .0 (Continued From Previous Page) p a..+J Q) +J 111 '00. > ..., a. a. . 0 a. -...., -.-I Ql ~ . .0. ~ ~ 0'-< " '" ." " '08 . .-< " . .-<.0 " " o 0 '0 ." "' -0 " '" lO- t!) 0 :>:u -: '" HI KLEINFELDER I PROJECT NO. 25423 6 -~ -975 - - 40-~ 7 -",. 970 - - 45-", & -~ 965 - - - 50-ii' 9 -~ 11 25 50/5" 16 32 5015" 21 39 50/5" 59 " " .~.>> .... <.::::1---- ------- ------ --- --- - -,------ - ----- -- -- Sharp contact, Sandy Silt (ML): brown, moist, very fine grained, trace ---!p1'Q.i1!ITIJl:a.n.dJl.!l<LcJ<!Y...IDic~~e~ms~h.a.!:g~ ,-- - - - - - - - - -- , Sand (SP): light brown, wet, medium to coarse grained, very dense. ....: ,.' . ."> Total depth = 51.5 feet. Groundwater encountered at approximately 29 feet below ground surface. Boring backfilled with soil cuttings. Proposed Rainbow Canyon Shopping Center SEC and SWC Pechan~la Pkwy and Highway 79 Temecula, California PLATE A-13b 4>\ ) LOG OF BORING 8-12 Drafted by:_Reviewed by: Explanation To Logs On Plate A-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 Date Drilled: Excavated By: Drilling Method: Logged By: 3/10/03 Cal Pac Drilling Hollow Stem Auger 6" D. Hasham Water Dep Date Measu Elevation: Reference " SOIL DESCRIPTION ~ ." · 1l '" AND .... 0 0 " ~ ~ " 0 H 0 ... z ~'" CLASSIFICATION :;J 0' " ~ ~ u . ." .. ...." .... .... :> " > ~.... Q, Q, :> 0 Q, ~ ~ Q, ~ ~ 0.... .. .... "'~ .....0 " '" -0 '" '" 1Il- " 1010 5 1005 10 ~ I 8 1000 15 '" 2 995 20 "". 3 3 990 25 4 3 985 .!. 30 =- 5 20 980 9 ARTIFICIAL FILL (At): Silty Sand (SM): brown, moist to very mo gramed, trace coarse sand, trace coarse gra of as halt. medium dense. ALLUVIUM (Oal~ Sandy Silt (ML): rown, moist, stiff, ped carbonate nodules. Si~ty Sand (S1\1): grayish brown, moist, v mIcaceous, loose. -- brown, wet, very fine to medium graine OrganiC-Silt (OilVblack, very m-ofst, 'm! occasional clay lenses, soft, highly plastic density, (sag pond deposit). -- Some to with fine sand, higher density, hydrogen sulfide odor. S;i1d ;fth Sil't(SP-SJ\i):-lfght ,graY'iSh-br medium to coarse grained, medIUm dense -- Cobble chatter. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING th: 29 feet red: 3/1 0/03 1012 Datum: MSL .... " '" ," " & - ~ de .... ~ - ". "de ....- ~ " "' ." '" " .... o G) tI) a " " ~ " -.-I +l Pc DE: .... m +J to 'tl ~ . .... 'n Gl r-l >- ." " 'tl ... ~ " o 0 'tl ." 0 :>:u -: .. ist, fine vel sized pieces ,- ogenic .----------- ery fine grained, d, bedded. .----------- eaceous, , very low less plastic, slight -----------'- own, v.let, yon Shopping Center PLATE a Pkwy and Highway 79 A-14a 8-13 (pV Drafted by:_Reviewed by: Explanation To Logs On Plate A-I I I I I I I I ; - I i I ~ I , I I I I : II I i I , I I I I , k SOIL DESCRIPTION . ~1 . .., '" AND +' 0 0 " " 0 H 0 " z ,.... CLASSIFICATION 'M 0'- 0 .., . . u . 'M (Continued From Pi'evious . +'.<:: rl ... ~ .<:: > ..., 0. 0. . 0 0. . . 0. e e 0'" . ... .... . . . ....Q k '" -0 " OJ "'- '" 6 32 . .'. , -- Sample mostly decomposed rock frag -"'" 5014" , ~975 - .,:, - -- Frequent cobbles. 40- ',.' -- No recovery. - ~970 - - , - 45- -- No recovery. - 965 - - , - , 50- ~ 7 38 -- Li2Cht brown with decomnosed cobb les -'"' 50/2" Total depth = 51 feet. ltel Groundwater encountered at approxim: found surface. oring backfilled with soil cuttings, III KLEIN FELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California '+, .<:: '" 'M " . . ;. '" ... . - . k'" +' - . " 0'- 'M .... k.., o 0) tJ) t:! <: 0 , " 'M +' 0. ;e) "8 .., . +I lTJ "t:l ~ ..., .ri Q)....-I >< 'M " '0 " . k o 0 '0 'M 0 :>:u -: "' nts. or boulders. y 29 feet below yon Shopping Center PLATE a Pkwy and Highway 79 A-14b - '0 Pal me ~ j PROJECT NO. 25423 LOG OF BORING B 13 Drafted by:------.-Reviewed by: Explanation To Logs On Plate A-1 ~ : -! I , I i J I - ~ , I i , I , i I I i , , I ! I ; I I I I Date Drilled: 3/10/03 . Excavated By: Cal Pac Drilling Drilling Method: Hollow Stem Auger 6" Logged By: D. Hasham Water Dep Date Meas Elevation: Reference " SOIL DESCRIPTION m 0" ~~ t> Al\'D +' 0 0 ~ ~ 0 "' 0 " z ~'" CLASSIFICATION ." 