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Home My WebLink AboutFinalSoilCompaction&DesignRecommendation(Jul.31,1998) I I I I I I I I I I I I I I I I I I I @ O Plinlell on Recycled Paper Converse Consultants Over 50 Years of Dedication in Geotechnical Engineering and Environmental Sciences FINAL SOIL COMPACTION AND GEOTECHNICAL DESIGN/CONSTRUCTION RECOMMENDATION REPORT Tracts 24182-1 .and -2 Paseo Del Sol Master Planned Community T emecula, California Prepared for: Newland Associates 27393 Ynez Road, Suite 253 Temecula, CA 92591 Converse Project No. 96-81-420-30 July 31, 1998 10391 Corporate Drive, Redlands, California 92374 Telephone: (909) 796-0544 . Facsimile: (909) 796-7675 . e-mail: ccieconv@aoLcom \ I I @ Converse Consultants Over 50 Years of Dedication in Geotechnical Engineering and Environmental Sciences I I I July 31, 1998 Mr. Dean Meyer, R.C.E. Director of Engineering & Development Newland Associates 27393 Ynez Road, Suite 253 Temecula, CA 92591 I Subject: FINAL SOIL COMPACTION AND GEOTECHNICAL DESIGN/ CONSTRUCTION RECOMMENDATION REPORT Tracts 24182-1 and-2 Pas eo Del Sol Master Planned Community Temecula, California Converse Project No. 96-81-420-30 I I I Dear Mr. Meyer: Converse Consultants (Converse) has prepared this report to present results of our field observation and density testing during rough grading of the above-referenced residential tracts in the city of Temecula, California. Our services were rendered in accordance with our proposal dated May 15,1997. I I I I I I I I .- I' This report also contains our recommended geotechnical design and construction recommendations for various facilities generally associated with residential developments including foundations for one- and two-story wood-frame buildings, slabs-on-grade, retaining walls, and concrete walkways driveways and curb and gutter. Recommendations regarding pavement design and construction for various streets will be presented in a separate report. Results of the field density tests are presented in Appendix A, Field Density Testing. Results of the relevant laboratory tests performed on representative samples of subgrade soils retrieved from the building pads and street areas are presented in Appendix B, Laboratory Testing. We appreciate this opportunity to be of service to Newland Associates. If you have any questions or need additional information, please do not hesitate to contact us. CONVERSE CONSUlTAN S Hashmi S. E. Quazi, Ph. D., P. E. Senior Vice President/Principal Engineer Dist.: 5/Addressee MSI/QSH/bac OPrinledOl'l Recycled Paper 10391 Corporate Drive, Redlands, California 92374 Telephone: (909) 796-0544 . Facsimile: (909) 796-7675 . e-mail: ccieconv@aol.com 'Z-- I I I I I I PROFESSIONAL CERTIFICATION This report has been prepared by the staff of Converse Consultants Inland Empire (Converse) under the supervision of the professional engineers whose seals and signatures appear hereon. The findings, conclusions, recommendations, or professional opinions presented in this report were prepared in accordance with generally accepted professional engineering principles and practice in effect in Southern California at this time. There is no other warranty, either express or implied. r/l--& - ~ '- 'F~ VI( - /J1~2 IJIiL I I I I I I I I I II I Mohammed S. Islam, Ph.D., P. E. Senior Project Engineer Michael O. Cook, C. E. G. 1716 Project Geologist _._~ "~--;:--ESS:;-;::" ~ /./0\'\'- . 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Senior Vice President/Principal Engineer 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 2 :; I I TABLE OF CONTENTS I I I 1.0 INTRODUCTION ................................................................................................................................................ 1 2.0 PROPOSED DEVELOPMENT ..........................................................................................................................1 3.0 PROJECT BACKGROUND ...............................................................................................................................2 I 4.0 SCOPE OF WORK ..............................................................................................................................................2 4.1 FIELD SERVICES ................................................... ...................................................................... ......................... 2 4 .2 LABORATORY TESTING..................................................................................... .................................................. 3 4.3 DA TA EVALUATION AND REPORT PREPARA TION ................................................................................................ 3 5.0 SITE CONDITIONS PRIOR TO GRADlNG.................................................................................................... 3 I I I 6.0 SITE GRADINGIEARTHWORK REQUIREMENTS..................................................................................... 4 7.0 FIELD OBSERVATION AND DENSITY TESTING ...................................................................................... 5 8.0 LABORATORY TESTS ...................................................................................................................................... 6 I I I I I I I 9.0 SITE CONDITIONS AFTER GRADING..........................................................................................................7 9 .1 SUBSURFACE CONDITIONS........................................................................ .......................................................... 7 9.2 GROUNDWATER .................................................................................................................................................. 8 9.3 SEISMIC HAZARDS...................................................................................................................................... ......... 8 9.3.1 General.......... .............................................. ........................ ................... ................ 8 9.3.2 Faulting and Seismicity.................... ......................... ............... ............. ..................... .......... 9 9.3.3 Liquefaction Potentia!.................. .................... ........ . ........ ............... ..........9 9.3.4 Seismically-Induced Graund Settlement.............. ....................... .............. ............... ........... 9 10.0 DATA ANALYSIS AND INTERPRET A TION ............................................................................................... 10 11.0 CONCLUSIONS................................................................................................................................................. 12 12.0 DESIGN AND CONSTRUCTION RECOMMENDATION .......................................................................... 12 12.1 BUILDING FOUNDATION AND RETAINING WALLS .............................................................................................12 12.2 SLABS-ON-GRAOE .............. .............................................................................................................................. 13 12.3 FOUNDA TION SETTLEM ENT ............................................................................................................................... 15 12.4 CONCRETE WALKS, DRlVEWA YS, ACCESS RAMPS, CURB AND GUTTER........................................................... 17 12.5 CORROS ION PROTECTION........................................... .............................................. ......................................... 17 12.6 SITE DRAINAGE, SLOPE PROTECTION AND LANDSCAPE IRRIGATION RECOMMENDATIONS .............................. 18 13.0 ON-SITE TRENCH BACKFILL COMPACTION .........................................................................................19 13.1 GENERAL ............................................................................................ ..................................... . ..................... 19 13.2 RECOMMENDED SPECIFICATIONS FOR PLACEMENT OF TRENCH BACKFILL ............................. ......................... 