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'1lUlPl1J1l :llIS :llll 1lupnp A.lllss=u :lq osIllJJ!A\ JlY p;ll:llldrnO:l Sl1 IU:lw:l:Jlljd pUIljl1AOW:lJ 'Aj1lUlPJO:l:lV ':ljqISS:lJdwoo pUll :lSOOI AI:lApl1j:lJ 1lUl:lq :lWOS lIllA\ :ljqllpllA AJlj1ll!j :lJl1 UOAUIl:l AjJ:llllnOS :llll JO UOlllod J:lA\Oj :llll Ul p:lJ:lluno:lu:l sl!os jlllAnJll1 :lApl1U :lljJ. '1lUlPIll1l :lllS :llll 1lUlmp jm p;ll:llldrnOO 11 Sl1 p:l:Jlljd pUll P:lAOW:lJ :lq 01 p:l.IJnb:lJ :lq JJ!A\ IjllS:lJ 11 Sl1 pUll 'jm p:lJOOUl1lU:l p:llu:lwn:>op 11 Sl1 p:l:llljd IOU Apu:lJl1ddl1 Sl1A\ :l1lpPjl1JlU:l:J :llllUl IU:lW:l:Jllld JJ!d lUOY1OJas'mm,n XlC{ OU9-,f."[ (606) 9119-,rf' (606) ,1,lrtLf'z6 V:J 'spuDWall 'JaUa JalUa:J SSJUlSIlf[ :/-[798,Z ""Z I I I I I I I I I I I I I I I I I 'I I I Mr, Ram Fullen Hiram-Hill Development Company, LLC August 17, 1998 Page 2 For the most part, the fill placed in the northerly canyon area appears to have been properly placed and compacted, As a result, only minor removal of the near surface materials in the northerly canyon area where compacted fill has been placed will be necessary due to natural weathering and weed abatement. Following the recompaction of the near surface materials and rough grading the site will be suitable for the support of the proposed structures with conventional spread footings provided that the recommendations contained herein are incorporated into the design and construction of the project. Preliminary laboratory testing indicates that the near surface materials have a very low to low expansion potential; however, review of geotechnical reports from the mass grading indicate that some of the soils may have a medium expansion potential, Accordingly, we have presented recommendations for design and construction of the houses for a medium expansion potential. Final review of the expansion potential will be made at the completion of the rough grading, The findings of the investigation and recommendations for site development are presented in the attached report, It has been our pleasure to be of service to you, Should you have any questions please contact our office. Respectfully submitted, ~'\Z'r- ~ Nicholas S, Hont, P,E, Principal Engineer 1. Stanley Schweitzer, P,E. Senior Geotechnical Engineer Distribution: (4) Addressee 1N40231..()()I-02 Ibg\98-08aug.msw\gi23 Uem.doc '?7 I I I I I I I I I I I I I I I I I I I TABLE OF CONTENTS smilm ~ 1.0 INTRODUCTION ..............................................................................................................................1-1 \,\ AUTIlORIZA TION .........,......................................,....,...........,...............................,..........................' \-\ 1.2 PURPOSE AND SCOPE OF WORK......................,.......,..........,.........................................,............... \-\ \.3 SITE DESCRIPTIONIBACKGROUND ....................,........................................................................, \-2 \.4 SURROUNDING PROPERTIES ,..,..,................................,........................,........................,.............., \-3 2.0 DESIGN DATA...................................................................................................................................2-1 3.0 SUBSURFACE INVESTIGATION ..................................................................................................3-1 3,\ SOIL BORINGSffRENCH PITS..........,....................,......................,...............,........,...,......,..,........... 3-\ 3,2 LABORATORY SOIL TESTING.....,............,.......,..,............................................,........................,.... 3-\ 3.3 SUBSURFACE CONDITIONS ...................................,....................................................................... 3-2 3.3. I Regional Geology .... ................ ............... .....,......... ........... ....,....................................................... 3-2 3.3.2 Earth Unils................................... .................. ............... ............... ..,..,.................................. ....,.... 3-3 3.3.3 Sile Geologic Structure.................. ....,............ .......................,........ ...........,....,........,......... ........... 3-4 3.3.4 Groundwater.................. ,............... ................... ............................... ..................., ......................... 3-4 3.3,5 Seismicily ,.........................,......,....... ................. .......,.............................,. ............ ......,......,....,....., 3-4 4.0 CONCLUSIONS................................................................................................................................. 4-1 4,1 GENERAL .........,........,..............,..,.....,..............,..............,.......................,.............,....................,......, 4-\ 4,2 SLOPE STABILITY .........................,.....,....,........,..,..,......,...........,..................................................... 4-\ 4.3 EVALUATION OF SOIL LIQUEFACTION POTENTIAL ..,........,......,..........................,..,..,..........,.4-\ 4.4 EXPANSIVE SOILS ....................................,..,.....................,..............,.................................,............, 4-2 4.5 EV ALUA TION OF EXISTING FILUCOLLUVIUM..,......,.......................,...........,.......,................... 4-2 4,6 REMEDIAL GRADING ,......................,........,.........,...................,....,............,.............,...............,.......4-3 5.0 RECOMMENDATIONS.....................................................................................................................5-1 5,\ FOUNDATION DESIGN .............,....,...............,.........,.........,...........,.............,........,....................,...., 5-\ 5,2 CONCRETE FLOOR SLABS-ON-GRADE,........,..........................................,................,.........,........ 5-2 5.4 EXPANSIVE SOILS ....,..,......,........,..,..........,.......................................................,..,..................,.......' 5-2 5,5 WATER-SOLUBLE SULFATES ....................,..,............................,..............,.....,............................., 5-3 5.6 SOIL CORROSIVITY...........................,........,....................,........,....................,................,............,..., 5-3 5,7 RETAINING WALLS .............,..................................,.......,................................................................, 5-3 5,8 SLOPES..................................................................................,..,......,..........................,.............,......,.., 5-4 5,9 TENTATIVE PAVEMENT DESIGN ..,..............,....,..,........,..........,.........,...............................,.......... 5-4 5,10 SITE GRADING .....................,..........................,........,...............................,...,..............,..,......,..,....., 5-5 5, J 0,1 Clearing and Grubbing................ ................... ....,.......................... ....,........, ............,.... ....,......... 5-5 5, I 0.2 Removals.....,................................ ......,............ ......,.......................... ..,................ ..........,....,......., 5-6 5, I 0.3 Placement of Compacted Fill......... ................... ....,.............................. .....,.............. ......,..,........, 5-6 5, 10.4 Import Soils......,................,............ ............ ,...... ................................... ................ .............,........, 5-7 5.10.5 Shrinkage and Subsidence ..,.........................................................................................,............, 5-7 5. 10.6 Trench BackfilL ..............., ................ ......... ..,........ ...........,.......................................................... 5-8 5,\\ SITE DRAINAGE .......................................,..,....,..................,...........,......,................,....,................,. 5-8 5,\2 SLOPE MAINTENANCE,.............,..................................,..,..,...................,.............................,..,...., 5-8 JN4023l-OOI-02 Ihg\98-08aug.msw\gi231tem.doc A. I I I I I I I I I I I I I I I I I I I TABLE OF CONTENTS (Continued) 5,13 POOL CONSTRUCfrON .......""........",,,,,,,,,,,,,,,,,.......,,.,,.........,,.,,,,,,..,,.............."""""",,,...,,,,,,,,.. 5-9 5,14 POST INVESTIGATIVE SERVICES """"""",,,,,....,,,,,,,,,,,,,,..........,,,,,,,,,,,,,,,,,,,,,,...,,,,,,,,,,,,",..."", 5-9 6.0 CLOSURE............................................................................................................................................6-1 7.0 REFERENCES .................................................................................................................................... 7-1 FIGURES Figure I - Site Location Map Figure 2 - Site Plan APPENDICES Appendix A - Boring & Trench Logs Appendix B - Test Results Appendix C - Guide Specifications for Placement of Fill and Backfill IN 40231-001-02 1hg\98-08aug.msw\si231te:m.doc ~ II II , I I I I I I I I I I I I I I I I I 1.0 INTRODUCTION 1.1 AUTHORIZATION This report presents the results of a preliminary geotechnical investigation performed at the request of Hiram-Hill, LLC by SECOR International Incorporated (SECOR) for the site of a proposed single-family residential development, Tract 23990, The proposed Tract will consist of one and/or two-story single-family houses and interior streets, located on the southerly side of Via La Vida between Calle Palmas and Via Sevilla in the City of Temecula, California (Figure I), This report has been prepared for Hiram-Hill Development Company, LLC and their project design consultants, to be used solely in the development of design of the proposed project as described herein, This report may not contain sufficient information for other uses or the purposes of other parties, 1.2 PURPOSE AND SCOPE OF WORK The objective of this investigation was to assess the nature and engineering properties of the encountered subsoils and to provide tentative geotechnical design recommendations for site development. A "Site Acquisition Environmental Assessment" was performed concurrently with this investigation and has been presented under separate cover, The scope of work which was performed in accordance with the instructions received from Hiram-Hill, LLC and SECOR's proposal letter to Hiram-Hill, LLC (PN 98077-R) dated May 28, 1998 included the following tasks: . Drill six soil borings; · Excavate five exploratory test trenches; . Perform laboratory soil testing on selected samples; . Evaluate geotechnical properties pertinent to the design and construction of the proposed development; and . Summarize findings, conclusions, and recommendations in this report, IN 40231~I-02 Ihg\98-08aug.msw\si231tem.doc: I-I Cp I I I I I I I I I I II I I I I I I I I 1.3 SITE DESCRIPTION/BACKGROUND The site of the proposed development consists of an approximately 6,32 acre parcel of vacant land located on the southerly side of Via La Vida between Calle Palmas and Via Sevilla in the City of Temecula, California, Site topography consists of an east-west trending ridge that is located in the central portion of the site with portions of two east-west trending canyons located along the northerly and southerly edges of the site, Regionally, the subject is located near the southwesterly corner of the Perris Block which lies northwesterly of the Elsinore Fault Trough and northwesterly of the Agua Tabia Mountains, The United States Geological Survey (USGS) 7.5-minute topographic map for the Murrieta quadrangle (Figure I) shows the subject site topography as being low lying hills with an elevation of approximately 1,153 feet above mean sea level (msl) and the drainage towards the west. The northerly canyon was partially filled with compacted fill in conjunction with the rough grading of the easterly adjacent residential tract (Tract 20882-3) in 1988, According to the Geotechnical Report of Rough Grading for that tract prepared by Leighton and Associates, dated May 20, 1988, the maxirilUm depth of fill placed on the subject site is on the order of 25 feet. Review of that report also indicates that a canyon subdrain was installed in the bottom of the canyon which is located just to the northeast of the property line, Following the placement of the compacted fill, the topography in this area is generally flat with a slight slope toward the west and Via La Vida, The canyon along the southerly edge of the property is essentially in a natural, ungraded condition, Both upstream and downstream of the site, the canyon has been filled in with compacted fill placed in conjunction with the rough grading of the adjacent residential tracts (upstream Tract 20153 and downstream Tract 22593), Surface waters upstream and downstream of the site have been channelized into storm drain pipes, Review of available geotechnical reports for the developments upstream and downstream of the site did not indicate that canyon subdrains were installed beneath the compacted f1ll in this canyon, Visual review of the central ridge indicates that some grading of the ridge has occurred over the years, A cut slope is located on the site along the westerly property line, This slope which descends down to the adjacent tract (Tract 22593) was apparently constructed as an off-site cut slope during the rough grading of the westerly adjacent tract. Topography of the rest of the ridge indicates that movement of material by both cut and fill operations appears to have occurred, At the time of the field exploration for this investigation, the site was vegetated by a moderate growth of native grasses with several large trees located in the bottom of the southerly canyon, 1N40231-OO1..Q2 Ihg\98..Qaaug.msw\gi231 tem.doc 1-2 \ I I I I !I I I I . I I I '. !. I I I I I 1.4 SURROUNDING PROPERTIES The subject site is surrounded by a mixture of single and multi-family residential developments, In addition to the on-site slope described above along the northerly portion of the westerly property line, off-site fill slopes that ascend from the property lines to the adjacent tracts are located along easterly and southerly property lines and the southerly portion of the westerly property line, JN4023I.oo1-02 Jhg\98-OSaug.msw\gi23ltem.doc 1-3 I I I I I I I I I I I I . I I I I . I 2.0 DESIGN DATA The proposed development will consist of the construction of a tract of one and/or two-story single-family residential structures with associated streets and utility improvements, A Tentative Tract Map showing 30 individual lots and two interior streets was provided for our use in the preparation of this investigation, However, it is our understanding that this concept is being revised to reportedly allow for a general increase in finish elevation over the entire site from that shown on the provided Tentative Tract Map, It is also our understanding that this increase in overall site elevation will require the importation of a significant amount of fill material. Although specific grading was not available at the time that this report was prepared, it is assumed that this change in grading concept will require the construction of fIll slopes along the southerly and northeasterly portion of the site and/or the placement of off-site fill along the lower portion of the existing off-site slopes that are located adjacent to the property line, For the purpose of analysis, we have assumed that the maximwn height of new or modified slopes necessary for development of the site will be on the order of 30 feet and that the following new slopes and changes to existing slopes will be required: . New cut and/or fill slopes at various locations around the site with a maximwn height of 20 feet; . Existing cut slope along the westerly property line will be decreased in height up to ten feet; . Existing off-site slope along the easterly property line (adjacent to the high point of the central ridge) will require cut of up to ten feet below the toe of the existing slope, thus creating a fill over cut condition; and . Existing off-site fill slopes along the southerly property line and the southerly portions of the easterly and westerly line may be reduced in height by the placement of off-site fill at the toe of the slope, Building design information was not available at the time that this report was prepared, However, for the purpose of analysis it has been assumed that the structures will be constructed with wood framing and concrete siab-on-grade first floors, It is our understanding that the structures will be supported by conventional spread footings. Based upon our experience with similar projects, we have assumed that continuous footings will carry loads of 1.5 kips per lineal foot or less and columns will carry five kips or less, The site location and the layout of the proposed structures are shown on Figure 2, IN 4023I-OOl-o2 Ihg\98-0Saug.msw\gi231 tem.doc 2-1 2> I I . I I I I I I 'I I I I II I I I I I I I 3.0 SUBSURFACE INVESTIGATION 3.1 SOIL BORINGSfTRENCH PITS A total of six soil borings and five test trenches were excavated at the site on May 26, 1998, The borings were drilled using an 8-inch outer diameter, hollow-stem auger to depths of approximately. 30 feet below existing ground surface, The test trenches were excavated using a track mounted dozer, The approximate boring and test pit locations are shown on the enclosed Site Plan (Figure 2), The rationale for the boring locations was to locate the borings in each of the two canyons and at both ends of the on-site portion of the ridge. The trenches were located along the upper portion of the ridge in order to evaluate the extent of grading that was previously done, A SECOR Project Engineer was on-site to observe drilling operations, log subsurface soil conditions, and to collect soil samples for physical and chemical analysis, Undisturbed samples of the materials encountered were obtained from the borings by driving a 2,S-inch inside diameter split-spoon sampler with a 140-pound hanuner. free-falling 30 inches, The sampler was advanced 18 inches at each sample interval and the blow counts required to advance the sampler each 6-inch drive length were recorded on the boring logs, The blow counts are used as an aid in the evaluation of the consistency of the soils and correlating the various engineering properties, In addition to the undisturbed sample retrieved from the borings, bulk samples of the near surface materials were obtained from the borings and from selected test pits, The boring logs are presented in Appendix A, A SECOR Engineering Geologist was on site to observe excavation of the trenches and log the subsurface conditions encountered, The logs of the test pits are also included in Appendix A, No sampling of the materials encountered in the trenches was performed, All borings and trenches were backfilled with native soil, No significant compaction of the boring and test pit backfill was performed, Compaction of the test pit backfill will have to be performed during rough grading for the subject project. 3.2 LABORATORY SOIL TESTING The following laboratory tests were performed on selected samples in our laboratory in accordance with the American Society for Testing and Materials (ASTM), or contemporary practices of the soil engineering profession, IN 40231-001-02 lhg\98-08aug.msw\gi2J ltem.doe 3-1 ~ I I I I I I I I I ! I I 'I I II I I I I I . In-Situ Moisture IASTM D-2216) and Unit Weight lDensity): These tests were performed on undisturbed samples by measuring the weight and volume of the sample and determining the moisture by drying a portion of the sample in an oven, These results are used to analyze the consistency and the degree of relative compaction of the subsurface soils, . Maximum Dry Density and Optimum Moisture Content IASTM D-1557)' This test is used to evaluate the relationship of maximum dry density and moisture content under standardized conditions, The data is used to compare in-situ characteristics with "optimum conditions," evaluate existing conditions and methods for improving bearing capacity and to control grading operations, . Consolidation Tests IASTM D-2435): These tests were conducted to estimate the potential senlement/heave of the structures by measuring the compression/expansion of undisturbed drive samples under various norma1loads, Water was added at some point during the test in order to determine the effect of increased moisture, . Direct Shear Test IASTM 0-3080): The tests were performed on undisturbed drive samples in order to obtain the soil shear values which are among the basic soil parameters that are used to estimate soil bearing capacity, slope stability and lateral earth pressures, . R-Value IASTM D-2844): The R-Value test is used to evaluate the quality of soils and aggregate base material for use as subgrade and base in structure pavement design, . Expansion Index I ASTM D-4829): These tests were performed on a portion of a bulk sample of the near surface materials in order to determine the expansion potential of the soil when allowed to become saturated, The laboratory results of all laboratory tests are presented in the Borings Logs (Appendix A) and Appendix B. 3.3 SUBSURFACE CONDITIONS 3.3.1 Regional Geology The site is located in the Peninsular Ranges geomorphic province, a region characterized by northwesterly trending faulting and mountain ranges, According to the Geologic Map of California, Santa Ana Sheet (USGS 1969), the near surface natural materials underlying the site and inunediate vicinity consist of a Quaternary age alluvial fan with stream deposits derived from IN 40231-001-02 1hg\98..oaaug.msw'lgi231tem.doc 3-2 \0 . I I I I I , I I II I I I I I I I II I I the adjacent mountains, The higher elevations consist of older, uplifted and dissected alluvium of Pleistocene Age referred to as Pauba Formation, In the lower areas, the Pleistocene Age materials are covered with Holocene (recent) alluvium, Regionally, these alluvial deposits consist primarily of sand, silt and gravel. 