0..... 0 +' .,;: m m u 0 ." " .... .... ~ ;: > m+' '" '" ~ 0 '" m "'" ~ ~ 0.... " .... '" " .....0 " ., -c '" '" "'- " - 1010 - - - 5- - -1005 - - - 10-" I -~ 1-1000 - - - 15- ~ 2 -~ 1-995 - - - 20-i" 3 -~ 990 - - - 25- ~ 4 -~ 985 - - - 30-~ 5 -~ "- 980 - - - " ' ARTIFICIAL FILL (Afl: , Silty Sand (SM): brown, moist, fme gram " ,sana. medium dense. ALLUVIUM (Oal): Silt (ML): brown, moist, trace fine sand, 9 , , , , 14 " ll_gff~1~~~~f~fatW!~~~~mo , fine-grained, micaceous, medium dense. ~----------------------- , Sa~d (SP): l~ght grayish brown, moist, fin .. gramea, medIUm dense. 23 Silty Sand (SM): brown, moist, flneto ill trace clay, medium dense. ------------------------ '. Sand (SP): light grayish brown, slightly m ,::' to coarse gramed, WIth gravel, medIUm de , clay clots. ::: -- Increase in soil moisture, heavily staine ',' ',' ',' ,', 19 40 -- Decrease in soil moisture and iron oxid increase in gravel and clay clots. -- Cobble chatter. III KLEINFELDER Proposed Rainbow Can SEC and SWC Pechang Temecula, California i l PROJECT NO. 25423 LOG OF BORING th: > 50 ured: 3/l 0/03 1012 Datum: MSL +' ;: '" ." ~ " - " i< '" .... " " "'" +'- m ~ 0..... ." '" " +' o lI'I t1J a ~ .8, ~ " "ri J..l ~ P - +' m +J en "Cl ~ 0"" ." m .... '" ." " 'tl " m " o 0 'tl ." C :su -: .. ed, trace coarse I stiff. .----------- - ------------.1 ist, ----------- ,e to medium WA ------------ edium grained, ------------ oist, medium nse, occasional d with iron oxide, e staining, yon Shopping Center PLATE a Pkwy and Highway 79 A-15a B-14 ~ Drafted by:_Reyiewed by: Explanation To Logs On Plate A-1 ~., f ~ I - I ~ ~. I 1 I I I I , " . oo:;; ~ ~ '" ., 0 0 " " 0 H 0 .. Z ~'l< 'M 0'- U ., "'" . . U . 'M . .... .... . '" > .., 0. 0. . 0 0. . . 0. ~ ~ 0.... . .... 'l< . .....Q " '" -Q '" '" "'- " SOIL DESCRIPTION AND CLASSIFICATION (Continued From Previous P -~ 6 28 -- Medium to coarse sand, no gravel. ,,' 975 - -- Cobble chatter. - ,":'.' - -..:. '. 40-_ 7 19 ':. >_ .::..Y ~TY.1IlQi~t.:._ _ ___ __ _ __ ---- -~ 970 - Clay (CL): olive brown, moist, stiff, n - ~----------------------- - ,,: Sand (SP): li8ht gray brown, very moi 45-"", :.. coarse grame , dense. -!:'. 8 38 ',' ~ f-965 - ".: - ",: b. -", 9 46 I;.. 50-1'E- Total depth = 50 feet. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainbow Ca SEC and SWC Pechan Temecula, California PROJECT NO. 25423 LOG OF BORIN 10 ., '" '" 'M " . - . l3: "' .... . . ""' .,- . " U'- 'M'l< " ., o (II Ul a " u ~ " .,-i +l Ol age) p~ ., . 4J tIl1:!p.. . ., .r-! Ql....-l >< 'M " 'tJ .. . " o 0 'tJ 'M Q :>:u -: '" derateiy pJastiC:- --, ------------- , medium to nyon Shopping Center PLATE ga Pkwy and Highway 79 A-15b G B-14 Cp-$ st Drafted by:_Reviewed by: Explanation To Logs On Plate A-I I , '. I , I ; I - I I I - I I , ; I i , ! '~ , I I I I I Date Drilled: Excavated By: Drilling Method: Logged By: 3/10/03 Cal Pac Drilling Hollow Stem Auger 6" D. Hasham h: > 50 Ired: 3/10/03 1012 atum: MSL " .c '" ." 0 * - 0 de ..; 0 " "de " - . 0 "'- ." '" " " 0 ~ 01 S o " " 0 ." " 0. DE! " . " ~ '1:l 0. ~ " ... . ..; >< ." 0 '1:l8 . " 0 0 '1:l ." 0 :>:u -: .. ed, trace coarse F ed, loose, .. WA ----------- -----------. 1, moist, fine- to WA lay lenses. -silts and clays,-- - / __________J , moist, medium _~"-_________.J t, fine-grained, -----------~ urn grained, yon Shopping Cent". PLATE a Pkwy and Highway 79 A-16a Water Dept Date Measl Elevation: Reference D " SOIL DESCRIPTION 0 ~., ~~ '" AND " 0 0 0 o 0 .., 0 8 Z "'" CLASSIFICATION ." 0'- " " 0 0 u ~ ." " ".c ..; ..; ~ .c > 0" 0. 0. ~ 0 0. 