19 14.0 CLOSURE........................................................................................................................................................... 20 REFERENCES ...............................................................................................................................................................21 I I I 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFllEI1996196-420-30 t\ I I I I I I I I I I I I I I I I I I I APPENDICES Appendix A, Field Density Testing Appendix B, Laboratory Testing Appendix C, Soil Corrosivity Study Appendix 0, Liquefaction Potential and Seismically Induced Ground Settlement Analysis ILLUSTRATIONS Figure No.1, Site Location Map...............................................................following page no. 1 Figure No.2, Lot Identification Map........................................................ following page no. 10 Drawing No.1, Field Density Test Location Map.................................................in map pocket Drawing No.2, Alluvial Removal Contour Map.................................................... in map pocket 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 ii ~ I I I I I 1 .0 INTRODUCTION This report contains results of our field observation and density testing during rough grading of the proposed residential Tracts 24182-1 and -2 situated within the Paseo Del Sol Master Planned Community in the city of Temecula, California. This report also contains our site-specific geotechnical design and construction recommendations for various facilities generally associated with residential tract development. I I The location of the subject tracts is shown in Figure No.1, Site Location Map. These tracts were rough graded by the earthwork contractor Kemmis Equipment, Inc. of Murrieta, California during the period from May 26, 1998 through July 6, 1998. Earthwork associated with the rough grading was performed in accordance with the requirements and the recommendations set forth in the following project plans and specifications: . Rough Grading Plans, Tract 24182-1, -2, -3 and -4, Sheets No.1 through 8, prepared by Keith International, Inc., Inland Empire Division, Moreno Valley, California, dated March 6, 1998. i I I . Supplemental Geotechnical Investigation, Tracts 24182-1 and -2, Paseo Del Sol Master Planned Community, Temecula, California, prepared by Converse Consultants, Redlands, California, dated May 19, 1998, Project No. 96-81-420-06. . The grading requirements of the city of Temecula, California and Appendix Chapter 33 of the Uniform Building Code (1994). I I I I I I I I I I The Sheets No. 6 and 7 of the above-referenced rough grading plans are included as Drawing No.1, Field Density Test Location Map ISheets 1 and 2). This report was prepared for the tracts described herein and are proposed to be developed as single family residences comprising one- and two-story structures. This report is intended for use solely by Newland Associates and its authorized agent(s). It may not contain sufficient information for use by others andlor for any other purposes. 2.0 PROPOSED DEVELOPMENT The subject Tracts, as shown in Figure 1, Site Location Map, are located within the Paseo Del Sol Master Planned Community in the city of Temecula, California. These tracts encompass approximately 44.5-acres of graded area. These tracts are bounded on the north by Campanula Way and De Portola Road, east by Tract 24182-5, south by Highway 79 and west by Tract 24182-3 and Campanula Way. The Tracts 24182-3 and -5 were mass graded concurrently with the subject tracts. The subject tracts are proposed to be developed as single-family residential housing complexes. The project will include construction of 95 and 61 one- andlor two-story single-family residences, in Tract 24182-1 and -2, respectively. The project also includes driveways, streets with curb and gutters, sidewalks, above- and below ground utilities and a park site. The residences are likely to be wood-frame structures founded on continuous andlor isolated spread-type concrete footings with slabs-on-grade. The vertical loads on continuous and isolated footings are anticipated to be less than 2,000 pounds per linear foot and 50,000 pounds, respectively. The project does not include construction of any 96.81-420-30 Converse Consultants \CCIENT\OFFICEIJOBFILE\ 1996\96-420-30 1 c, I I I I I I I I I I I I I> .0 I Ig . ~ 11 u . > o I~ I I TO RIVERSIDE TO CORONA OJ c =:t "" :;t) -" r;; r o ~ ::\ Sri '!:\ ~ ~ ~~RGARlr '" z " :1 C'1 Ul 1'0 0 :1, ?-t'" C ~ ?,,-UBA City of Ie ~ '-" PORIOLA aE. 70 HIG\'WIAY "\- :,IAIt- ) TO SAN DIEGO VICINITY MAP NOT TO SCALE SITE LOCATION MAP FINAL SOIL COMPACTION AND GEOTECHNICAL DESIGN / CONSTRUCTION RECOMMENDATION REPORT ._ TRACT - 24182 -1 & 2 Temecula, California For: Newland Associates @converse Consultants PrOject No 96-81-420-30 Figure No 1 1. I I I I I I retaining walls of significant height. The perimeter retaining walls for such residential developments are usually on the order of six (6) feet in height, constructed of masonry blocks a[ld founded on concrete footings. 3.0 PROJECT BACKGROUND The subject tracts are located within the Paseo Del Sol Master Planned Community in the city of Temecula, California. Prior to the current rough grading, these tracts, except Lots No. 17 through 42 of Tract 24182-1, had been mass graded with Tracts 24183 through 24186, and Tract 24188-1 of the Paseo Del Sol Master Planned Community. The mass grading was performed by the earthwork contractor ACI, Corona, California, during the period from October 1996 through June 1997. Earthwork associated with the mass grading was completed in accordance with the following project plans and reports: I I I I . Mass Grading Plan Tract No. 24182 and 24183, Sheets 1 through 3, dated August 13, 1997, prepared by Keith International, Inc., Inland Empire Division, Moreno Valley, California. . Preliminary Geotechnical Investigation, Eastern and Southern Portion of the "Meadows", Approximately 800-acre site, City of Temecula, California, dated April 26, 1996, prepared by Converse Consultants Inland Empire for Newland Associates, Converse Project No. 96-8-420-01. Converse performed full-time field observation and density testing during mass grading. Results of field observation and field density testing were presented in the following report: I I I I I I . As-Built Geology and Compaction Report of Rough Grading, Tract 24182 through 24186 and 24188-1, Paseo Del Sol Master Planned Community, T emecula, California, dated August 20, 1997, prepared by Converse Consultants Inland Empire for Newland Associates, Converse Project No. 96-81-420-01. The current project included rough grading the mass graded Tracts 24182-1 and -2 In accordance with the project plans and specifications referenced in Section No.1, Introduction. 4.0 SCOPE OF WORK Our scope of work for the current project included the following: 4. 1 Field Services I I I Converse soil technicians performed full-time field observation of grading and fill compaction testing to verify compliance of earthwork with the project plans and specifications. The project geologist and the engineer performed periodic field observation during grading. Field Observations are summarized in Section 6.0, Field Observation and 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 2 'I II ,I I I I Density Testing. The fill compaction test results are summarized in Appendix A, Field Density Testing. Our services included retrieval of representative samples of subgrade soils from the building pads and street areas for relevant laboratory testing. All samples were retrieved from the upper 12 inches of the subgrade soils. These samples were collected in plastic bags and immediately transported to the laboratory for testing. 4.2 Laboratory Testing Our scope of work also included laboratory testing to determine relevant engineering parameters for the purpose of fill compaction/quality evaluation and providing final geotechnical design and construction recommendations. I I I I I I I I I I I I I 4.3 Data Evaluation and Report Preparation The project engineer continuously reviewed the data obtained during field density testing for the purpose of quality assurancelcontrol. The results of the laboratory tests were analyzed and 'evaluated for the relevant engineering parameters. This report prepared to present summary of site conditions, field observation, results of field and laboratory testing, and final geotechnical design and construction recommendations for the proposed facilities. 