3.3.2 Earth Units The subsurface materials underlying the site include sedimentary bedrock of the Pauba formation as well as colluvium and artificial (compacted) fill, The approximate distribution of these materials on the subject site is shown on the enclosed Site Map, Figure 2, Pauba Formation The entire site is underlain by bedrock of the Pauba formation, In the central portion of the site the bedrock exists near the existing ground surface, Along the southerly portion of the site the bedrock is covered with colluvium from the natural canyons, In the northerly portion of the site the colluvium has been removed and is now covered with artificial (compacted) fill from the mass grading, The Pauba formation as encountered during our exploration consist primarily of silty sandstone with interbeddes of siltstone and claystone, No significant cementation of the sandstone was detected in any of the samples obtained during the field exploration, CoUuvium (Col) Colluvium was encountered overlaying the bedrock in the areas of the southerly canyon, This material consists of a combination of transported soils and residual topsoils which have accumulated within the old drainages and along the base of the slopes, These deposits consist primarily of dark brown to light yellow brown, silty sands that are in the native state porous and compressible, Review of referenced reports for the rough grading of the northerly adjacent property and information received during our field exploration indicates that the colluvium was removed from the northerly canyon prior to the placement of compacted fill. Artificial (Compacted) flU (Qat) Overlying the native materials in the northerly and central portions of the site is artificial fill that was placed and compacted during the mass grading of the northerly adjacent property, This fill was derived from the on-site materials during the mass grading and varies from silty sand to sandy clay, In general, the fill materials placed in the northerly canyon were dense and moist. Fill materials encountered in the central ridge area were loose and dry to slightly moist. IN 40231-001-02 lhg\98-0Saug.msw\gi231tcm.doc 3-3 \\ , . II I I I I I I I I I I I I I I I I I 3.3.3 Site Geologic Structure Although the native materials underlying the colluvium and artificial fill is classified as bedrock and assigned to the Pleistocene Age Pauba formation, no well defined geologic structure for the on-site materials was encountered during the field exploration, 3.3.4 Groundwater Groundwater was not encountered within the depth explored for this investigation, Based upon monitoring data from the regional Cooperative Well Measuring Program (WMWD, 1998), the depth to groundwater at the site is estimated to be on the order of 300 feet below the ground surface, As a result of this depth, groundwater is not expected to adversely affect the development provided the recommendations resented herein are implemented, 3.3.5 Seismicity The site, as is most of California, is located in a seismically active area, However, the site is not located within an Alquist-Priolo Earthquake Fault Zone and there are no known active or potentially active faults underlying the site or adjacent area, The closest known active or potentially active fault is the Elsinore Fault which is approximately 0,61 miles from the site, Other active faults that could have an impact on the development include: . Whittier-North Elsinore Fault located approximately 5 miles southwesterly of the site; . Cucamonga Fault located approximately II miles northeasterly of the site; . Newport-Inglewood Fault located approximately 26 miles southwesterly of the site; and . San Andreas Fault located approximately 26 miles northeasterly of the site As a result of this separation from any known active fault system, seismic induced ground rupture is thus not expected at the site. The anticipated primary affect of a seismic event on any of the adjacent fault systems would be a moderate to high level of ground shaking, Due to the close proximity of the site to the Elsinore Fault Zone, it appears that this fault will be the controlling feature for the seismic design of the proposed development. Based upon the above distance from the site to the Elsinore Fault Zone, the attenuation relation by Campbell & Boorgnia (1994) and the maximum credible and probable (recurrence interval of 50 - 100 years) earthquake magnitudes presented in the Riverside County Seismic Safety Element (1976), we IN4023J-OOI-02 Ihg\98-08aug.msw\gi23Item.doc 3-4 \7.- I I I I I . . I I I I I I I I . I I I have estimated the maximum peak ground acceleration at the site, The estimated maximum peak ground acceleration at the site for the maximum credible earthquake (M=7,O) is O,63g while the maximum probable earthquake (M=5,O) will produce a ground acceieration ofO,I8g at the site, Based upon the research of Ploessel and Slosson (1974), the repeat high ground acceleration (RHGA) recommended for structural design of the development is 65 percent of the maximum peak acceleration, For the subject site the RHGA for the maximum probable earthquake is O,l2g, Accordingly, the provisions of the Uniform Building Code (UBC) and the Structural Engineers Association of California (SEAOC) guidelines are considered appropriate for design of the structures, IN40231.QOI..Q2 1hg\98-08aug.msw\gi23I tem.doc 3-5 \'? I I I I . I I . I I . . I I I I I I I I 4.0 CONCLUSIONS 4.1 GENERAL The results of this investigation indicated that the site is suitable for the proposed development, provided that the recommendations presented herein are implemented during design and construction the proposed development. 4.2 SLOPE STABILITY In order to evaluate the gross stability of slopes necessary for the development of the site, SECOR has performed preliminary calculations using Janbu's method of analysis as simplified by Singh (1970), These calculations indicate that compacted fill slopes constructed with native or similar materials and/or cut slopes excavated into native materials with a maximum height of 30 feet will have a static factor of safety in excess of 2.5, Analysis of surficial slope stability using an Infinite Slope with Parallel Seepage approach indicates that the factor of safety for the site following grading as recommended herein for new slopes against potential surficial failures is also in excess of 2,5, 4.3 EVALUATION OF SOIL LIQUEFACTION POTENTIAL Liquefaction is the sudden decrease in shearing strength of cohesionless soil due to vibration, During dynamic or cyclic shaking, the soil mass is distorted, and interparticulate stresses are transferred from the sand grains to the pore water, When the pore water pressure increases to the point that the interparticulate effective stresses are reduced to zero, the soil behaves temporarily as a viscous fluid (liquefaction) and, consequently, loses its capacity to support the structures founded thereon, Engineering research of soil liquefaction potential (Seed, et. aI., 1982 and 1985) indicates that three basic factors must exist concurrently in order for liquefaction to occur, namely: I) A source of ground shaking, such as an earthquake, capable of generating soil mass distortions; 2) A relatively loose sandy soil fabric exhibiting a potential for volume reduction; and 3) A relative shallow groundwater table (within approximately 50 feet below ground surface) or completely saturated soil conditions that will allow positive pore pressure generation, IN 4023 1-001-02 Ihg\98-OSaug.msw\gi231 tem.doc 4-1 \l\ I I I I I I I I I I I !I I I I I I I I Groundwater was not encountered during this investigation and review of the referenced reports from the site mass grading of adjacent developments did not reveal any evidence that would indicate groundwater should be expected beneath the site in the fill and/or native soils, Review of the rough grading reports and the data received during this investigation indicates that the compacted fill and native soils are relatively dense, Accordingly liquefaction induced by seismic shaking is not anticipated at the site due to the absence of an established groundwater condition and the absence of loose sandy soils, 4.4 EXPANSIVE SOILS Preliminary laboratory testing on portions of the bulk samples obtained during this investigation indicates that the on-site near surface materials possess a low expansion potential as defined by the Uniform Building Code, As a result, the preliminary recommendations for the design and construction of footings and slab-on-grade floors and hardscape presented herein are based upon a low expansion potential, It should be noted that the site grading performed as part of the proposed project may alter the distribution of the near surface materials and as a result the expansion potential of the near surface soils that are present following grading in the building pads will need to be evaluated, 4.5 EVALUATION OF EXISTING FILL/COLLUVIUM Evaluation of the existing fill placed in the northerly portion of the site during the mass grading of Tract 20882, indicates that with the exception of the near surface materials, the fill is relatively dense and hard, According to the report, all loose compressible colluvium was removed to firm material prior to the placement of the compacted fill. No evidence was detected during this investigation to indicate that the fill was not placed and compacted as indicated in the referenced rough grading report and the requirements of the Uniform Building Code and/or the County of Riverside, The soft loose condition of the existing near surface material is believed to be due, in part, to approximately 12 years of weed control measures and the recent heavier than normal rainfall at the site, Soft compressible native colluvium was encountered in the lower portions of the southerly canyon, Review of the data received from the field exploration and laboratory testing indicates that the thickness of the compressible colluvium is on the order of 10 to 13 feet. In order to eliminate the potential for adverse settlement of the proposed residences due to compression of this material, the colluvium should be removed to firm native material prior to the placement of any compacted fill in the southerly canyon, The estimated limits of the deep alluvial removal is shown on the attached site plan (Figure 2), IN 40231-001...