0 00. S ~ 0"; " ..; '" 0 " ..;.0 " '" -0 01 01 1Il- " 1010 5 1005 10 7 1& 13 ARTIFICIAL FILL (An: Silty Sand (SM): brown, moist, fine grain sana, medium dense. ALLUVITJM (Oal): Silty Sand (SM): brown, moist, fine grain occasional clay fenses 1/4 to 1/2 inch thick Silt (ML): brown, slightly moist. Sand with sIft-(sP-SM):iight graybra\;;,} medium-grained, medium dense. -- Medium to coarse grained, occasional c -..: BfilVY ir.Q!l QxJd.e_slainlQg,. _ _ _ _ _._ ___ Silty Clay (CL): 2 inch layers of bedded ~~~~~m~~~~~C_____________ Gravelly Sand (SP): light brown, slightl) tQ ~Q.a.IS~ ,g!:.ain~d FTIh Q,O.llTI>s< gITty:~Lqms Sandy Silt (ML): olive brown, very mois trace medium sand, some clay, stiff. Sand (SP): light gray brown, moist, medi trace coarse sand, dense. I I III KLEINFELDER I l PROJECT NO. 25423 Proposed Rainbow Can SEC and SWC Pechang Temecula, California 1000 15 2 15 LOG OF BORING B-15 (PG) 995 20 990 25 4 26 9&5 30 9&0 Drafted by:_Reviewed by: Explanation To Logs On Plate A-I I I i \ I i I I , - - . I , I , ; I , I , , I ! I I ! i I i I I I I . " SOIL DESCRIPTION W wZ ~~ '" AND -" 0 0 c c 0 H 0 f< Z ;;!'" CLASSIFICATION ... 0..... 0 ... W W U w ... (Continued From Previous Pa . -".0 ... ... . .0 > W-" '" '" . 0 '" w w '" a a 0.... . .... .... w ....,q " '" -Q " '" lll-' " ~6 32 " "'- -975 - .;. :'. - - 40-" 7 32 -- Medium to coarse grained, moist to v -... "'- coarse gravel. 970 - '::.:" - ,', , . 45- "" 8 45 -- Occasional decomposed cobbles. -~ 965 - - , , -- Some coarse gravel. "" 9 47 -" '" 50-"'- Total depth = 50 feet. Groundwater not encountered. Boring backfilled with soil cuttings. III KLEINFELDER Proposed Rainhow Can SEC and SWC Pechang Temecula, California PROJECT NO. 25423 LOG OF BORING ery -" .0 '" ... c w - w :3' '" .... w - . "'" ...- w c 0..... ... .... " .u o UJ {J) Ei c 0 , C .r! +l 0. ge) :> 8 -" W +J IJ) 'CIa. ..u or-! QJ...-l >< ... c " .. . " o 0 " ... Q :>:u -: .. moist, trace yon Shopping Center PLATE a Pkwy and Highway 79 A-16b ~ B-15 C::.1 Drafted by:~eviewed by: Explanation To Logs On Plate A-I ~ ;1" " F ;1 f., , ,,_,";;;' I;.,i;'>/:i;i;: i ; ,: ~'-_{~ .-:r. ,." . ~. ,. -~;~:r' .-.;J" ',';.' . ',' .:~~~i:.'-' AP'PENDix B 'C.', ,. -..." .' , :_"~ .-:':{~::. .(~~~;::~~:~5: ..:;',;,,';. . . .~ . ~,,'~,'" - " '_d -,' LABORATORY TESTING '--"'r' . .-, --;..'':< ,".,.' :~--;..:, - y. ".J:L ,"~ ^.'r_'" :,<,,', ~- ~';.""'" - ~ -,'. .-; ".:.: ,-.,', ..., ',",' . ;~ fPD'.' I \ ~ I ! I i i I , , , I l I ! ~ I , , t - , I I ; I I I ! I I I I I '~ ....~ KLEINFElDER APPENDIX B LABORATORY TESTING Laboratory tests were performed on selected bulk and relatively undisturbed soil samples to estimate engineering characteristics of the various earth materials encountered. Testing was performed in accordance with one of the following references: I) Lambe, T. William, (1951), Soil Testing for Engineers, Wiley, New York. 2) Laboratory Soils Testing, U.S. Army, (970), Office of the Chief of Engineers, Engineering Manual No. 1110-2-1906. 3) ASTM Standards for Soil Testing, latest revisions. 4) State of California Department of Transportation, Standard Test methods, latest revisions. LABORATORY MOISTURE AND DENSITY DETERMINATIONS Natural moisture content and dry density tests were performed on several relatively undisturbed samples collected. The moisture content was performed in general accordance with ASTM Test Method D 2216. The results are presented on the Logs of Borings and are summarized in Table B-1, Moisture and Density Determinations. WASH SIEVE The percent passing #200 sieve of thirteen (13) selected soil samples were performed by wash sieving in accordance with ASTM Standard Test Method]) I 140-92. The test results are summarized in Table B-2, Wash Sieve Test Results. EXPANSION INDEX Expansion index testing was performed on I selected bulk sample of the near-surface soils to evaluate their expansion characteristics. The test was perfoIDled in accordance with UBC Standard No. 18-2, Expansion Index Test Method. The test results are presented on Table B-3, Expansion Index Test Results. 