5.0 SITE CONDITIONS PRIOR TO GRADING This section contains a brief discussion on the site conditions prior to grading. The above- referenced Preliminary Geotechnical Investigation report dated April 26, 1996, and the "Supplemental Geotechnical Investigation" report, dated May 19, 1998 contain detailed description on site conditions prior to grading. Prior to grading, the southern portion of Tract 24182-1 and Tract 24182-2 consisted of undeveloped land within the Pauba Valley. The topography within this portion of the site was characterized by ground surface sloping gently to the west and covered with light to dense vegetation. The northern portion of the Tract 24182-1 was comprised of highland with a steeply slopin9 hill in the north-central area and a deep canyon to the west. The hillside and the canyon were covered with moderate to heavy growth of vegetation. An approximately 40-foot by 180-foot wide abandoned concrete slab was buried at the south side of the hill. The ground surface elevation within the subject tracts ranged from approximately 1,090 feet above Mean Sea Level (MSL) at the southwest corner of Tract 24182-2 to about 1,190 feet above MSL at the top of the hill at the north-central area. The hill area was underlain by Pauba Formation bedrock mantled with a veneer of colluvium. The Pauba Formation bedrock comprised of soil-like sandstone, siltstone and silty claystone. Recent alluviallcolluvial deposits and older sandy alluvial deposits were 96-81-420.30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 3 C'b I I I I I I I I I I I I I I I I present at the bottom of the canyon with gentle to moderately sloped sidewalls. Some artificial fills were present along De Portola Road. The Pauba Valley portion of the site was underlain by alluvial soils to depths in excess of 50 feet from the existing ground surface. The alluvial soils in this area comprised of mainly loose to medium-dense silty sand and sand and with some interbedded layers of sandy silt. Groundwater was encountered at a depth of 17 to 20 feet in the exploratory borings drilled in 1996 within the Pauba Valley portion of the subject tracts. The above-referenced Preliminary Geotechnical Investigation report, dated April 26, 1996 and the "Supplemental Geotechnical Investigation" report, dated May 19, 1998, contain detailed description of the site conditions prior to grading. 6.0 SITE GRADING/EARTHWORK REQUIREMENTS The detailed earthwork requirements for mass grading are included in the above-referenced Preliminary Geotechnical Investigation report, dated April 26, 1996. The above-referenced As-Built Geology and Compaction Report of Rough Grading, dated August 20, 1997 contains a summary of these requirements. The above-referenced "Supplemental Geotechnical Investigation" report, dated May 19, 1998, contains detailed gradinglearthwork requirements for the current rough grading. The major earthwork requirements for rough grading are summarized below: . All vegetation and trash including the abandoned concrete foundation at the location of Lots No. 28 through 31 of Tract 24182-1 are to be removed from the grading areas. . All fills placed over existing slopes should be keyed into firm materials at the toe. Fills should be benched into the firm native and/or existing engineered fill materials. . The final bottom surfaces of all excavated areas should be observed and approved by the project geotechnical consultant prior to placing any fill and/structure. . Once approved, at least the upper six (6) inches of the excavated surfaces should be scarified, moisture conditioned, if necessary, and compacted to at least 90 percent relative compaction as per ASTM Standard 01557-91 prior to placing any fill andlor structures. . The cut Lots No. 18, and 29 through 31 of Tract 24182-1 should be overexcavated to at least five (5) feet below existing ground surface. . The cutlfill transition Lots No. 17, 19 through 23, 26 through 28 and 32 through 41 of Tract 24182-1 should be overexcavated to a depth of at least five (5) feet below proposed final grade. I I I . For the remaining lots in Tract 24182-1 and the entire Tract 24182-2, site grading should include removal and recompaction of the upper 18 inches of the existing fills placed during mass grading. 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 4 ~. il II I . Where existing fills placed during mass grading will be cut to reach the final grade, the subgrade should be overexcavated andlor scarified, and compacted to a depth of at least 24 inches below existing grade or 12 inches below proposed final grade. I I I I I I I I I I I I I I I I . The cut slopes should be constructed at slope of 2: 1 (H:V) or flatter. A stabilization fill with a backdrain should be constructed at the backyards of Lots No. 23 through 35 of Tract 24181-1 as shown in Drawing No.1, Geologic and Test Pit Location Map, included in the above-referenced Supplemental Geotechnical Investigation report dated May 19, 1998. The purpose of the fill slope was to stabilize a steep natural slope. . All fills, unless otherwise noted in the project geotechnical reports, shall be compacted to at least 90 percent relative compaction as defined in the ASTM Standard 01557-91. . The in-place density of the compacted soils shall be measured in accordance with the ASTM Standard 01556-91 (Sand Cone) andlor 02922-96 (Nuclear Gauge) methods. 7.0 FIELD OBSERVATION AND DENSITY TESTING Converse performed full-time field observation and density testing during rough grading. This section contains a summary of the field observations. In general, earthwork was completed in accordance with the recommendations included in the above-referenced Supplemental Geotechnical Investigation report, dated May 19, 1998. Earthwork equipment included 623- and 637-scrapers, D6-dozer, 824-dozer, blades and water trucks. Prior to the start of any earthwork, the subject tracts were cleared of vegetation and debris including the abandoned concrete foundation at the south of the hill. The existing hill slopes were also stripped of vegetation prior to the start of grading. Colluvial soils and Pauba Formation bedrock were exposed at the face of the slopes around the hill. The Pauba Formation bedrock comprises the majority of the slopes. The bedrock comprised of mainly medium- to coarse-grained, massive clayey sandstone with six (6) to 12 inches thick interbedded siltstone layers. The overlying colluvial soils comprised of mainly sandy silt and silty sand with clay, gravel and some cobbles. The back-cut for the recommended stabilization fill at the backyards of Lots No. 23 through 35 of Tract 24182-1 also exposed Pauba Formation bedrock comprising mainly massive clayey sandstone with six (6) to 12 inch-thick interbedded siltstone layers. The stabilization fill with a backdrain was constructed as recommended in the above-referenced Supplemental Geotechnical Investigation report, dated May 19, 1998. The cut lots around the hill were overexcavated to a depth of about five (5) feet below original ground surface. The cutlfill transition lots adjacent to the hill were overexcavated to a depth of about five (5) feet below finish grade. The upper 12 inches of the existing fill from the mass graded lots that needed additional fill to reach the finish grade were removed. The upper eight (8) to 12 inches of the excavated areas were then scarified, moisture conditioned and recompacted prior to placing any additional backfill/fills. 