(12 Ibg\98-oSaug.msw\gi231tem.doc 4-2 6 I I I I I. I I I I I I I I I I I I II ! I I 4.6 REMEDIAL GRADING In addition to the compressible colluvium discussed above, past site grading, weed control and natural weathering of the site have resulted in the rest of the site being covered with a thin mantle of loose soil, Our evaluation indicates that in order to provide adequate support for new fill and/or the proposed structures, it will be necessary to remove these soils and moisture condition as necessary to near the optimum moisture content and recompact these soils, Preliminary rough estimate of the depth of loose fill and native soil is three feet. In addition, it is assumed that rough site grading will create lots containing cut/fill transition lines, Our experience indicates that where a contact between bedrock and fill exists at the ground surface within a building there is a very high potential for adverse differential senlement of the building to occur, As a result, we have recommended that where the transition between bedrock and fill occurs within a building, the bedrock be over-excavated as necessary to provide a cap of compacted fill beneath the building, IN 40231-001-02 1hs\98-o8aug.msw\g12311em.doc: 4-3 \~ I . I '. I I I . I . I I II I I . I . I 5.0 RECOMMENDATIONS The following recommendations have been developed upon, in part, the information received from the field exploration and laboratory testing performed for this investigation and the information contained in the referenced reports and represents our evaluation of existing site conditions, These recommendations should be considered preliminary and subject to review and possible revision following our review of the project grading plans and the actual site conditions encountered during construction, 5.1 FOUNDATION DESIGN Following completion of the site grading performed in accordance with the recommendation presented herein, conventional shallow spread footings and/or post-tension are expected to provide adequate support for the proposed structures, An allowable soil bearing pressure of 1500 pounds per square foot is recommended for preliminary design of footings founded in properly compacted fill and firm native soil, A one- third increase in the vertical bearing pressure may be assumed when considering short term seismic or wind forces in combination with vertical loads, Footings should have a minimwn width of 12 inches and a minimum embedment depth below lowest adjacent grade of 18 inches, A friction resistance of 0,35 between concrete and soil and a passive bearing pressure of 300 pounds per square foot per foot of depth, limited to 1500 pounds per square foot are recommended for calculating resistance to lateral loads, The minimum reinforcement of continuous footings should be two #4 reinforcing bars, one at the top and one at the bottom, Continuous footings should be extended across all exterior door openings, The above recommended footing size and reinforcement should be considered minimwns and additional size and/or reinforcement should be provided as structural design considerations dictate, Alternatively, a post-tensioned slab/foundation system designed in accordance with the provisions of the Uniform Building Code may be used for the support of the proposed structures, Building senlement due to the above described footings loads should be less than one-inch total and less than one-half inch differential between similarly loaded footings of the same size, IN 4023)-001-02 Ibg\98-o8aug.msw\gi23ltem.doc 5-1 \\ I II I I I I I I I I I I I I I I I I I 5.2 CONCRETE FLOOR SLABS-ON-GRADE At the time of concrete placement, the floor and garage slab subgrade should be firm, relatively unyielding, and be at least optimum moisture content to a depth of 12 inches below pad subgrade. Concrete slabs-on-grade should have a minimum thickness of 4 inches, nominal. Building slabs- on-grade should be reinforced with a minimum of No, 3 reinforcing bars, spaced at a maximum of 16 inches on center each way, Additional reinforcing should be provided as structural conditions dictate, If approved by the owner, equivalent welded wire mesh may be used for reinforcement of concrete slabs-on-grade, However, to be effective, it is imperative that the reinforcement be located within the center third of the slab thickness, The commonly used procedure of "hooking" the reinforcement during concrete placement seldom, if ever, results in proper location of the slab reinforcing. To protect against capillary moisture from the underlying soil, the building floor slab in areas that where a damp floor condition is unacceptable such as areas that are to be covered by carpet, tile or other moisture sensitive floor coverings, should be underlain by a minimum 6-mil plastic membrane covered with a minimum of two inches of sand, The garage slab should be separated from the foundation stem wall with felt and should saw cut into quarters for crack control. Other design and construction criteria for concrete floor slabs, such as mix design, strength and durability, reinforcement and joint spacing, elc" should conform to current specifications promulgated by the American Concrete Institute (ACI), 5.4 EXPANSIVE SOILS It is anticipated that following grading the near-surface soils are expected to exhibit a low expansion potential as defined by the Uniform Building Code, Consequently, special design for expansive soils are not considered necessary for the project. Recommendations presented herein, are considered adequate for this range of expansive soil conditions, These recommendations should be considered preliminary and su):>ject to conformation or revision based upon the expansion potential of the actual soils occurring near the ground surface in the building pad areas, IN 4023I-QOI...{l2 Ihg\98-OBaug.msw\gi231 tern.doe 5-2 \~ I I I .1 I I I I I I I I I I I !I I I I 5.5 WATER-SOLUBLE SULFATES The results of preliminary laboratory testing indicate that there are negligible concentrations, as defined by the Uniform Building Code, of water-soluble sulfates in the soil. As a result, special sulfate resistant concrete is not currently considered necessary for the subject project. The concentration of water soluble sulfates in the near surface soil should, however, be confirmed at the completion of rough grading, 5.6 SOIL CORROSMTY The results of preliminary laboratory testing indicate that the near surface soils have a saturated resistivity on the order of 1600 ohm-cm, and water extractable chloride of 39 ppm, In general term soils with this level of resistivity should be classified as non-corrosive to metal in contact with the soil, The corrosion potential of near-surface soils should be confirmed at the completion of rough grading by soil resistivity, pH and chloride testing, 5.7 RETAINING WALLS Retaining walls up to five feet in height that are part of the development and are constructed structurally independent of the residences may be designed using the following parameters: . Allowable bearing capacity 2,000 pounds per square foot (pst) . Minimum depth of footing 18 inches or as necessary to provide minimum horizontal distance of five feet to descending slope faces * . Minimum footing width 18 inches . Active earth pressure Level backfIll 30 psf per foot of depth Sloped backfIll (2: I H: V) 45 psf per foot of depth . Passive earth pressure Level ground 300 psf per foot of depth Descending ground (2:1 H:V) 160 psf per foot of depth . Sliding coefficient 0,35 IN 40231-001-02 1hg\98..08aug.msw\gi231 tem.doc 5-3 ,<\ I I I I I I I I I I I I I I I I I I I * Additional horizontal distance between the bottom edge of footing and the slope face should be provided as required by the Uniform Building Code, Adequate provisions (subdrains) to drain the retained earth must be included in design and construction of the walls, Where wet wall conditions are not considered desirable, the wall should be water proofed. Backfills must be compacted to a minimum relative compaction of 90 percent in order to preclude the occurrence of objectionable post construction subsidence, Caution must be exercised during the placement and compaction of backfill materials to avoid temporarily over- stressing the walls, If retaining walls with a height greater than five feet and/or that are restrained at the top are added to the project should be reviewed by a Geotechnical Engineer on an individual case. 5.8 SLOPES During the proposed grading for the subject project, construction of new slopes and the modification of existing slopes are anticipated, The maximum height of graded slopes is anticipated to be on the order of 30 feet. Permanent graded slopes should be constructed with a maximum slope inclination of 2 to I (horizontal to vertical), Temporary construction slopes with a maximum height of 30 feet may be constructed with a maximum inclination of I to I, Temporary trench excavations should be sloped or shored in accordance with CALOSHA and local safety codes, Review of the material types encountered during this excavation indicates that a Soil Classification Type B as defined OSHA Rules and Regulations for design of trench slopping and/or shoring, 5.9 TENTATIVE PAVEMENT DESIGN Tentative pavement structural sections were evaluated in accordance with State of California, Department of Transportation (CAL1RANS) procedures using an R-Value of 17 for the near- surface soils following grading and the City of Temecula requirements for minimum traffic indices, Grading of the site and the importation of fill material will significantly alter the distribution of subgrade materials, As a result, the R-Value of the street subgrade soils and the corresponding pavement section should be confirmed following the site grading, 1N4023I-001-02 lhg\98-OSaug.msw\gi23Itcm.doc 5-4 tp I I I . . I I I I I I I I I I I I I I Traffic Type Cui de Sacs TI = 5.0 17 Local Residential TI = 5.5 17 R-Value Asphalt Concrete (AC) Thickness (inches) Aggregate Base (AB) Thickness (inches) 4.0" 4,0" 6,0" 8,0" The above pavement sections are based upon the assumption that the subgrade is uniformly moisture conditioned to at least two percent above optimum moisture content and compacted to at least 90 percent relative compaction to a depth of 12 inches at the time of base placement. Final geotechnical observation and testing of subgrade should be performed just prior to the placement of aggregate base, The aggregate base should meet the specifications for Crushed Aggregate Base (CAB) as contained in the Standard Specifications for Public Works Construction, and should be compacted to at least 95 percent relative compaction with a uniform moisture content of near optimum, 5.10 SITE GRADING In the absence of detailed grading information we have assumed that the grading necessary for the project will consist primarily of lowering the grade in the area of the central ridge and raising the grade with fill in the area of the southerly canyon, It is anticipated that this grading will require the creation of some new slopes and the modification of some of the existing slopes, 5.10.1 Clearing and Grubbing Clearing and grubbing of the site will be required to remove all vegetation and unsuitable material prior to grading, Topsoil and soil containing vegetation, organics and/or humus shonld be removed and disposed of off-site, It is essential that excavations created by removing vegetation roots and other unsuitable materials, should be backfilled with clean fill soil and should be compacted in accordance with the requirements presented below, IN 40231-001-02 lhg\98-08aug.msw\gi231tem.doc 5-5 7.