25423/DBA3R041 Copyright 2003, KleinfeJder,lnc B-1 March 18,2003 ~ I , - I I , I ! I I I I i l I I , I ! I I I I I ! ; - I I I I I I k~ KlEINFElDER ." REMOLDED DnrnCT SHEAR One (1) selected sample, remolded to 90 percent relative compaction, was subjecte.d to direct shear testing for shear strength and cohesion values of the in situ soils in accordance with ASTM Standard Test Method D 3080. The results are presented in Plate B-l. MAXIMUM DENSITY Two (2) maximum density tests were performed on a selected bulk sample ofthe on-site soils to determine compaction characteristics. The test was performed in accordance with ASTM Standard Test Method D 1557-91. The test results are presented in Table B-4, Maximum Density and Optimum Moisture. R-VALlJ"E TESTS R-value testing was performed on One (1) sample of the near-surface soils encountered at the site. The test was performed in general accordance with Caltrans Standard Test tv1ethod 30l. The test results are presented in Table B-5, R-Value Test Results. CONSOLIDATION TESTS Consolidation testing was performed on two (2) relatively undisturbed samples in accordance with ASTM Standard Test Method D-2435. The test results are presented on Plates B-2 and Plate B-3. COLLAPSE POTENTIAL TEST Collapse potential testing was performed on four (4) selected relatively undisturbed sample in accordance with ASTM Standard Test Method D-5333. The test results are presented on Plates B-4 through B-7_ ,'l- GRAIN SIZE ANALYSIS Hydrometer testing was conducted on one sample to aid in the c:lassification of the fine-grained soils. The tests were performed in general accordance with ASTM Test Method: D 422. The result of this test is presented on Plate B-8, Grain Size Distribution. 25423/DBA3R041 Copyright 2003, Kleinfelder, inc 8-2 March 18, 2003 10 I ,1< I I I I ! I i , ~ I i , ! I i I I ; i I i I : I I , i I I I I I I , k~ KLEINFElDER CORROSIVITY TESTS A series of chemical tests were performed on selected samples of the near-surface soils to estimate pH, resistivity and sulfate and chloride contents. A qualified corrosion engineer may use the test results to evaluate the general corrosion potential with respect to construction materials. The test results are presented in Table B-6. Table B-1 Moisture and Density Determinations 'B~ing'~ ~DrIlth,,!ji't\- ~~DP1rDens]'fi'l'l('-IlCfi~ i!i!!!i.!li!%J\lfoistupi~~~ ~"'''~.a1_,-, ~~:.~"l1',;.~"~^'".~@t.~W~~';'!J.__;Jjji"J:,~,-.,,,,,,,:,;:!:"::;]N, .%~t~~ i:a1tS*WWt:t~v,,,~w~' ",.. B-1 5 123.7 10.1 B-1 10 96.0 10.2 B-1 20 108.8 10.4 B-2 5 118.0 9.7 B-2 10 96.1 16.1 B-2 15 121.2 8.7 B-3 5 124.0 10.1 B-3 10 101.6 6.9 B-3 15 I 09.4 6.8 B-3 20 106.8 4.0 B-4 5 1l2.4 7.7 B-4 10 108.5 3.2 B-4 15 101.7 15.1 B-5 5 I 21.7 6.2 B-5 15 109.0 12.4 B-5 20 105.7 2.3 B-5 25 82.6 30.3 B-6 5 1l3.5 9.5 B-6 10 98.3 14.2 B-6 15 98.1 10.3 B-7 5 94.2 3.7 B-7 10 101.3 8.9 B-7 15 108.5 3.2 B-8 5 98.2 5.0 ' B-8 10 95.3 7.0 B-8 15 103.2 11.4 B-9 5 89.5 16.0 B-9 10 94.4 12.6 B-10 5 111.2 16.3 B-10 10 109.1 2.0 25423/DBA3R041 Copyright 2003, Kleinfelder, lnc March 18,2003 1\ B-3 I Ii , I , I I I I I , I , , I i I , I J i , I , I I , I I I I I I ,. k". KLEINFElDER Table B-2 Wash Sieve Test Results i:ii'~~B(frun~~~~De~tlil"lfl.'\l'~S\'-;""~ !li;"RlfCe'nhRlis'sfn~l'J\.'J~tI20Otr'Ol04~mm,~JlIi; ~:ti;l"Ym,.".~~,,-"g~~~/ iZ~$-w"~+~~>iWC"p~__\~}'~~~~1c .-o.i,~,~~",~~"""ce,!,c,~"""""""~~;il~"m~tkt<,q."",,>,,,-,,,,~"}=;i~&_,<\9", B-3 B-4 B-4 B-4 B-6 B-7 B-S B-9 B-13 B-13 B-14 B-15 B-15 1-5 10 10 15 5 5 5 1-6 15 30 15 10 15 35.6 41.6 20.5 50.9 42.5 31.S 34.1 4S.1 15.2 10.0 4.0 32.S 5.9 Table B-3 Expansion Index Test Results _I{O"r,i~ _,U!\~l,~~ ~~~~-- ~~pa~mll:k.I!\~11 ,."'^"''''~~''''''' .0 B-7 6-8 20 Very Low II Table B-4 Maximum Density and Optimum Moisture B-3 B-9 1-5 1-6 8.0 12.0 133.0 U6.5 Table B-S R-Value Test Results iili",_'ii"'''''1P>-''-'_jf' _.:rd~!:l,"".'ir'0"'n~t'li"if'~_'_'fT>"7 ~~{~~~;~'ti21WJJ!g~~~~~~~~p_~,,'fI'>"~~~~~~~ B-10 1-5 5 Table B-6 Corrosion Potential Results i"',wiltei:-SoliiBlei \-;Wa1er.=SolUble[': ~c'S'trt~t~Ii1:'MilGi ,;; ~'G~ldplid~i(irlv ~ ~~ll~? ~~ ~t-"1'8:fu)~~:fj5C~Bi ~j/\stij~r('~HJj~~~;~i,~~~ '-'" tPP..., ,,'.. ". _" ,.. P.P....y, ..' 36 134 57 269 ;;' ResistiYiTh\2i'jo ~~~~l~i~~~~~ B-7 4,250 B-9 2,100 25423/DBA3R041 B, 4 Copyright 2003, Kleinfelder, Inc March 18, 2003 IV I ," i ~ I ! , i I I I I I i I II II , i i I II I I I ; i I I I I I I , 2.5 '+- .. .