96-81-420-30 Converse Consultants \CCIENT\OFFICEIJOBFILE\ 1996\96-420-30 5 'P I I I I I I I I I I I I I I I I I I I The upper 12 inches of the final subgrade of the previously mass graded lots that were cut during rough grading to reach the finish grade were scarified, moisture conditioned and recompacted. Approximately 24 inches of compacted fills were placed over the greenbelt area within Tract 24182-2 during the current rough grading On-site soils removed from the cut areas around the hills, the previously mass-graded lots that were cut during rough grading and the overexcavated areas were placed as fill/backfill, where necessary. The fill soils were mixed and moisture conditioned and compacted mechanically to at least 90 percent relative compaction. At the end of each working day, the field soil technicians prepared a Daily Field Report of Grading, documenting the relevant geotechnical observations made during the day. A copy of the daily field report was submitted to the client's representative. Sand Cone (ASTM Standard 01556-9) and Nuclear Gauge (ASTM Standard 02922-96) test method were utilized to evaluate the in-place density of the compacted filllbackfill. These tests were conducted at randomly selected locations. The results of the field density tests are summarized in Table No. A-l, Summary of Field Density Test Results, in Appendix A, Field Density Testing. Tests performed in accordance with the Sand Cove (SC) method are designated SC in Table No. A-1. The remaining tests were performed per the Nuclear Gauge test method. The approximate locations of the field density tests are plotted in Drawing No.1, Field Density Test Location Map (Sheet 1 through 3). The relative compaction for each field density test reported in Table No. A-l, Summary of Field Density Tests, is obtained by dividing the measured in-place dry density by the maximum laboratory dry density of the same "Soil Type" presented in Table No. 8-1, Summary of Laboratory Maximum Dry Density and Optimum Moisture Content Tests, in Appendix B, Laboratory Testing. If the results of a field density test indicated less than 90 percent relative compaction the representative fill volume was reworked and retested until a subsequent test showed at least 90 percent relative compaction. 8.0 LABORATORY TESTS Representative soil samples were retrieved during grading and at the completion of grading for laboratory testing. Laboratory testing included the followings: . Sieve Analysis (ASTM Standard 0422-63) . Laboratory maximum dry density and optimum moisture content relationship tests (ASTM Standard 01557-91). . Expansion index tests (UBC Standard 18-2) . Direct shear tests (ASTM Standard 03080-90) . Consolidation tests (ASTM 02435-90) . Soil corrosivity tests (ASTM Standards 0512, 0513, G516, 01125, 01126, 02791, G51 and G57) . R-value tests (California Test Method 301-G). 96-81-420-30 Converse Consultants \CCIENT\OFFICE\JOBFILE\ 1996\96-420-30 6 \\ I I I I I I I I I I I I I I I I I I I I The procedure and - results of the laboratory tests are summarized in Appendix B, Laboratory Testing. 9.0 SITE CONDITIONS AFTER GRADING 9. 1 Subsurface Conditions The subject tracts are rough graded in accordance with the requirements and recommendations contained in the project plans and specification referenced in Section 1.0, Introduction, and Section 3.0, Project Background. The topography of the graded tracts is characterized by terraced residential building pads, gently sloped streets, a park site and a small hill at the north-central area. The ground surface elevation of the rough graded lots ranged from approximately 1,101 feet near Highway 79 to 1,138 feet near De Portola Road. The eastern and western hillsides are comprised of cut slopes on the order of 30 feet in height. The south side of the hill along the backyards of Lots No. 23 through 35 of Tract 24182-1 comprised of a fill slope on the order of 40 feet in height. A backdrain comprising of a six (6)-inch diameter perforated pipe encased in about nine (9) cubic-feet per feet of % -inch crushed rock wrapped by a geotextile was installed. The subsurface profile within the graded tracts, except the hill, area is comprised of engineered backfill/fill, recent alluvium older alluvium and Pauba Formation bedrock. The fill soils are comprised of on site-excavated soils and import from the concurrently graded tracts within the Paseo Del Sol Master Planned Community. The imported soils comprised of mainly Silty Sand (SM), Clayey Sand (SC), Sandy Silt (ML) and Sandy/Silty Clay (CU. These soils are derived mainly from the soil-like Pauba Formation bedrock. The cutlfill transition lots included Lots No. 17, 19 through 23, 26 through 28 and 32 through 41 of Tract 24182-1. These lots were overexcavated to depth of at least five (5) feet below finish grade. The combined thickness of the engineered fill including backfill (compacted soil placed to backfill overexcavation to original ground surface level) and fill (compacted soils placed over original ground surface level) within this portion of the site is on the order of five (5) to 25 feet. The fill thickness ranges from about 0.0 to 20 feet. Grading for Lots No. 18 and 29 through 31 of Tract 24182-1 was on the order of five (5) to 25 feet below existing ground surface. The remaining lots within Tract 24182-1 and the entire Tract 24182-2 are fill lots. Prior to placing any artificial fill during grading, the upper five (5) to 10 feet of eXisting recent alluvium, older alluvium, colluvium and bedrock were overexc3vated either to remove unsuitable loose near surface materials andlor to place at least 10 feet of compacted fills underneath the footing foundations within the Pauba Valley portion of the site. The Drawing No.2, Alluvial Removal Contour Map, depicts the contours of the elevation of the final bottom of the areas overexcavated during mass grading. 96-81-420-30 Converse Consultants \CCIENT\OFFICE\JOBFILE\ 1996\96-420-30 7 \~ I I I 'I I I Tract 24182-2 and the portion of Tract 24182-1 south of the "Recent Alluvium and Pauba Formation Bedrock or Older Alluvium Contact Line" shown in Sheet 2 of Drawing No.1, Field Density Test Location and Geologic Map, are underlain by engineered fill over recent alluvium. The subsurface profile within the Pauba Valley Portion of the site is comprised of engineered backfill and fill over recent alluvium. The combined thickness of the engineered fill including backfill and fill within this portion of the site is on the order of 15 to 25 feet. The thickness of the fill ranges from about seven (7) to 20 feet. As shown in Sheet 2 of Drawing No.1, Field Density Test Location and Geologic Map, the remainder of Tract 24182-1 to the north of the "Recent Alluvium and Pauba Formation Bedrock or Older Alluvium Contact Line" (referred to as the highland area) is underlain by engineered backfilllfill over either older alluvium or Pauba Formation Bedrock. The combined thickness of engineered backfill and fill over this portion of Tract 24182-1, excluding the above-referenced cut and cutlfill transition lots, ranges from about 15 to 30 feet. The fill thickness ranges from about 10 to 25 feet. I I I I I I I I I I I I I 9.2 Groundwater Groundwater was encountered in the exploratory borings drilled within the Pauba Valley portion of the site during field exploration performed for the above-referenced "Preliminary Geotechnical investigation" report, dated April 26, 1996. The depth to groundwater ranged from about 17 to 20 feet below existing ground surface. Groundwater was encountered at a depth of about seven (7) feet below existing ground surface in the exploratory boring drilled in 1988 within the Pauba Valley area adjacent to Highway 79. Based on the existing ground surface, which is raised by about seven (7) to 20 feet above the original ground surface, the depth to ground should be at least 25 feet from the finish grade. As discussed in the above-referenced As-Built Geology and Compaction Report of Rough Grading dated August 20, 1997, groundwater seepage was encountered at a location near the intersection of Ceserta Drive and Pavia Way. A subdrain was installed to drain perched groundwater to a nearby coarse alluvium layer. No perched groundwater was encountered during current rough grading. 9.3 Seismic Hazards 9.3.1 General Results of a detailed site-specific faulting and seismicity study performed for the Paseo Del Sol Master Planned Community are presented in the above-referenced As-Built Geology and Compaction Report of Rough Grading, dated August 20, 1997. The following is summary of the findings of this study. 