--' I I I I I I I I I I I I I I I I I I I 5.10.2 Removals In order to provide adequate and uniform support of new fill and/or structures, removal and recompaction of near surface materials is considered necessary, The depth of required removal should be determined during grading based on inspection by the Project Soils Engineer, The following subsections outline the preliminary depths of removal considered necessary based on the available preliminary data, In general, removal of all porous, collapsible and relatively loose native soils (with less than 85 % relative compaction) should be required, Loose SuiflJJ;e Soil As the result of previous grading and years of weed abatement and recent heavy rains, most of the site is covered with a mantle ofloose. soft fill and soil, Currently, the depth of loose fill and soils removal is estimated to be on the order of two to five feet. The estimated depths of removal are shown on the attached Site Plan, Figure 2, In the area of the central portion of the site and southerly canyon, the depth of removals will be considerably greater in order to remove loose compressible colluvium, It is anticipated that deeper removals will extend to a depth of 10 to 13 feet below the existing grade in this area, The approximate limits of the deeper removals are shown on the attached Site Plan, Figure 2, that should be further evaluated and verified by the Project Soils Engineer during grading, Other localized areas of deeper removals may also be necessary based on the inspections of the Project Soils Engineer, depending on the conditions that exist at the time of grading, Transition Lots Bedrock beneath the building in building pads that contain a transition between bedrock and the compacted fills should be removed as necessary in order to provide a minimum of three feet of compacted fill below the bottom of all footings, Bedrock removal for transition lots should be performed to a minimum of five outside the building limits, 5.10.3 Placement of Compacted Fill Prior to the placement of fill, the bottom of over-excavations and areas to receive fill shonld be scarified to a depth of 6 inches, then moisture conditioned to near-optimum moisture content and surface compacted to the relative compaction specified below for fill, The bottom of all over- excavations should be observed by the project Geotechnical Engineer or his representative prior to the placement of any fill. IN 40231-001-02 Ihg\98-08aug.msw\gi231 tem..doe 5-6 1-:V II I I Placement of compacted f1ll should be performed in thin lifts at or over optimum moisture content using mechanical compaction equipment. Unless specified otherwise, all fill should be compacted to a minimum of 90 percent relative compaction based upon the maximum density obtained in accordance with ASTM Standard D-1557, I I I I During grading, frequent density testing should be performed by a representative of the soil engineer to evaluate compliance with grading specifications, Where testing indicates insufficient relative compaction, additional compactive effort should be applied with the adjustment of moisture content where necessary until the required relative compaction is obtained, 5.10.4 Import Soils I I Any imported soil shall be tested for expansion, strength and sulfate concentration and approved by the Geotechnical Engineer prior to importation to the project site, Final acceptance of any imported soil will be based on the review of the soil actually delivered to the site, 5.10.5 Shrinkage and Subsidence I I I Calculations have been performed based on the in-situ unit weight of the materials encountered during our geotechnical investigation and the estimated compacted unit weight of the materials after grading to estimate the shrinkage which might be expected as a result of the grading recommended in our Geotechnical Investigation report. It is estimated that shrinkage on this project could range from five to ten percent by volume, Subsidence, as a result of the grading operations, could range from zero to 0,2 feet in these types of materials, Please note that these estimates are based upon limited available date and on interpolation of soil conditions between tested locations, Consequently, the actual values may be more or less than estimated herein, and thus, the estimates should be used with extreme caution. I I The above values are based upon an assumed balance between the native cut and over- excavation of loose alluvium which may vary depending on the actual grading plan developed, As a result, the values for shrinkage and subsidence should be reviewed and adjusted as necessary based upon the Geotechnical Engineer's review of the rough grading plan, I I I I I This firm assumes no responsibility for the use of these earthwork factors or the balancing of earthwork quantities on this project and recommends that contingencies be developed for balancing the earthwork quantities based upon the actual shrinkage and subsidence which occurs during grading, IN 40231-001-02 lhg\98-<l8aug.msw\gi231 tem.doc 5-7 ~? I I I . I I I . I . I I I I I I I I I 5.10.6 Trench BackfIll From a Geotechnical Engineering viewpoint, the on-site soils are suitable for use as utility trench backfill. However. the City of Temecula may have special requirements for trench backfill that limits the use of the on-site native materials, All utility trench backfill should be brought to at least optimum moisture content and then compacted to obtain a minimum relative compaction of 90 percent of the laboratory standard, Flooding/jetting is not recommended for the site materials, All trench excavations should minimally conform to CAL-OSHA and local safety codes, 5.11 SITE DRAINAGE It is imperative to building and overall site stability that positive drainage away from buildings and slopes be provided, The use of area drains to drain the rear yards and the connection to roof down spouts to the area drains should be considered, Subsequent to the rough grading of the building pads, the designed drainage away from the buildings and slopes should be maintained to allow runoff water to drain towards the street or designed area drain, Failure to maintain positive drainage may contribute to foundation distress. utility trench settlement, and/or slope failures, During and subsequent to any homeowner improvements, the positive drainage away from the residential structures and top of slopes should be maintained, 5.12 SLOPE MAINTENANCE The developer and the ultimate home owners should be aware that the continued stability of the slopes is dependent on the continued maintenance of the slopes, including the maintenance of landscaping and drainage devices, Any slope distress should be repaired inunediately, Seeding and planting of the slopes should by implemented to achieve, as rapidly as possible, a well established and deep-rooted vegetation requiring minimal watering, The type of vegetation and watering schedule should be established by a landscape architect familiar with hillside maintenance, The watering requirements should be reviewed by this firm. IN 40231-001..(12 lhg\9S-OSaug.msw\gi231 tem.doc 5-8 2A I I I I I I . I I I. I I I I. . I I I I A burrowing rodent suppression program should by established and maintained, Rodent activity is very detrimental to slopes and the importance of curtailing such activity cannot by overemphasized, Along the top of the any slope, berms should be constructed in order provide positive drainage away from the slope and to prevent surface water from flowing over the top of the slope, Homeowner improvements that modify the drainage and berms should not be allowed, 5.13 POOL CONSTRUCTION All pools and/or spas constructed on lots that are adjacent to descending perimeter slopes should be constructed with a liner and subdrain to prevent leakage from the pool/spa saturating the slope material, 5.14 POST INVESTIGATIVE SERVICES Post investigation services are an important and necessary continuation of this investigation, and it is recommended that SECOR be retained as the Project Soils Engineer to perform such services, Final project plans and specifications should be reviewed prior to construction to confirm that the full ,intent of the recommendations presented herein have been applied to the designs, Following review of plans and specifications, sufficient and timely observation during construction should be performed to correlate the findings of this investigation with the actual subsurface conditions exposed during construction, The following items of construction should be observed and tested as necessary to ensure compliance with the recommendations contained herein, (a) Rough site grading, including inspection of the bottom of subexcavation in order to determine the depth of required removal by the Project Soils Engineer; (b) Footing excavations to confirm that the foundation elements are founded III the recommended materials; (c) Utility trench backfill; (d) Street subgrade preparation and base placement and compaction; and (e) All other items of work requiring an opinion of adequacy from the geotechnical engineer to be included in a final geotechnical report, IN 40231-001-02 Jhg\98-OSaug.msw\gi231tem.doc 5-9 ~~ ~.