>t. (J) 2.0 (J) W 0:: t- (J) 0:: 1.5 <I: w I (J) 1.0 4.0 I I 1 // / /" /' / 1../ / / /' / /" V 3.5 3.0 0.5 0.0 0.0 0.5 1.0 1.5 2.0 2.5 NORMAL STRESS - ksf 3.0 3.5 4.0 Test type controlled - strain test Rate of shear - in/min 0.02 Normal Stress - psf 1000 2000 4000 Maximum Shear - psf 900 1560 2712 Shear Strain - % Sample B-3. Depth - ft 1-5 Friction Angle - deg 31 Cohesion - ksf 0.32 Description Silty Sand Classification SM .Sample remolded and compacted to 90% of Maximum Dry Density Maximum Dry Density = 133.0 pcf; Optimum Moisture Content = 8.0 % Test Sample: Dry Density = 119.7 pcf, Moisture Content = 8.0 % Moisture Content After Test = 14.2 % Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California 1ft KLEINFELDER DIRECT SHEAR TEST PROJECT NO. 25423/1 PLATE B-1 1'0 I i , " I 0 ; I I : I I 2 I ~ x , ~ I - Z H <I: "" 3 l- I en , ~ ...J <I: Ll H I- , "" , w , I :> 4 I I 5 I , I I I I I I I trrl , -+-+=4111-1 ..t-.1-rTTTl - I'--. " '\. ~ ~ r-. f\ ...... ...... ....... ~ 6 10 100 0.1 1 PRESSURE - ksf Sample Depth Description Classification Compression Ratio Recompression Ratio 6-6 5.0 ft Silty Sand SM 0.023 0.010 Moisture Content Before = 9.5 % Moisture Content After = 18.8 % Initial Dry Unit Weight = 113,5 pcf III KLEINFELDER Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California PLA TE CONSOUDA TION TEST B-2 1Pv - PROJECT NO. 25423/1 - I I , , I~ I ~ i I i i ~ I , I I I I I I' - ~ - , I I I I I I ., -......... nTm nm "-.. ......... ......, ~"- ~ \ \ I' 1\ ..... \ ~ r\ i'---- 1\ ['--.., ~ 1\ o~ 2 ~ ~ ~ Z H <I: a:: 3 I- Ul --' <I: U H I- a:: w :> 4 5 6 0.1 10 100 1 PRESSURE - ksf Sample Depth Description Classification Compression Ratio Recompression Ratio B-7 5.0 ft Silty Sand SM 0.033 0.012 Moisture Content Before = 3.7 % Moisture Content After = 27.3 '\'o Initial Dry Unit Weight = 94.2 pcf III KLEINFELDER Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California PLA TE CONSOUDA TION TEST B-~~ > PROJECT NO. 25423/1 r ~" -. 0.0 0.5 1.0 1.5 2.0 '" 2.5 z H <L a:: .... 3.0 (/) 3.5 4.0 4.5 5.0 5.5 6.0 I , I , I i I ! I , I I I - ; I , , , I I i I : I ! , I I I I 1'----1__ .............. j'-... i'.. I"t ~, ~ 0.1 1 PRESSURE - ksf 10 Sample B-2 Depth (ft) 10,0 Description Silty Sand Classification SM Collapse Potential (%) Severity of Collapse 0.32 Low Moisture Content Before = 16.1 % Moisture Content After = 25.0 % Dry Density Before = 96,1 pcf IfI KLEINFELDER Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California PLA TE COLLAPSE POTENTIAL TEST 8-4 14> PROJECT NO. 25423 - , ~ f I i i ~ II I II i I I' * I I t I ; , ; I I I ; , I i I I I I I I " 0.0 0.5 1.0 1.5 2.0 x 2.5 z H <I: <:t: >- 3.0 en 3.5 4.0 4.5 5.0 5.5 ---- r--- t--- ......, ~ ,..... ...... ..... 6.0 0.1 1 PRESSURE - ksf 10 Sample 8-4 Depth (ft) 10.0 Description Silty Sand SM Classification Collapse Potential (%) Severity of Collapse 1.64 Moderate Moisture Content Before = 3.2 % Moisture Content After = 19.4 % Dry Density Before = 108.5 pcf Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California PLA TE III KLEINFELDER 8-5 11 PROJECT NO. 25423 COLLAPSE POTENTIAL TEST I I ,I i , 0.0 0.5 1.0 1.5 2.0 >< 2.5 z H <J: '" I- 3.0 Ul i I I I I i ~ I I ; ~ ~ J I I 1 - i I I I I I --- -...... ~ ...... i'- ..... , ~ 3.5 4.0 4.5 5.0 5.5 6.0 0.1 1 PRESSURE - ksf 10 Sample B-4 Depth (ft) 15.0 Description Sandy Silt Classification ML Collapse Potential (%) 0.32 Moisture Content Before = 15.1 % Moisture Content After = 22.1 % Dry Density Before = 101.7 pcf Severity of Collapse Low III KLEINFELDER Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Ph-wy and Highway 79 Temecula, California PLA TE COLLAPSE POTENTIAL TEST 8-6 1'6 PROJECT NO. 25423 I i I 0.0 : , I 0.5 ; I 1.0 I , , I I I - , I , , , I I - I I i I I I I I I 1.5 2.0 '" 2.5 z H <I: '" t- 3.0 (f) 3.5 4.0 4.5 5.0 5.5 6.0 k ....... .......... ........ " .......... I-....... ...., 0.1 1 PRESSURE - ksf 10 Sample 6-8 Depth (It) 5.0 Description Silty Sand Classification SM Collapse Potential (%) Severity of Collapse 0.74 Low Moisture Content Before = 5.0 % Moisture Content After = 30.7 % Dry Density Before = 98.2 pcf L...