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 8 \"?- I I I I I I 9.3.2 Faulting and Seismicity The subject tracts are located in Seismic Zone 4 in according with Figure 16-2, Seismic Zone Map of the United States, of the UBC (1994). These tracts, however, are not located within a currently designated State of California Earthquake Fault Zone. No active fault projects toward or through these tracts. The nearest known active fault is the Wildomar segment of the Elsinore Fault Zone, which is capable of generating an earthquake of Moment Magnitude (MM) 7.5. This fault may be classified as the "A" type seismic source as defined in Table 16-U, Seismic Source Type, of the UBC (1997). This fault is located approximately 1.5 miles (2.5 km) south-southwest from the subject tracts. I I I I I I I I I I I I I Based on a deterministic seismic hazard analysis, the subject tracts may experience a peak ground acceleration of about 0.60g, where g is the acceleration due to gravity, during an MM7.5 seismic event generated by the movement of the Wildomar Fault. Based on a site- specific probabilistic seismic hazard analysis, a maximum peak ground acceleration on the order of 0.36g has a 10 percent probability of exceedance in 50 years. 9.3.3 Liquefaction Potential Converse performed a detailed liquefaction study in 1998 for the Pauba Valley area. Results of this study were summarized in the above-referenced Preliminary Geotechnical Investigation report dated April 26, 1996. This analysis indicated that the Pauba Valley portion of the site was susceptible to soil liquefaction. Site conditions are improved due to removal of the upper five (5) to 10 feet of alluvial soils and the placement of compacted fill over the original ground surface level. The depth to groundwater from the ground surface as well as the effective confining stress is increased as a result of the backfill/fill placement. Results of a liquefaction analysis for the current site conditions are presented in Appendix 0, Liquefaction Potential and Seismically-Induced Ground Settlement Analysis. Based on these studies, the potential for soil liquefaction still exists, although to a lesser extent, within Tract 24182-2 and the Pauba Valley portion of Tract 24182-1 during a significant seismic event generated by the movement of the nearby Wildomar segment of the Elsinore Fault Zone. Due to the absence of shallow groundwater and dense soil conditions, the highland area of Tract 24182-1 north of the Recent Alluvium and Pauba Formation Bedrock or Older Alluvium Contact Line is not considered prone to soil liquefaction. 9.3.4 Seismically-Induced Ground Settlement Results of a seismically induced ground settlement analysis for the current ground conditions are presented in Appendix C, Liquefaction Evaluation. This analysis is based on estimated maximum credible ground acceleration of 0.60g. Based on this analysis, under the present conditions, the southern portion of Tract 24182-2 near Highway 79 is prone to about 3.0 inches of ground settlement during a maximum credible earthquake event associated with the nearby Wildomar Branch of the Elsinore fault. The estimated ground settlement near the highland area is estimate to be minimal, if any. 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 9 Y\. I I I I I I I I I I I I I I I I I I I The seismically induced differential ground settlement over the footprint of a single family residence is estimated to be on the order of 0.50 inches near the northern boundary of Tract 24182-2 to about 1.50 inches near Highway 79. 10.0 DATA ANALYSIS AND INTERPRETATION This section contains results of our analysis and interpretation of data obtained during laboratory testing. Typical gradation of the subgrade soils within the various lots are presented in Figures No. B-1, Grain-Size Distribution in Appendix B, Laboratory Testing. Results of laboratory compaction tests performed on samples of fill soils retrieved during rough grading are presented in Table B-1, Summary of Laboratory Maximum Dry Density and Optimum Moisture Content Tests, in Appendix 8, Laboratory Testing. Results of additional laboratory compaction tests performed at the completion of rough grading are presented in Figure No. 8-2, Compaction Test, in Appendix 8, Laboratory Testing. Based on these results, the laboratory maximum dry density and the optimum moisture content of the compacted fill soils tested ranged from 112.0 pounds-per-cubic-foot (pcf) to 131.5 pet and eight (8.0) percent to 16.0 percent, respectively. Results of expansion index tests performed on representative bulk samples of subgrade soils retrieved from the building pad areas are presented in Table B-2, Summary of Expansion Index Test Results. The lot classifications based on expansion index of the subgrade soils are presented below in Table No.1, Lot Classification Based on Expansion Index. The lot numbers in this table refers to the numbers shown in Figure No.2, Lot Identification Map. TABLE NO.1, LOT CLASSIFICATION BASED ON EXPANSION INDEX Exoansion Potential Very Low Low Medium High Expansion Index fEll 0-20 21-50 51-90 91.130 TRACT 24182-1 10-36,49-74, and 84-90 8, 9, 37-48 and 75-83 1-7 None lOTS NO. TRACT 24182-2 1-18, 28-37 and 54-61 19-27 and 38-53 None None Results of direct shear tests performed on remolded samples of the representative subgrade soils are presented in Figures No. B-3 through B-6, Direct Shear Test. Based on these results, the effective cohesion and internal friction angle of the subgrade soil samples tested ranged from 20 to 192 pounds-per-square-foot (psfl and 23.6 to 31.9 degrees, respectively. 96-81-420-30 Converse Consultants \CCIENT\OFFICEIJOBFILE\ 1996\96-420-30 10 ^ \~ I I I I I I I I I I I I I I~ .a I I~ ~ Il . > o I~ I I .-----/ ~- .~ --c ANUlA 49 50 28 51 29 52 ~ CENON WAY 24 59 2 !j! J2 23 "< 49 58 ~ "' ~ 3 33 22 50 57 "'- '" ~ ~ 4 ~ 34 21 35 51 56 .... 5 ~ 35 20 36 52 55 ~ 6 '" 36 19 37 53 54 '" 7 ST. HWY. 79 ( lOT IDENTIFICATION MAP FINAL SOIL COMPACTION AND GEOTECHNICAL DESIGN/CONSTRUCTION RECOMMENDATION REPORT TRACT - 24182 - 1 AND 2 Temecula, California For: Newland Associates @ Converse Consultants Prcl'~~: No 96-81-420-30 Fu;ul":' ,\10 2 \f.p ! I I I I Consolidation tests were performed on two (2) remolded samples of the representative subgrade soils. Results are presented in Figures No. B-7 and 8-8, Consolidation Test. These results indicate that the compression index of the subgrade soils tested is on the order of 0.06 to 0.10. This range of the compression index corresponds to low- to moderately compressible soils. I Two (2) representative samples of the subgrade soils from the building pad areas were tested to determine soil corrosivity with respect to common construction materials such as concrete and ferrous metal. These tests were performed by M. J. Schiff and Associates, Claremont, California. Test results are included in Appendix 8, Laboratory Testing. These results are similar to the soil corrosivity test results presented in a report prepared by M. J. Schiff and Associates, Claremont, California, for the nearby Tract 24186-1,-2, Tract 24184-1 and 24188-1. This is to be expected, as the subgrade soils for the subject tracts are comprised of imports from the tracts studied by M.J. Schiff and Associates. This report was included in the above-referenced As-Built Geology and Compaction Report, dated August 20, 1997. Conclusions and recommendation regarding soils corrosivity contained in the referenced M.J. Schiff report are applicable for the subject tracts. A copy of the report is also included in Appendix C, Soil Corrosivity Study, of this report. I I I I Representative samples of street subgrade soils were tested in accordance with the State of California Test Method 301-G to determine Resistance (R-value). Results of the R-value tests and recommendations regarding pavement structural sections will be presented in a separate report. I I I As stated in Section 9.0, Site Conditions After Grading, the thickness of engineered fill placed over the Pauba Valley portion of the subject tracts range from about seven (7) to 20 feet. The majority of these fills were placed during mass grading between October 1996 and June 