-. I I I I I I I I I I I I I I I I I I I ~.:o.;...:: 6.0 CLOSURE Our conclusions, recommendations and discussions presented herein are (I) based upon an evaluation and interpretation of the findings of the field and laboratory programs, (2) based upon an interpolation of subsurface conditions between and beyond the explorations, (3) subject to confirmation of the actual conditions encountered during construction, and (4) based upon the assumption that sufficient observation and testing will be provided by SECOR during construction, Any person using this report for bidding or construction purposes should perform such independent investigations as he deems necessary to satisfY himself as to the surface and subsurface conditions to be encountered and the procedures to be used in the performance of work on this project. This report contains information which is valid as of this date, However, conditions that are beyond our control or that may occur with the passage of time, may invalidate, either partially or wholly, the conclusions and recommendations presented herein, The conclusions of this report are based on an interpolation of subsurface conditions encountered at the boring locations, The actual subsurface conditions at unexplored locations may be different. Consequently, the fmdings and recommendations of this report will require re-evaluation if subsurface conditions different than stated herein are encountered, Inherent in most projects performed in the heterogeneous subsurface environment, continuing subsurface investigations and analyses may reveal fmdings that are different than those presented herein, This facet of the geotechnical profession should be considered when formulating professional opinions on the limited data collected on this project. The fmdings and recommendations contained in this report were developed in accordance generally accepted current professional principles and practice ordinarily exercised, under similar circumstances, by reputable geotechnical engineers and geologists practicing in this locality, No other warranty, expressed or implied, is made, IN 4023 1-OO1..()2 Ihg\98-OSaug.msw\gi231 tc:m.doc 6-1 1Y I II II II I II I I I I I I I I I I I I I 7.0 REFERENCES California Division of Mines and Geology (CDMG); 1966; Geologic Map of California, Santa Ana Sheet, Scale 1:250,000, CDMG, 1994; Fault Activity Map of California and Adjacent Areas with Locations and Ages of Recent Volcanic Eruptions, Compiled by Jennings, C,W,; Geologic Data Map No, 6, Scale 1:750,000, CDMG, 1990, Special Studies Zone Map, Murrieta Quadrangle. California Geo Tek, Incorporated, 1988, Mass Grading and Compaction Control, Phase I, Tract 22593, Rancho California Area, Riverside County, California, April 26, 1988, Project No 7S3WRC-I44, California Regional Water Quality Control Board (CRWQCB), San Diego Region (7); September 8, 1994; Water Quality Control Plan, CRWQCB, Colorado River Basin Region (7), Inland Foundation Engineering, Inc., 1980, Preliminary Soil Investigation, Tentative Tract Nos, 13,936 and 14,284, Morago and General Kearny Roads, Rancho California, California, January 7, 1980, Project No, ROI6-002. Leighton and Associates, Inc" 1988, Geotechnical Report of Rough Grading, Tracts 20882, 1,2 and 3, Ranch California Area, County of Riverside, California, dated May 20, 1988, Project No, 6861086-03, Leighton and Associates, Inc" 1986, Geotechnical Report of Rough Grading, Lots I through 22 Tract 29882-3, Rancho California Area, County of Riverside, California, dated September 21, 1986, Project No, 2790722-10, Ploessel, M,R, and Slosson, J,E" 1974, repeatable High Ground Accelerations from Earthquakes, California Geology, Vol. 27, No, 9, pp. 195-199, Singh, Awtar, 1970, Shear Strength and stability of Man-Made Slopes, Journal of Soil Mechanics and Foundations Division, American Society of Civil Engineers, November, 1970, United States Geological Survey (USGS), Murrieta Quadrangle, 7,5-Minute Series, 1953, Photorevised 1979, 1:24,000, Western Municipal Water District (WMWD), 1998, Cooperative Well Measuring Program, Covering Upper Santa Ana River Watershed, San Jacinto Watershed and Santa Margarita Watershed, Fall, 1997, dated April 1998, IN 40231-001-02 [hg\98-OSaug.msw\gi231tcm.doc 7-1 "\ l' FIGURES 1fb' I I I I I I I I I I I I I I I I I I I I ~~~IQQ Y?f7f.,t:.<. "~v~>~~IP.'" - tVtbroF'1 VN" :" ~/~;~p~/,~~~ ~I '~~)5f@,'/'/' "'~. ~M'I9:' if1 D~ Cjfj '/Zoo "C31 . ~~~, ~-fr -=", ~/ <<:. /(j ff' ~~~~~ ~I , If;{;1) C2'o!-~.' /" .w''',~,>.' ~.,,'?c?o~ ~ 'f': ~ 0 ",'"'111 P: (,:>; l" 0'.... p/i;?"",t:;;;> p (hj . {f)~~'" ~ :' -; ~~~Sfr::' --0f ;;[ ~\~ r:i '~. '" c~:J;;:o,~,> .": :';, C,/~.:::. ~~w7~: ..l~~~~,/~ :0 . '-%,.,./ ~ ~. "~~o;::::s;--=:,(((~~ !~ " ,,'~.. . ~ ~ I ll15~/l, ~ "...~'. ~J1"'Ml;' '. --- 1100' I ~( m; -""". 1'1 .... -, ~ Ao. . ~ )".,( ,~--<~ S1d;~75 ~~"'" ~"1~~ T~.. 41'1 ':;,F '~~l1J~!f;/~ :(~~~oV?~~.p~~ t' "., (#V..' <=>. . ~.~.~~~\\-~ .."..,{ " ~L ~ - ~ ~%" (R? >:'~I'~ ( I~~:'",...~\ol'< ~d:l~\j ~ ",'''',~ ~ ( '-, ..\ h"?/ ~;O~ ~ l'd:' I '"" 'l{?--;' I' ,\lie ~ IV!. ~./ p ..I)o';J.~! 1^~. I ;'\~ AI'" -d.C:;,c:::5 ,;;;; '?J)/ltf/<2,h'""',.;:, ~ . ,,~...... ' ... B ~ ~ a '-.::: <.:<2::'<.;:=::Y/c. ~.s - ,'.,$0, ~ :. ~""'__, ~ "(]. .::. ~//oo:::.::J-~..,.,.g ?~~~~' ....:... v/":, 0_ .< ~ " ../" r.... t. ROAD,k. . ;.::::.;. .. .. '~..." .. f' . \.. ~' ll..," ~ ":~,,;:-:- -:/A1/ ,0 0 vA 00 9': ~~ ". '.::. ,;'~::'~\'. ~ J/1Q <J(" . ~l~ )' ."::~'-" ~j,.~ ~A ~ ~,\~;. ;-- ~.,.~. ~ ~"""=o )~~P;:<;;~I A-~I' ~:n~~~~,-~," "-, ~~~" .\ '.:iI~~. ..~. .'~"'''f''':: . ~ ': ~ . . '\" Ai'porl "'~',: ~\ ~:-Il>" ~=:> , "- '.. i"' > '~~'\-.".. ~\ \ - "'0...\ l.nL :::r------::::: \~~, \ .; ,.'! .~,.~ .;:.~v Ref: U,S,Geological Survey, 1953, Murrieta Quadrangle, Riverside County, CA, 7,5 Minute. Series, Topographic, Photorevised 1979. SCALE Tentative Tract- 23990 Alstrup Road Murrieta, Californio SITE LOCATION MAP 1 inch = 2000 feet NORTH 2000 1000 0 2000 feet SECOR PROJECT: 40231-001-01 FIGURE: 1 MAPBROR1,OWG HOP vo.", I I I I I I I I I I I I I I I I I I I ~ EXPLANANTION B-1. T-2EE3 & APPROXIMATE BORING LOCATION APPROXIMATE TRENCH LOCATION APPROXIMATE DEPTH OF REMOVALS APPROXIMATE REMOVALS LIMITS /' '.j\v\A /" ~SS\ ,/ B-1, '.j\\A;~5/\' . " \ 1\ & !JI \ ';;?:.9J5-- ~ if - '\ T-4ffi ~/ ~ \ B.5 ( T.T. 23990 \ ) ^ \ RIDe ~\ C ~ NORTH SCALE NOT TO SCALE EXISTING HOMES (f) <( :2 -.J Ci. EXISTING HOMES w TR 22593 -.J -.J <( U --- EEl T-2 --- STORM DRAIN +8-3 ~ ~ -fANYON &- :/-" EXISTING HOMES TR 20153 EXISTING HOMES TR 20882-3 ~ '1-).. ~ EXISTING SLOPES EXISTING HOMES TR 20882-3 "STOR DRAIN SITE VICINITY MAP TENTATIVE TRACT 23990 6.32 ACRE SITE TEMECULA, CALIFORNIA SECORAOoD\DWG-TMf'\TEMECUlADWG PROJECT: 40231-001-02 FIGURE: 2 ?P , ,. II I I I I I I I I I I I I I I I I I APPENDIX A BORING LOGS -;\ I I I I I I I I I I I I I I I I I I I Logged By: JSS ee "Legen to gs for sampling method, classifications and laboratory testin methods Date Drilled: Drilling Contractor: Method/Equipment: Hollow Stem Auger Boring Number: B-1 5/26/98 Boring Diam.(in,): 8 CaI Pac Groundwater Elevation (ft.): SZ i Not Encountered Casing Elev.(ft.): Total Depth (ft.): 31.0 Drive wt.(lbs,): 140 .or~p DIst.(IO.): 30 ~ " 5 c. ;" Well t: .s " ~ Construction 1 ~ c. 0 " a; Q <Il -a ~ .~ " " -a .c 0 E c ~ u_ i Description ",j,! "",, Q,e, ~ ~ " i:' a 0. ~ ~ Q '0 ::E <Il Fill: (SM) Silty SAND - brown to dark brown, moist, firm to slightly stiff, some sandy silt 12 120 13.5 16 23 5 15 (SM) Silty SAND -brown to dark brown, moist, firm to 116 13.5 17 slightly stiff, some sandy Silt 30 13 117 13.5 17 22 10 II (SM) Silty SAND - brown to dark brown, moist, stiff, some 113 13.5 13 sandy Silt 20 19 122 10.0 28 35 . . 15 .- .. 14 109 10.0 19 25 17 .. (SM) Silty SAND - very dark gray brown with brown and 117 9,0 50 dark brown, moist, stiff, some sandy Silt The substrata descriptions above are generalized representations and based upon visual/manual classification of cuttings andlor samples obtained during drilling, Predominant material types shown on the log may contain different materials and the cbange fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Project No. 40231-001-02 Date June 98 Log of Boring Figure A-I (sheet I of 2) ?;J' I I I I I I I I I I I I I I I I I I I Logged By: JSS or Well Construction Date Drilled: 5/26/98 Boring Diam.(in.): 8 :5 -5 it o " Q. ?: " ! '" ~ ~ o OS 22 25 30 Drilling Contractor: Method/Equipment: Hollow Stem Auger Drive Wl.(Ibs.): 140 112 Boring Number: B-1 .Dr~p DISt.(m.): 30 E ~ .~ ~ " 0 1! l'!- 0 u_ 0 Description ,,~ ~>#. Z 05 ~~ " i:' Q. 0 ~ ~ '" Log of Boring Figure A-I 9,5 The substrata descriptions above are generalized representations and based upon visuaUmanual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated. Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times. 25 30 35 Date June 98 Casing Elev.(ft.): Cal Pac Groundwater Elevation (ft.): SZ i Not Encountered Total Depth (ft.): 31.0 Project No, 40231-001-02 .. . .. .. . . .. .. . .. .. . .. .. , ... (SW) SAND - yellow brown with some rust brown, moist, stiff (ML) Sandy SILT - dark brown to olive yellow brown, moist, stiff (ML) Sandy SILT, dark brown with rust brown, moist, stiff Total Depth = 31.0 feet below ground surface Groundwater was not encountered (sheet 2 of 2) ?'? I I I I I II , , I I I I I I I II I I I I I Logged By: Date Drilled: Drilling Contractor: Method/Equipment: Boring Number: Hollow Stem Auger B-2 JSS 5/26/98 Cal Pac ee gen to gs or Boring Casing Groundwater Elevation (ft.): Tolal Drive .Dr~p sampling method. Diam.(in.): E1ev.(ft.): SZ Depth (ft.): wt.(lbs.): DtSt.(m.): classifications and laboratory 8 i Not Encountered 31.0 140 30 testin methods E ~ ~ u .~ ~ u S c. ~ ~ Well ~ 0 o~ u~ ~ .s u ~ Description u~ u"" Z Construction j ~ Q~ ~ - u c. 0 a u a; ~ Q. Q ~ ~ '" Q '0 ::g '" Colluvium: (SM) Silty SAND, dark brown, moist, slightly fitm, slightly porous 5 108 12 5 6 5 8 (SM) Silty SAND - brown, moist, firm, slightly porous 6 10 9 (SM) Silty SAND - light yellow brown, moist, firm, 104 7,5 12 slightly porous, slight increase in sand content 15 . . Backfilled 10 17 (SM) Silty SAND - light yellow, moist, stiff, slightly 117 9,5 with Soil 20 porous, slight increase in sand content Cuttings 25 12 (SM) Silty SAND - light yellow, moist, stiff, slightly 100 12.0 15 porous, slightly porous, slight increase in sand content 20 ------------------------------- 15 14 Pauba Formation(Qp): (ML) Sandy SILT - olive brown, 115 14.5 15 moist, firm to slightly stiff, low Sand 20 13 110 15,0 28 35 (SM) Silty SAND ' olive brown with rust streaks, moist, dense The substrata descriptions above are generalized representations and based upon visuallmanual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type 10 another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times. Project No. 40231.001.02 Date June 98 Log of Boring Figure A-2 (sheet I of 2) ';1\ I I I I I I I I I I I I I I I I I I I Logged By: Date Drilled: Drilling Contractor: Melhod/Equipment: Boring Number: Hollow Stem Auger B-2 JSS 5/26/98 Cal Pac ee gen to gs or Boring Casing Groundwater Elevation (ft.): Total Drive .DrC!p sampling method, Diam.(in.): Elev.(ft.): SZ Depth (ft.): wt.(\bs.): D15l.(m.): classifications and laboratory 8 i Not Encountered 31.0 140 30 testin methods E ~ ~ u ?;> B u S "" ~ = ~ Well ?: '~ 0 =~ (.)~ 0 -5 u ~ Description u,B ull'< Z Construction l ~ 05 ~ - u is- 0 g a; i:> ]- 0 '" 0 '0 = ::E '" 2S 111 9,S 2S 30 Pauba Formation (Qp): (SM) Silty SAND - dark brown to dark gray, moist, dense 25 25 25 35 30 26 50 (CL) CLAY - olive brown, moist, stiff, low plasticity Total Depth = 31.0 feet below ground surface Groundwater was not encountered 35 The substrata descriptions above are generalized representations and based upon visual/manual classificatiou of cuttings and/or samples obtained during drilling. Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Project No. 40231~01~2 Log of Boring Date June 98 Figure A-2 (sheet 2 of 2) ?;6 I . . . I . I I I I I . I I. I I I . I Logged By: Date Drilled: Drilling Contractor: Method/Equipment: Boring Number: Hollow Stem Auger B-3 JSS 5/26/98 Cal Pac ee gen to gs or Boring Casing Groundwater Elevation (ft.): Total Drive Drop sampling method, Diam.(iD.): Elev,(ft.): SZ Depth (ft.): wt.(\bs,): DiSl.(io.): classifications and laboratory 8 i Not Encountered 31.5 140 30 testin methods E ~ ~ ~ .~ B ~ C. .0 S ~ = E Well ?: 0 =~ u_ = -6 ~ !< Description ~.g ~"" Z Construction ~ 0 o,e, ~ - ~ e- O; i::' E Q. 0 ~ 0 ~ E '" '0 ~ ::E '" Colluvium: (SM) Silty SAND - fine grained, very dark brown, very moist, firm, porous 5 117 12,0 8 12 .. 5 8 119 12,0 8 9 .. 7 (SM) Silty SAND - fine grained, very dark brown, very 112 10.5 8 .. .. moist, firm, porous, increase in sand content 10 .. 10 7 (SM) Silty SAND, fine grained, very dark brown, very 115 14.5 9 moist, no visible pores, increase in silt content 15 9 (SM) Silty SAND - fine grained, very dark brown, very 113 16,0 14 moist, firm, slightly porous 15 15 15 (SM) Silty SAND - very dark brown, very moist, firm, 104 15,5 t5 porous 18 Pauba Formation (Qp): (CL) Sandy CLAY - brown, stiff, moist 15 III 20,0 30 35 . The substrata descriptions above are generalized representations and based upon visual/manual classification of cuttings and/or samples obtained during drilling. Predominant material types shown On the log may contain different materials and the change fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Project No. 40231-001-02 Date June 98 Log of Boring Figure A-3 (sheet I of 2) op I I . I I I I I I I I I I I I I I I I Logged By: JSS ee gen to gs or sampling method, classifications and laboratory testin methods Well Construction Date Drilled: 5/26/98 Boring Diam.(in.): 8 ~ :S -S "- u Q u "- ~ u ~ '" ~ ~ ~ o iil Drilling Contractor: Method/Equipment: Hollow Stem Auger Boring Number: B-3 Drive wt.Obs.): 140 Drop Dist.(in.): 30 35 . 50 . . 25 15 25 30 Casing Elev.(ft.): Cal Pac Groundwater Elevation (ft.): SZ i Not Eucountered Total Depth (ft,): 31.5 E ~ e- II u 0 1! .;;; 0 o~ u~ 0 u<B u" Z Q,e, ~ ~ u j';> a ~ ~ Q ~ '" 105 4.5 The substrata descriptions above are generalized representations and based upon visuaUmanual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times. Project No. 40231-001-02 30 16 24 30 35 Date June 98 Description (SW -SM) Silty SAND - yellow brown, moist, dense, some Silt (ML) Sandy SILT, yellow brown, very moist, stiff, very Sandy interbedded layers of (CL) CLAY, Sandy Silt (ML), and (SM) Silty SAND - olive brown, moist, dense, Clay has low plasticity, fine grained Sand Total Depth = 31.5 feet below ground surface Groundwater was not encountered Log of Boring Figure A-3 (sheet 2 of 2) ~\, I I I I I I I I I I I I I I I I I I I Logged By: JSS Date Drilled: 5/26/98 ee gen to gs or Boring sampling method, Diam.(in.): classifications and laboratory testin methods 8 u S Co Wen ?: ~ .s u ~ Construction fr ~ 0 0 ~ 0; '" 5 10 IS 7 8 11 17 23 28 15 16 20 Drilling Contractor: Method/Equipment: Hollow Stem Auger Drive wt.(lbs.): 140 111 12.5 108 14.0 Boring Number: B-4 Drop Dist.(in.): 30 E " ~ u u E ~ .~ 0 E o~ u_ = Description u", ull'< Z o,e, " - u i:' a ~ ~ 0 '0 ~ ::;: '" Log of Boring Figure A-4 The substrata descriptions above are generalized representations and based upon visual/manual classification of cuttings and/or samples obtained during drilling. Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Date June 98 Casing Elev.(ft.): Cal Pac Groundwater Elevation (ft.): SZ i Not Encountered Total Depth (ft.): 31.0 Project No, 40231~01~2 Fill: (SM) Silty SAND - fine grained, brown, slightly moist, loose, pieces of asphaltic concrete Pauba Formation (Qp): (SM) Silty SAND - fine grained, dark ohve brown, moist, dense :<S-P~SM) Silti SAND -, fine - graTned~ low silt - - - - - - - - _ ------------------------------- (SM) Silty SAND, fine grained, dark olive brown, moist, dense (ML) Sandy SILT - olive brown, stiff, moisl, low Sand (CL) CLAY - olive brown, moist, very stiff, low plasticity (sheet I of 2) 1;'0 I I I I I I I I I I I I I I I I I I I Logged By: JSS e gen to gs~ or sampling method, classifications and laboratory testin methods Date Drilled: 5/26/98 Boring Diam.(in.): 8 u S "- Well ?: ~ .s u ~ Construction 0. ~ "- 0 u ~ a; Cl 27 50 25 30 35 17 18 29 Drilling Contractor: Method/Equipment: Hollow Stem Auger Boring Number: B-4 Drive wt.(lbs.): 140 .Dr~p DISt,(m.): 30 Cal Pac Casing Groundwater Elevation (ft.): Elev.(ft.): SZ i Not Encountered Total Depth (ft.): 31.0 E - .~ ~ u 0 ~ c~ u~ ~ u~ u"" Cl.e - - u i:' E 1 ~ Cl '0 :;: '" 117 14.5 The substrata descriptions above are generalized representations and based upon visuaI/manual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated. Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Project No. 40231-001-02 Date June 98 Description (ML) Sandy SILT - olive brown with rust brown, moist, stiff, low Sand interbedded (SM) Silty SAND and (SW) SAND - fine grained, light tan to off-white, slightly moist, dense interbedded (SM) Silty SAND and (SW) SAND - fine grained, light tan to off-white, slightly ,moist, dense Total Depth = 31.0 feet below ground surface Groundwater was not encountered Log of Boring Figure A-4 (sheet 2 of 2) ~ I I I I I I I I I I I I I I I I I I I Logged By: JSS ee "Legen to gs or sampling method, classifications and laboratory testin methods Date Drilled: Drilling Contractor: Method/Equipment: Hollow Stem Auger 5/26/98 Boring Diam.(in.): 8 Cal Pac Casing Groundwater Elevation (ft.): Elev,(ft.): SZ i Not Encountered Total Depth (ft.): 31.2 Drive wt.(Ibs.): 140 Boring Number: B-5 Drop Dist.(in.): 30 ~ S "" ~ Well ?: .s ~ ~ Construction ~ ~ "" 0 ~ a; Q '" '" = ~ ;,. II ~ 0 ~ .~ 0 o~ u_ ~ Description ~.B ~"" Z Q,e, ~ ~ ~ i:> ~ 0. Q '0 E '" ::E '" Fill: (SM) Silty SAND - fine grained, dark brown, slightly moist, loose The substrata descriptions above are generalized representations and based upon visuallmanual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Project No, 40231-001-02 Date June 98 Log of Boring Figure A-S (sheet I of 2) J>.p I II I I I I I I I I I I I I I I I I I Logged By: JSS ee gen to Logs or sampling method, classifications and laboratory testin methods Date Drilled: 5/26198 Boring Diam.(in.): 8 u S Q. Well ~ ~ .s u ~ Construction ]- ~ Q. 0 u Iii Cl ~ '" IS 25 40 25 30 30 40 50/2" 22 50 Drilling Contractor: Method/Equipment: Hollow Stem Auger Drive wt.(Ibs.): 140 97 Boring Number: D-5 Drop Dist.(in.): 30 E " ~ u u E 1! .~ 0 c~ u~ 0 Description u"' u"" Z Cl,e, " ~ u ~ a 0. Cl ~ S '0 ~ ::E '" Log of Boring Figure A-5 19.0 The substrata descriptions above are generalized representations and based upon visuallmanual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated. Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times. 35 Date June 98 Cal Pac Casing Groundwater Elevation (ft.): Elev,(ft.): SZ i Not Encountered Total Depth (ft.): 31.2 Project No. 40231~01~2 interbedded (SM) Silty SAND and (ML) Sandy SILT - fine grained, light brown, moist, dense (ML) Sandy SILT - light olive brown, moist, stiff -. -' . '.... ... .t... .-:.r . . . , i;.. t..... .'. , . (SP-SW) Silty SAND - fine grained, tan, slightly moist, dense, low Silt Total Depth = 31.2 feet below ground surface Groundwater was not encountered (sheet 2 of 2) A.\ I . I I . I . I I I I .. II I . I I . . Logged By: Date Drilled: JSS ee gen to gs or sampling method, classifications and laboratory testin methods v ,s "- >e Well >. .... -5 v ~ Construction l ~ "- 0 v i'ii Q '" 5 Backfilled with Soil Cunings 10 5/26/98 Boring Diam.(in.): 8 13 20 20 Drilling Contractor: Method/Equipment: Hollow Stem Auger Boring Number: B-6 Drive wt,(Ibs.): 140 Drop Dist.(in.): 30 15 19 25 36 11 19 24 11 20 30 20 20 25 Casing Elev.(ft.): Cal Pac Groundwater Elevation (ft.): SZ i Not Encountered Total Depth (ft.): 31,0 E ~ t;- v v E ~ '~ 0 o~ u~ Description v,B e"" z Q,e, g- v C ~ Q 'S :E '" 115 11.5 122 11.5 (CL-ML) Sandy CLAY and Sandy SILT - olive brown to dark brown, moist, firm, some silty Sand 115 12.5 Date June 98 Fill: (SM-ML) Silty SAND and Sandy SILT - olive brown to dark brown, moist, firm (SM,ML) Silty SAND and Sandy SILT - olive brown to dark brown, moist, firm (SM) Silty SAND - fine grained, light brown to dark gray, moist, dense, occasional gravel up to 1" in size (SM) Silty SAND - fine grained, light brown to dark gray, moist, dense, occasional gravel up to 1" in size 120 10,5 118 11.0 The substrata descriptions above are generalized representations and based upon visuallmanual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type to another could be different than indicated, Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times, Project No, 40231~01~2 Log of Boring Figure A-6 (sheet I of 2) A.,?/ II I I I I I I I I I I I I I I I I I I I Logged By: Date Drilled: JSS 5/26/98 ee gen to gs" or Boring sampling method, Diam.(in.): classifications and laboratory testin methods 8 u oS 0- 'e Well >> .... .s- " ~ Construction l ~ 0- 0 u liS 0 '" 22 . . . 5013" . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 . 60 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 . . 30 . . . 5015" . . . . 35 Drilling Contractor: Method/Equipment: Hollow Stem Auger Boring Number: Drive wt.(Ibs.): 140 B-6 .Dr~p DlSt.(m.): 30 Casing Elev.(ft.): Cal Pac Groundwater Elevation (ft.): SZ i Not Encountered Total Depth (ft.): 31.0 " ~ '" u u " -S .;;; 0 =~ u~ 0 u~ e"" z 0", ~~ u j';> l 0 'S ::E '" 105 4.5 105 5.0 The substrata descriptions above are generalized representations and based upon visual/manual classification of cuttings and/or samples obtained during drilling, Predominant material types shown on the log may contain different materials and the change fro one predominant material type 10 another could be different than indicated. Descriptions on this log apply only at the specific location at the time of drilling and may not be representative of subsurface conditions at other locations or times. Project No, 40231-001-02 Date June 98 Description Pauba Formation (Qp): (SM-SW) Silty SAND to SAND - fine gramed, light tan, slightly moist, dense (SM-SW) Silty SAND to SAND - fine grained, light tan, slightly moist, dense (SM-SW) Silty SAND to SAND, fine grained, light tan, slightly moist, dense Total Depth = 31.0 feet below ground surface Groundwater was Dot encountered Log of Boring Figure A-6 (sheet 2 of 2) A!