~ KLEINFELDER Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California PLATE PROJECT NO. 25423 COLLAPSE POTENTIAL TEST B-7 1~ - I J' i i ~ ~ ~ :~ _ ,~ 60 (J) II ~ 50 , w : u _I ~ 40 I g 30 [ * ! I i i , I \ , ! i I i I , I I SIEVE ANALYSIS c:== HYDROMETER 3" 1,5" 3/4" 3/8" #4 U.S. STANDARD SIEVE SIZES #16 #30 #60 #100 #200 #10 100 , , , , , , 0 1 2 3 , 4 "-- \'. ~ ... 90 o 80 o 70 o o o ~ H <I: >- w 50 0:: >- Z W u 60 ffi 0- ...J <I: 70 b >- 20 80 10 90 o 0.1 0.01 0.001 10 1 GRAIN SIZE (mm) GRAVEL SAND ] fine medium fine SILT CLAY coarse coarse Symbol Sample Depth (ft) Description Classification . 6-13 25 Silty Sand SM III KLEINFELDER Proposed Rainbow Canyon Shopping Center SEC and SWC of Pechanga Pkwy and Highway 79 Temecula, California PLA TE GRAIN SIZE DISTRIBUTION B-8 <eo PROJECT NO. 25423 ~. '~,' '."';,~-rt " ~ii .'.. .~i" .(;""i::~:i;;~c !~jjl'~ . ",' " APPENDIX,G,., <>>:,,:~~;./>;.,'.,-.. ~,; .".,.,.~, , ~. '''' "., ~",>- ,'r' , ' '1-' ,,"',">,. . "~;~i):;. ", .",,:;-~..., ";'~lt~tii2ff~~s~~;~~;::f;~:~,i :-::\_:', '-". ~~:~~~~_~'~1_' -", -,' :::;,,';~~:_;~',~.}.~:":~ .....~,\n.'J.\t;; -,' '\'.' _.. 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C- ~ " . ~ o .. o ~ o , ~ S o ~ ~ o . ~ ~ ,~ o ~ f ~ ,~ -w -w "0 "Z ~ a: o . . . ~ ~ " .. > i!i " >. n ~ . 0. o ~ . o I I I I I I I I I I I I I I I I I ~ :~ u' om ~~ .0 ~o ~ .~ .0 ~ I I 9;). I- I., : I~ I ~.~~(~I~~'~'jl~m~~lilWI(!I'~~~__ 1_~1i]il:ilmlnm,_ , I 'I I - I I , I I ! I i I I i I ! ~, I' I I I I I ~ Geotechnical Services Are Performed for Specific Purposes, Persons, ami Projects Geotechnical engineers structure their services to meet the spe- cific needs of their clients, A geotechnical engineering study con- ducted for a civil engineer may not fulfill the needs of a construc- tion contractor or even another civil engineer. Because each geot- echnical engineering study is unique, each geotechnical engi- neering report is unique, prepared solely for the client No one except you shouid rely on your geotechnical engineering report WIThout first conferring with the geotechnical engineer who pre-' pared it. And no one-not even you-should apply the report for any purpose or project except the one originally contemplated. A Geotechnical Engineering Report Is Based on A Unique Set 01 Project-SpeCifiC Factors Geotechnical engineers consider a number of unique, project,spe- cific factors when establishing the scope of a study, Typical factors include: the client's goals, objectives, and risk management pref- erences; the general nature of the structure involved, its size, and configuration; the location of the structure on the site; and other planned or existing site Improvements, such as access roads, parking lots, and underground utilities. Unless the geotechnical engineer who conducted the study' specifically indicates other- wise, do not rely on a geotechnical engineering report that was: o not prepared for you, o not prepared for your project, o not prepared for the specific site explored, or o completed before important project changes were made. Typical changes that can erode the reliability of an existing geotechnicai engineering report include those that affect: o the function of the proposed structure, as when it's changed from a parking garage to an office building, or from a light industrial plant to a refrigerated warehouse, o elevation, configuration, location, orientation, or weight of the proposed structu re, o composition 01 the design team, or o project ownership. As a general rule, always inform your geotechnical engineer of project changes.