1997. As discussed in the above-referenced Preliminary Geotechnical Investigation report dated April 26, 1996, this fill placement had surcharged the underlying compressible alluvium soil layers resulting in consolidation settlement. Fill soils also experience compression under self,-:weight. During mass grading, a number of settlement monuments were installed within the Pauba Valley portions of Tract 24182. Based on the results of the settlement monitoring, fill thickness, subsurface soil conditions and the time elapsed since the completion of mass grading, it is our opinion that the majority of static ground settlement due to fill placement during mass grading has occurred. I I I During current rough grading, engineered fills on the order of 25 feet were placed within the fill lots adjacent to the hill Tract 24182-1. These fill soils are underlain by dense older alluvium andlor Pauba Formation bedrock. Some compression settlement is likely to occur over this portipn of Tract 24182-1 due to the compression of the underlying older alluviumlbedrock and the compression of the fill under it's self-weight. The majority of the settlement should have occurred immediate after the completion of fill. placement. We recommended that three (3) to four (4) months time be allowed to elapse between the completion of fill placement and the start of building construction within the fill Lots No. 24, 25 and 42 and cut/fill transition Lots No. 17, 19-23, 26 through 28, and 32 through 42 of Tract 24182-1. I I I I 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 11 \"\ , I I I I I I Structures will also experience settlement due to compression of the foundation soil subjected to bearing stress from external dead and live loads. The magnitude of this component of building settlement depend on many factor including soil compressibility, embedment depth and dimensions of footing and the actual foundation pressure applied. As stated in Section 9.3, Seismic Hazards, the Pauba Valley portion of the tracts is prone to seismically-induced ground settlement on the order of 0.0 at the north side near the northern boundary of Tract 24182-2 to about 3.0 inches to the south side near Highway 79. The building foundation at the site are not susceptible to bearing failure during earthquakes since the liquefiable area is underlain by an engineered fill mat of at least 1 5 feet in thickness. This fill mat should act as a relatively rigid mat resulting in a more uniform settlement. I I I Due to relative deep groundwater and the compacted fill mat, disruption at the ground surface, if any, is expected to be minimal at the subject tracts. 11.0 CONCLUSIONS Based on our', field observation and fill density testing, it is our opinion that earthwork associated with the grading of the subject tracts for the purpose of residential development has been completed in accordance with the project plans and specifications. I I I I The subject tracts, from a geotechnical point of view, are suitable for the construction of the proposed residential structures provided the recommendations provided in this report are considered in the design and construction. 12.0 DESIGN AND CONSTRUCTION RECOMMENDATION This section contains our recommendations regarding design and construction of various facilities including building foundations, slabs-on-grade, retaining walls, pavements, driveways, walkways, curb and gutter. 12. 1 Building Foundation and Retaining Walls I I One- or -two-story buildings and retaining walls may be supported by continuous andlor isolated spread footings. Continuous footings should be at least 12 inches and 18 inches wide for one-story and two-story buildings, respectively. The recommended minimum width for an isolated spread footing for an individual column is 18 inches and 24 inches for one-story and two-story buildings, respectively. I I I I The expansion potential of the subgrade soils for various lots within the subject tracts range from very low to medium as define in Chapter 18 (Table No. 18-I-B) of the UBC (1994). For lot classifications for the subject tracts based on expansion potential, see Table No.1, Lot Classifications Based Expansion Index Test Results, of this report. The recommended minimum depth of footing embedment and reinforcement for various ranges of expansion potential of the subgrade soils are included in Table No.2, Suggested 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 12 \'b I I I I I I Guidelines For Design and Construction of Foundations and Slabs-on-Grade for One- and Two-story Residential Buildings. Footings should be designed based on an allowable bearing pressure of 1,500 psf. This bearing stress may be increased by one-third for short duration loading such as wind or seismic forces. Structural designs may require wider footings andlor more reinforcement than recommended in this report. I I I I Building clearance from ascending slopes, footing setback from descending slopes and foundation elevations should meet the requirements of Section 1806.4, Footings on or Adjacent to Slopes, of the UBC (1994). Active lateral earth pressures from soils at the site may be taken as equal to that developed by a fluid of density of 40 pounds per cubic foot (pcf). At-rest earth pressure may be taken as equal to that developed by a fluid of density of 65 pcf. I I Resistance to lateral loads can be assumed to be provided by friction acting at the base of foundations and by passive earth pressures against the sides of the foundations andlor walls. An ultimate value of the coefficient of friction of 0.30 between concrete and soil may be used with the dead load forces. An ultimate value of the passive earth pressure resistance of '250 psf per foot of depth may be used for the sides of footingslretaining walls. The maximum value of the passive pressure should be limited to 1,500 psf. The lateral resistances provided by the friction and the passive resistances may be combined directly without any reduction. These lateral resistances may be increased by one-third for short duration seismiclwind forces. For earthquake-resistant design of structures, the soil profile type at the site may be classified as "53" with a "s Factor" value of 1.5 in accordance with Table 16-J, Site Coefficients, of the UBC (1994). I Footings should be founded on firm and uniform compacted fills. Footing excavations should be observed and approved by the project geotechnical consultant- after the rebar is in place and prior to placing any concrete. I I I The total footing settlement from bearing load will depend, among other factors, on the subgrade soil type, depth and width of footing, thickness of compacted fills underneath the footings and changes in the moisture conditions of the subsurface soils. Anticipated total static settlements of footings, designed and constructed in accordance with the recommendations provided herein, should be less than one inch. The expected differential settlement between footings for individual residences may be taken as equal to half of the total settlement. I I I I 12.2 Slabs-On-Grade Based on the expansion index tests, the pad subgrades are classified as in Table 1, Lot Classification Based on Expansion Index Test Results. Recommendations regarding conventional slab-thickness, reinforcement and presoaking subgrade soils at the time of construction are provided in Table No.2, Suggested Guidelines For Design and 96-81-420-30 Converse Consultants \CCIENT\OFFICE\JOBFILE\ 1996\96-420.30 13 ,<\. I I I I I I I I I I I II I I I I I I I Construction of Foundations and Slabs-an-Grade for One- and Two-story Residential Buildings. TABLE NO.2 SUGGESTED GUIDELINES FOR DESIGN AND CONSTRUCTION OF FOUNDATIONS AND SLABS.ON. GRADE FOR ONE- AND TWO-STORY RESIDENTIAL BUILDINGS Foundation System Type I Type II Type III Type IV Type V Exoansion Potential Very low Low Medium Hioh Very Hiah Expansion Index IE.I) 0-20 21 - 50 51 - 90 91.130 Above 130 Footing Depth One Two One Two One Two One Two One Two Story Story Story Story Story Story Story Story Story Story Perimeter 12" 18" 12" 18" 18" 18" 18" .l!L 30" 30" Interior 12" 18" 12" 18" 12" 18" 18" 18" 18" 18" Footing 1- # 4 Bar 1 - # 4 Bar 1. # 4 Bar 2.4Bars 