/ I I I I I I I I I I I I I I I I I I I I SECOR International Incorporated Trench Logs Test Pit No. Depth (ft.) Description T-I 0.0 - 3,0 FILL: Silty Fine Sand (SM), yellow brown, slightly moist, traces asphalt, red clay pipe, wood and metal, occasional gravel. T-2 0.0 - 3,0 FILL: Silty Fine Sand (SM), medium yellow brown, slightly moist, traces of asphalt and wood, occasional gravel. T-3 0.0 - 4.0 FILL: Silty Fine Sand (SM), light to medium yellow brown and gray, slightly moist, traces of plastic, asphalt and ceramics, occasional gravel. T -4 0.0 - 3,0 TOPSOIL: Silty Fine Sand (SM) dark gray brown, slightly moist 3.0 - 5,0 PAUBA FORMATION: Silty Fine Sand (SM), light yellow brown, moist, massive T-5 0.0 - 1.5 TOPSOIL: Silty Fine Sand (SM), medium to dark gray brown, slightly moist. 1.5 - 5.5 PAUBA FORMATION: Sand with varying amounts of silt (SM,SP,&SW), moist, light yellow brown to gray brown, massive to localized laminations (near horizontal). ~ I ~ I I I I I I I I I I I I I I I I I APPENDIX B TEST RESULTS ~ I I I I I I I I I I I I I I I I I I I I TABLE 1 SUMMARY OF EXPANSION INDEX TEST RESULTS SAMPLE ID SOIL DESCRIPTION EXPANSION INDEX lED B-1 SANDY SILT(ML) 45 B-2 SILTY SAND(SM) 22 TABLE 2 SUMMARY OF R-VALUE TEST RESULTS SAMPLE ID SOIL DESCRIPTION MEASURED R-VALUE 300 psi Exudation Pressure T-2 SANDY SILT(ML) 17 #- I I I I I I I I I I I I I I I I I I I 0 1 2 ~ 3 C Gl l:! Gl 4 Q. M Z 0 ~ 5 Q ::i 6 0 UJ Z 0 7 (.) 8 9 10 0,1 PRESSURE - kips per ft.2 0.2 0.3 0.4 0,5 1,0 2,0 3,0 4.0 5,0 10,0 >-- -- r-. --- \J"--... ~ I J...... ~ " . SAMPLE INFORMATION BORING No. B-1 SAMPLE DEPTH: 10' o TESTED AT NATURAL MOISTURE CONTENT . TESTED WITH WATER ADDED SECOR ACAD\ LlBRARY\ B-2. OWG CONSOLIDATION TEST RESULTS PROJECT: 40231 -001 -02 FIGURE: B-1 0..'\ :. I . I I I I I I I I I II I I I I I I 0 1 2 - 3 C Gl e Gl 4 a. ~ Z 0 - 6 ~ Q :i 6 0 en z 0 7 (J 8 9 10 01 PRESSURE - kips per ft.2 o 2 0 3 0,4 0,6 1.0 2,0 3,0 4,0 6,0 10,0 :l....... r--... ~ ...... ~ .... ~ I--. '" , l"- . SAMPLE INFORMATION BORING No. B-2 SAMPLE DEPTH: 5' o TESTED AT NATURAL MOISTURE CONTENT . TESTED WITH WATER ADDED SECOR ACAD\UBRARy\8-2.DWG CONSOLIDATION TEST RESULTS PROJECT: 40231 -001 -02 FIGURE: B-2 Afb '. I I I I I I I I I I I I I I I I I I 0 1 2 - 3 C Gl l::! Gl 4 Co M Z 0 - 5 !;( Q ::I 6 0 (/) Z 0 7 (.) 8 9 10 PRESSURE - kips per ft.2 0.1 0,2 0,3 0.4 0,5 100 1,0 2,0 3,0 4,0 5,0 4- -i: \ 1\ \ \ \ 1\ \ L. \ I\.. ... JW' SAMPLE INFORMATION BORING No, B-2 SAMPLE DEPTH: 12 1/2' o TESTED AT NATURAL MOISTURE CONTENT . TESTED WITH WATER ADDED SECOR ACAD\UBRARy\S-2.DWG CONSOLIDATION TEST RESULTS PROJECT: 40231 -001 -02 FIGURE: B-3 1\'\ , I I I I I I I I I I I I I I I I I I I 0 1 2 - 3 l::: Gl e Gl 4 Co ~ Z 0 ~ 5 Q :J 6 0 en z 0 7 0 8 9 10 PRESSURE - kips per ft.2 01 02 030405 1,0 100 2,0 3,0 4,0 5,0 "- ........ ~ ~ ~ -...... - "'- '" , SAMPLE INFORMATION BORING No. B-3 SAMPLE DEPTH: 1 0' o TESTED AT NATURAL MOISTURE CONTENT . TESTED WITH WATER ADDED SECOR ACAD\UBRARy\B-2.DWG CONSOLIDATION TEST RESULTS PROJECT: 40231 -001 -02 FIGURE: 8-4 ~o I I I I I I I I i I I II I I I I I I I I 0 1 2 ~ 3 C Gl e Gl 4 D. ~ Z 0 ~ 5 - ...I 6 0 en z 0 7 0 8 9 10 0,1 PRESSURE - kips per ft.2 0,2 0.3 0.4 0.5 1.0 2,0 3,0 4,0 5,0 100 , Cli:. ---- I<D-. "- ~ "- ~. "- '" '" '\ ... "- ... r\ .. -,.r SAMPLE INFORMATION BORING No. B-3 SAMPLE DEPTH: 15' o TESTED AT NATURAL MOISTURE CONTENT . TESTED WITH WATER ADDED SECOR ACAD\L1BRARy\8-2.DWG CONSOLIDATION TEST RESULTS PROJECT: 40231 -001 -02 FIGURE: 8-5 ~\ II I I I I I 'I I I I I I I I I I I I I Ul Ul r.:I U:: E-< Ul U:: -.,: ~ Ul 2,0 /' ./ Y / V rz, Ul ~ Z - Ul Ul r.:I U:: E-< Ul 1.0 U:: ~ :r: Ul ,0 ,0 5,0 2,0 3,0 NORMAL STRESS IN KSF 1.0 4.0 2,0 ~ ~ ~ "" "- d '-' -... .... lIP rz, Ul ~ Z - 1.0 ,0 ,0 .2 .1 .3 .4 .5 HORIZONTAL DEFORMATION IN INCH BORING/SAMPLE : 84 DEPTH (ft) DESCRIPTION : Clayey Silt (ML) STRENGTH INTERCEPT (ksf) .489 FRICTION ANGLE (degree) 32.0 15 (PEAK STRENGTH) (PEAK STRENGTH) MOISTURE DRY DENSITY VOID NORMAL PEAK RESIDUAL SYMBOL CONTENT (%) (pc!) RATIO STRESS (ks!) SHEAR (ksf) SHEAR (ksf) 0 27.4 103.1 .634 .50 ,70 ,34 0 30.4 96.3 .749 1.00 1.26 ,51 {:, 25.4 97.7 .724 2.00 1.69 1.32 DIRECT SHEAR TEST SECOR/40231-001-02 9' 'I I I I I I I I I I I I I I I I I I I 2,0 1.0 /" V /' / / IZ, Ul :>::: z - Ul Ul r.1 0:; E-< Ul 0:; r;j :I: Ul ,0 ,0 1.0 2,0 3.0 NORMAL STRESS IN KSF 4.0 5,0 2,0 IZ, Ul :>::: z - Ul Ul r.1 1.0 0:; E-< Ul 0:; < ~ Ul ,0 ,0 .1 .2 ,3 .4 .5 HORIZONTAL DEFORMATION IN INCH BORING/SAMPLE : 85 DEPTH (it) DESCRIPTION : Silty Sand/Sandy Silt STRENGTH INTERCEPT (kst) .426 FRICTION ANGLE (degree) 31.6 20 (PEAK STRENGTH) (PEAK STRENGTH) MOISTURE DRY DENSITY VOID NORMAL PEAK RESIDUAL SYMBOL CONTENT (%) (pct) RATIO STRESS (kef) SHEAR (kst) SHEAR (kst) 0 17.7 110,7 ,521 .50 .72 ,43 0 23.7 103.9 .621 1.00 1.06 ,46 /:, 31.5 98,0 .720 2,00 1.65 ,60 DIRECT SHEAR TEST SECOR/40231-001-02 ~? I I I I I I I I I I I I I I I I I I I ~ 6100 Quail Valley Court Riverside, CA 92507 P,O. Box 432 Riverside, CA 92502 PH (909) 653-3351 FAX (909) 653-1662 Environmental Laboratory Certification #1156 ~ E,S, BABCOCK & SONS, INC, EsrAeUSHEDl906 2836 Client: Secor Todd Shibata 23564-F Business Center Dr. I ,.}..,...,....,...."...,........",.P..".".,..,..a.,...s.'......e,...'...,.......,..,....,.....,..'.,.,..,...1,..,.,i,...,o..,."...,.,&, ."..,...,.,'.""...1,.'.",'....,'....,....,.........,'........,....,.,"."1 ~~.....ii9}I......$~~$74.pbdt ............ Date Reported: 07/29/98 Collected By: Date: Time: Submitted By: Date: 07/24/98 Time: 0900 Redlands,CA 92373 Client I.D.: Site: Description: Matrix: B4 0-4 JOB 40231-001-02 Temecula soil-ag Constituent Result Date / Analyst Method RL Water Extractable Sulfate w##~g...$1S#$'iii:i#00?~~.,.$lj't!::i#~4~....... Saturated Resistivity '.........."...i.}...II~....,. ".....,'.....,......,.,...~##,..~#~~i,...i. ohm-em SM 2520B '" .,'. ,,':~~;~;j:; . 980728/BW 150 ..--.........."......."...."." ,.,...--........-....-..-,.-----,',.,,',' "',",.,.,..,..,..--...... . ," ...__d............. .... '.....................................;i9/... 1600 5. ...""'..."............. 5 ...................... ...... .-.,'-.-.-.-....-.--.-..'-.-.-...-.-..'-.. :'::::c::_:-:.:__,:.;,',:-:",;,;.,,:.;., ..;:(:::.;:: O. NO = None detected at RL (Reporting Limit). RL units same as result. Results reported in ppm expressed on air-dried soil basis. cc: ?A , I I I I II I I i I I I I I I I I I I I I I I APPENDIX C GUIDE SPECIFICATIONS FOR PLACEMENT OF FILL AND BACKFILL /" -;P I I I I I I I I I I I I II I I I I I I APPENDIX C GUIDE SPECIFICATIONS FOR PLACEMENT OF FILL AND BACKFILL The guide specifications presented in this Appendix, together with the geotechnical report should be used in development of technical specifications for the project. The following sections of these guide specifications should be regarded as the minimum requirements to be included in the project specifications, I) All filling and backfilling operations should conform with applicable local building and safety codes and to the rules and regulations of those governmental agencies having jurisdiction over the subject construction, The earthworks contractor is responsible to notify governmental agencies, as required, and the Project Soils Engineer at the initiation of grading, and any time that grading operations are resumed after an interruption, Each step of the grading should be approved in a specific area by the soil engineer and, where required, by the applicable governmental agencies before proceeding with subsequent work, 2) Prior to the start of grading, all debris, vegetation, deleterious materials, surface obstructions and loose unapproved fill shall be removed and disposed off site, Any existing irrigation, drainage or utility lines, or other abandoned subsurface structures shall be removed, destroyed or abandoned in compliance with specifications and recommendations from the Project Soils Engineer, 3) Within areas to receive fill or to provide structural support, all existing fill and dry porous (potentially collapsible) or loose soils shall be excavated to expose dense, non- porous natural deposits of soil. 4) Where fill is placed on a sloping ground that is steeper than 20 percent, the ground to receive fill shall be prepared by proper keying and benching, The vertical and horizontal sizes of the keys and benches shall be determined by the Soils Engineer. In general, it shall be required that a keyway be constructed under the toe of the fill at least 10 feet in width, and fIll be placed and compacted on nearly horizontal benches only, 5) The excavated areas shall be observed by a representative of the Project Soils Engineer to evaluate if suitable materials have been exposed, 6) Fill, on site or import, shall consist of materials approved by the Soils Engineer. Fill shall be free of debris, organics and deleterious materials, Rock 3 inches or larger in diameter shall not be used, Imported fill soil should have a plasticity index no greater than 5, JN4023I-001-02 Ihg\98-08aug.msw\gi231 tem.doc lof2 -6'" I I I I I I I I I I I I I I I I I I I 7) Fill soils shall be placed in lifts not exceeding 6 inches, brought to within plus or minus two percent of optimum moisture content and compacted to not less than the density specified below, 8) Fill slopes shall be constructed at intervals not exceeding 4 feet vertically. Placement of fill shall not continue until the slope face, at a depth of 6 inches, measured perpendicular to the slope face, has been tested and found to be compacted to at least the density specified below, 9) All fill and backfill shall be compacted to at least 90 percent of the laboratory dry density as determined by the ASTM D-1557 test procedure, except for the top 6 inches of subgrade and the aggregate base layer underlying concrete slabs-on-grade pavements, which shall be compacted to at least 95 percent of the laboratory maximum dry density, 10) Areas to receive backfill shall be cleared of trash, debris, and loose, soft, or disturbed soils, Prior to placement of backfill, the areas shall be observed and approved by the Project Soils Engineer. 11) Backfill shall be compacted by mechanical means to the density specified above, The contractor shall select equipment and techniques to accomplish completion of the backfill to the specified density such that backfilling operations will result in no movement or damage to completed work, 12) Observation and field moisture and density tests shall be performed by the Project Soils Engineer at the time of fill and backfill placement to verify that the specified percentage of moisture content and the required degree of compaction have been obtained, Where the requirements or specifications are not met, additional effort shall be made with appropriate adjustment of the compaction energy or moisture content as necessary until the requirements and the specifications are met. 13) Wherever, in the opinion of the Soils Engineer or Owner's Representatives, an unstable condition is being created, either by cutting or filling, the work shall not proceed in that area until an investigation has been made and the grading plan revised, if necessary, JN40231.QOI-02 Ihg\98-OSaug.msw\gi23ltem.doc 20f2 -:)1.