~ven minor ones--and request an assessment of their impact. Geotechnical engineers cannot accept responsibility or liability for problems that occur because their reports do not con sider developments of which they were not informed. Subsurface Gomlitions Can Change A geotechnical engineering report is based on conditions that existed at the time the study was performed. Do not rely on a geotechnical engineering report whose adequacy may have been affected by: the passage of time; by man-made events, such as construction on or adjacent to the sITe; or by natural events, such as floods, earthquakes, or groundwater fluctua- tions. Always contact the geotechnical engineer before appiy- ing the report to determine if IT is still reliable. A minor amount of additional testing or analysis could prevent major problems. Most Geotechnical Findings Are Professional Opinions SITe exploration identifies subsurface conditions only at those points where subsurface tests are conducted or samples are taken, Geotechnical engineers review field and laboratory data and then apply their professional judgment to render an opinion about subsurface conditions throughout the site. Actual sub- surface conditions may differ-sometimes significantly-from those indicated in your report. Retaining the geotechnical eng~ neer who developed your report to provide construction obser- vation is the mosl effective method of managing the risks asso- ciated with unanticipated condi1io ns. ~(pj l-..1. i f!. Report's Recommendations Are Not Final Do not overrely on the construction recommendations included in your report. Those recommendations are not final, because geotechnical engineers develop them principally from judgment and opinion. Geotechnical engineers can finalize their recom- mendations only by observing actual subsurface conditions revealed during construction. The geotechnical engineer who developed your report cannot assume responsibility or liability for the report's recommendations If that engineer does not perform construction observation. A Geotechnical Engineering Report Is Subject To Misinterpretation Other design team members' misinterpretation of geotechnical engineering reports has resulted in costly problems. Lower that risk ,by having your geotechnical engineer confer with appropriate members of the design team after submitting the report. Also retain your geotechnical engineer to review perti- nent elements of the design team's plans and specifications. Contractors can also misinterpret a geotechnical engineering report. Reduce that risk by having your geotechnical engineer participate in prebid and preconstruction conferences, and by providing construction observation. Do Not Redraw the Engineer's logs Geotechnical engineers prepare final boring and testing logs based upon their interpretation of field logs and laboratory data. To prevent errors or omissions, the logs included in a geotechnical engineering report should never be redrawn for inclusion in architectural or other design drawings. Only photo- graphic or electronic reproduction is acceptable, but recognize that separating logs from the report can elevate risk. Give Contractors a Complete' Report and Guidance Some owners and design profeSSionals mistakenly believe they can make contractors liable for unanticipated subsurface cond~ tions by limiting what they provide for bid preparation, To help prevent costly problems, give contractors the complete geotech- nical engineering report, but preface it with a clearly written let- ter of transmittal. in that letter, advise contractors that the report was not prepared for purposes of bid development and that the report's accuracy is limited; encourage them to confer with the geotechnical engineer who prepared the report (a modest fee may be required) and/or to conduct additional study to obtain the specific types of information they need or prefer. A prebid conference can also be valuable. Be sure contractors have suffi- cient time to perform additional study. Only then might you be in a position to give contractors the best information available to you, while requiring them to at least share some of the financial responsibilities stemming from unanticipated conditions, '" i- :1 ,I Read Responsibility Provisions Closely Some clients, design professionals, and contractors do not , recognize that geotechnical engineering is far less exact than other engineering disciplines. This lack of understanding