2- # 4 Bars Reinforcement Top and Bottom Top and Bottom Top and Bottom Top and Bottom Top and Bottom Garage Grade Beam 12" x 12" wi 12" x 12" wi 12" x 12" wi 12" x 12" wi 18" x 18" wi 1- # 4 Bar 1- # 4 Bar 1- # 4 Bar 1- # 4 Bar 1. # 4 Bar At Door Opening Top and Bottom Top and Bottom Top and Bottom Top and Bottom Top and Bottom Floor Slab Thickness 4" Nominal 4" Nominal 4" Nominal 4" Nominal 6" Nominal Floor Slab #4 at 18" o.c. Reinforcement 6" x 6"- #101#10 6"x6"-#1 0/#1 0 6"x6"-#1 0/#1 0 Dwellinas Not Mandatory Not Mandatory 6"x6"-#101#10 Each Wav 6"x6"-#1 01#1 0 6"x6"-#6/#6 Garages Subgrade Moisture 120 % of 120% of 120% of 120% of Optimum Optimum Optimum Optimum Optimum Requirement at Time or Higher Moisture to 12" Moisture to 12" Moisture to 18" Moisture to 18" of Construction Below Slab Below Slab Below Slab- Below Slab Structural designs may require slab thickness andlor reinforcement greater than recommended in herein. Slabs-on-grade should be underlain by 6-mil Visqueen (or equivalent) moisture barrier. To help break capillary rise of soils moisture, to aid concrete curing and to prevent puncture, we recommend that at least two (2) inches of clean sand be placed above and below the moisture barrier. Joints in the moisture barrier should be lapped a minimum of six (6) inches and properly sealed. Slab-on-grade subgrade soils must be firm and uniform. All loose or disturbed soils including under slab utility trench backfills should be recompacted prior to the placement of clean sand base underneath the moisture barrier. Joints for concrete slab-on-grade must be carefully designed. Joint spacing IS dependent upon slab thickness and concrete properties and should be selected by the structural engineer. Joints should be properly sealed. Unless local conditions and concrete properties indicate otherwise, the joint spacing (in feet) should not exceed approximately twice the slab thickness (in inches). Joint spacing may be increased if slabs are heavily reinforced. 96-81-420-30 Converse Consultants \CCIENT\OFFICE\JOBFILE\ 1996\96-420-30 14 1P I I I I I I During hot weather, the contractor should take appropriate curing precautions after placement of concrete to minimize cracking of the slabs. The potential for slab cracking may be lessened by the addition of fiber mesh to the concrete, andlor control of waterlcement ratio. Concrete should be cured by protecting it against loss of moisture and rapid temperature change for at least seven days after placement. Moist curing, waterproof paper, white polyethylene sheeting, white liquid membrane compound, or a combination thereof may be used after finishing operations have been completed. The edges of concrete slabs exposed after removal of forms should be immediately protected to provide continuous curing. Recommendations regarding garage grade beam at door opening for various expansion potential conditions are also included in Table No.2, Suggested Guidelines For Design and Construction of Foundations and Slabs-on-Grade for One- and Two-story Residential Buildings. I In lieu of the recommendations presented on Table No.2, building foundations on lots with EI > 20 may be constructed with post-tensioned slab as recommended in Chapter 18 of the UBC (1994). Recommendations for post-tensioned slab design, based on Section 1816 of the UBC, are provided below: I I . Edge Moisture Variation (Em, Center Lift): 6.0 feet . Edge Moisture Variation Distance (Em, Edge Lift) : 3.0 feet . Estimated Differential Swell (Ym, Center Lift): 0.90 to 1.4 inches . Estimated Differential Swell (Ym, Edge Lift): 0.20 to 0.34 inches I I I I I I I We recommend that the subgrade soils for lots with post-tensioned slab, if used , be soaked as recommended in Table No.2. 12.3 Foundation Settlement Total static settlement of foundations at site will comprise of the followings: . Compression of the foundation soils due to bearing pressure . Compression of fill soils due to self weight and . Compression of the underlying native soils due to fill weight The total settlement due to compression of foundation soils under bearing load only should be less than 1.0 inch. The differential settlement may be taken as half of the total settlement. A discussion of the other two components of the static total settlement is presented in Section 10.0 of this report. As discussed in Section 9.3, Seismic Hazards, the portion of the site within the Pauba Valley is prone to seismically induced total settlement on the order of 3.0 inches. The anticipated seismically induced differential settlement over the footprint 'of the structures may be taken as half of the total settlement. Due to this range of differential settlement, based on published information as shown in Table No.3, Severity of Cracking Damages, residential buildings supported on conventional footing and slab-on-grade as recommended in Section 9.1 and 9.2, may experience negligible to slight damages. I I I 96-81-420-30 Converse Consultants \CCIENT\OFFICE\JOBFILE\ 1996\96-420-30 15 ~ I I I I I I I I I I I I I I I I I I I Table No.3, Severity of Cracking Damage (After Day, 1998) Damage Category Description of Typical Damage Approximate Crack Width a S/L (11 (2) (3) (4) (5) Negligible Hairline cracks <O.lmm <3cm (1.2 in.) < 1/300 Includes fine cracks that can be easily treated during normal Very Slight decoration, perhaps isolated slight 1mm 3-4 em (1.2-1.5 in) 1/300-1/240 fracture in building, and cracks in external brickwork visible on close inspection Includes cracks that can be easily filled and redecoration would probably be required, several slight Slight fractures may appear showing on the 3mm 4-5cm (1.5-2.0 in) 1/240-11175 inside of the building, cracks that afe visible externally and some repainting may be required, and doors and windows may stick Includes cracks that require some opening up and can be patched by a mason, re.current cracks that can be .masked by suitable linings; repainting 5-15mm or a number of Moderate of external brickwork and a small 5-8cm 12.0-3.0 in) 1/175-1/120 cracks> 3mm amount of brickwork replacement may be required, doors and windows stick, service pipes may fracture, weather tightness is often impaired Includes large cracks requiring extensive repair work involving breaking-out and replacing sections of walls (especially over doors and 15-25mm, but also depends Severe windows) distorted windows and 8-13cm 13.0-5.0 in) 1/120-1/70 on number of cracks door frames, noticeably sloping floors, leaning or bulging walls, some Joss of bearing in beams, and disrupted service pipes Often requires a major repair job involving partial or complete Very Severe rebuilding, beams lose bearing, walls Usually> 25mm but also. > 13cm (> 5 in) >1/70 lean and require shoring, windows depends on number of cracks are broken with distortion, and there is a danger of structural instability To further reduce the potential of damage due to differential settlement, the structures may be strengthened andlor supported on post-tensioned foundation systems. The recommended differential settlement for the design of buildings at various lots are presented in Table No.4, Recommended Differential Settlement. 