has created unrealistic expectations that have led to disappoint- ments, claims, and disputes. To help reduce such risks, geot- echnical engineers wmmonly include a variety of explanatory provisions in their reports. Sometimes labeled "limitations", many of these provisions indicate where geotechnical engi- neers responsibilities begin and end, to help others recognize their own responsibilities and risks. Read these provisions closely. Ask questions. Your geotechnical engineer should respond fully and frankly. i I rl , i :1 ! ! :1 I , I Geoenvironmental Concerns Are Not Covered The equipment, techniques, and personnel used to perform a geoenvironmentlll study differ significantly from those used to perform a geotechnical study. For that reason, a geotechnical engineering report does not usually relate any geoenvironmen- tal findings, conclusions, or recommendations; e.g" about the likelihood of encountering underground storage tanks or regu- lated contaminants, Unanticipated environmental problems have led to numerous project failures. If you have not yet obtained your own geoenvironmental information, ask your geotechnical consultant for risk management guidance. Do not rely on an environmental report prepared for someone else. I ., l I Rely on YOUI' Geotechnical Engineer for Additional Assistance Membership in ASFE exposes geotechnical engineers to a wide array of risk management techniques that can be of genuine ben- efit for everyone involved with a construction project. Confer with your ASFE-member geotechnical engineer for more information, I I I I ASF' e PROFESSIONAL FIRMS PRACTICING IN THE GEOSCIENCES 8811 Colesville Road Suite G 1 06 Silver Spring, MD 20910 Telephone: 301-565-2733 Facsimile: 301-589-2017 email: info@asfe.org www.asfe.org I I Copyright 1998 by AS FE, Inc. Unless ASFE grants written permission to do so, duplication of this document by any means whatsoever is expressly prohibited. Re-use of the wording in this document. in whole or in part, also is expressly prohibited, and may be done only with the express permission of ASFE or for purposes of review or scholarly research. I IIGER06983.SM I I f.-- ; il \ I I [ I I ~ T I i r' I I r I , ' I , I i I I I I I k~ KlEINFElDER APPLICATION FOR AUTHORIZATION TO USE Geotechnical Investigation Rainbow Canyon Shopping Center SEC and SWC of Pechanga Park"Way and Highway 79 Temecula, California File Number: 25423 Report Date: March 18, 2003 KLEINFELDER, INC. 1370 Valley Vista Drive, Suite 150 Diamond Bar, California 91765 (909) 396-0335 To whom it may concern: Applicant understands and agrees that the Geotechnical Investigation (Report) for the subject site is a copyrighted document, that Kleinfelder, Inc. is the copyright owner and that unauthorized use or copying of the Report for the site is strictly prohibited without the express written pelmission of Kleinfelder, Inc. Applicant understands that Kleinfelder, Inc. may withhold such permission at its sole discretion, or grant permission upon such terms and conditions, as it deems acceptable. Applic,ant agrees to accept the contractual terms and conditions be,tween Kleinfelder, Inc. and Raitibow Canyon Development, LLC originally negotiated for preparation of this Report. Use of this Report without permission releases Kleinfelder, Inc. from any liability that may arise from use of this report. To be Completed by Applicant By: (company name) (Print Name) (address) (Signature) Title: (city, state, zip) Date: (telephone) (FAX) By: Approval of Original Client Date: (print Name) (Signature) For K1einfelder, Inc.'s use only approved for re-use with additional fee of $ approved for re-use with applicant's agreement to following cooditions: Applicant agrees to above terms and understands that findings discussed in report were based on available information and site conditions as noted at time of ESA. disapproved, report needs to be updated By: Date: (Kleinfelder, Inc. Project Manager) 25423/DBA3R041 Cop)'right 2003, Kleinfelder, loe ~ March 18, 2003 E-I