96-81-420-30 Converse Consultants \CCIENT\OFFICEIJOBFILE\ 1996\96-420-30 16 -JJ-- I I I I I Table No.4, Recommended Differential Settlement Tract No. Lots No. Estimated Differential Settlement 1-16,18,24-25,29-31 and 41-95 0.5 24182-1 17, 19-23, 26-28 and 32-41 (cut/fill transition lots) 1.0 24182-2 1-4,22-34,41-50 and 57-61 1.0 5-21, 35-40 and 51-56 1.5 12.4 Concrete Walks, Driveways, Access Ramps, Curb and Gutter I Except as modified in this report, concrete walks, driveways, curb and gutters may be constructed in accordance with Section 303-5, Concrete Curbs, Walks, Gutters, Cross- Gutters, Alley Intersections, Access Ramps, and Driveways, of the Standard Specifications for Public Works (SSPWC, 1994). I I I I I I I I I I I I I Prior to pouring concrete, at least the upper 12 inches of the subgrade soils under these structures should be scarified, moisture conditioned to slightly above optimum and compacted to at least 90 percent relative compaction. The subgrade soils under the driveways of various lots should be pre-soaked prior to pouring concrete in accordance with the recommendations provided for concrete slab-on- grade in Section 12.2, Slab-on-Grade. The thickness of driveways for passenger cars should be at least four (4) inches. Transverse control joints for driveways should be spaced not more than 10 feet apart. Driveways wider than 12 feet should be provided with a longitudinal control joints. Concrete walks subjected to pedestrian and bicycle loading should be at least four (4) inches thick. Transverse joints should be spaced 15 feet or less and should be cut to a depth of Y. the slab thickness. The composition of subgrade soils along the concrete walkways is likely to vary significantly from sand to sandy clay. Subgrades containing clayey soils should be presoaked to 1 20 percent of the optimum to a depth of at least 12 inches prior to pouring concrete. In areas where the subgrade soils are mainly clayey, the concrete driveway andlor walkway slabs should be underlain by about two (2) inches of moist clean sand and/or aggregate base to aid in concrete curing and to facilitate subsurface drainage. Positive drainage should be provided away from all driveways and sidewalks to prevent seepage of surface andlor subsurface water into the concrete base andlor subgrade. 12.5 Corrosion Protection Based on the corrosion study report presented in Appendix C, Soil Corrosivity Study and additional soil corrosivity tests presented in Appendix B, Laboratory Testing, subgrade soils within the subject tracts are not significantly deleterious to concrete. Type I or II Portland Cement may be used in concrete construction. Standard concrete covers, that is, 2.0 inch 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 17 ~~ II I if placed against form and 3.0 inches if placed directly against earth, may be used to protect reinforcing rebar. I I I Site soils are classified as severely corrosive to ferrous metal. For corrosion protection recommendations of steel, iron pipes, copper tubes, plastic and vitrified clay and other types of pipes, see the attached soil corrosivity study report in Appendix C, Soil Corrosivity Study. If additional corrosion recommendations are desired, we recommend that a qualified corrosion specialist be contacted. 12.6 Site Drainage, Slope Protection and Landscape Irrigation Recommendations I Adequate positive drainage away from structures should be provided to prevent ponding and to reduce percolation of water into subgrade andlor other structural fills. Building pad drainage should satisfy the requirements of Section 3315, Drainage and Terracing, of the Appendix Chapter 33 of UBC (1994). Planters and landscaped areas adjacent to the building perimeter should be designed to minimize water infiltration into the subgrade soils. Gutters and downspouts should be installed on the roofs, and runoff should be directed to storm drains through non-erosive devices. I I I I I I Slopes should'. be provided with adequate erosion control measures as soon as possible. Erosion control may include planting the slopes with appropriate drought-resistant vegetation as recommended by a landscape architect. Landscaping should disturb the slope soils as little as possible. Care should be exercised to prevent loose fills from being placed on slopes during landscaping. Slopes should not be over-irrigated, as this can soften the near surface soil resulting in surficial slope failures. The V-ditch should be maintained at all times to prevent overflow of surface water during storms. Rodents burrowing, small concentrations of uncontrolled water, or localized depression of utility trench backfill on slopes should be controlled andlor repaired as soon as possible. I I I I I I I Most hillside residential lot problems are associated with water. Homeowners should be aware that altering drainage patterns, landscaping and the addition of patios, planters and other improvements, broken pipe, as well as irrigation and variations in seasonal rainfall all affects moisture conditions of the subgrade soils. Excessive landscape irrigation may significantly increase the subgrade soil moisture conditions resulting in localized ponding and saturation of the subsurface soils. Percolating groundwater water may even flow from upper- grade lot areas to adjacent lower-grade lot areas. Excessive soil moisture affects performance of buildings, slopes, pavements and other structures as well as landscaping. Local drainage collection and transporting devices such as subdrains may be required if waterlogging conditions develop in the future. Modifications to the graded pad areas should not be attempted without the approval of a qualified soils engineer andlor geologist. Additional site drainage recommendations are provided in the above-referenced As-BUilt Geology and Soil Compaction Report of Rough Grading report dated, August 20, 1997. 96-81-420-30 Converse Consultants \CCIENT\OFFICEIJOBFILE\ 1996\96-420-30 18 7A. I I I I I I 13.0 ON-SITE TRENCH BACKFILL COMPACTION 13. 1 General Except as modified herein, the trenches for underground utilities, including water, sewer and gas pipelines; and conduits for electrical, fiber optics etc., should be backfilled in accordance with the recommendations contained in Section 306 of the Standard Specifications for Public Works (SSPWC, 1994). The pipes should be bedded as recommended by the pipe designer. The gradation of the bedding material, if used, should be selected to prevent migration of fines from the surrounding native soils. Bedding materials should be tested and approved by the project soils consultant prior to importing them to the site. I I I I The excavated soils should be suitable for use as trench backfill. These materials may need to be processed and may require mixing and moisture conditioning prior to compaction. Bedding material, if used, should be vibrated in-place, and care should be taken to densify the bedding material below the springline of the pipe. Flooding or jetting of the bedding material should not be attempted because the water from the trench is not expected to drain freely. Long-term accumulation of water in the pipe trench from any sources should be avoided, and trenches should be pumped dry if water collects inside. 13.2 Recommended Specifications for Placement of Trench Backfill I I I I I I I I I Trench backfill shall be compacted to a minimum relative compaction of 90 percent as per ASTM Standard 01557-91. At least the upper 12 inches of trench underlying pavements should be compacted to at least 95 percent relative compaction as per ASTM Standard 01557-91 . Additional trench backfill placement and compaction recommendations are provided below: . Bedding material for the pipe should be selected by the pipe design engineer. Bedding material should have a Sand Equivalent (SE) greater than or equal to 30, as determined by the California Test Method 217. . Trench backfill shall be compacted by mechanical methods, such as sheepsfoot, vibrating or pneumatic rollers, or mechanical tampers, to achieve the density specified herein. The backfill materials shall be brought to two (2) to three (3) percent within optimum moisture content, then placed in horizontal layers. The thickness of uncompacted layers should not exceed eight inches. Each layer shall be evenly spread, moistened or dried as necessary, and then tamped or rolled until the specified density has been achikved. . The contractor shall select the equipment and processes to be used to achieve the specified density without damage to adjacent ground and completed work. 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 19 p I I I I I I I I I I I I I I I I I I I I · The field density of the compacted soil shall be measured by the ASTM Standard 01556-90 (Sand Cone) or ASTM Standard 02922-91 (Nuclear Method) test method or equivalent. . Observation and field tests should be performed by the project soils consultant during construction to confirm that the required degree of compaction has been obtained. Where compaction is less than that specified, additional compactive efforts shall be made with adjustment of the moisture content as necessary until the specified compaction is obtained. . It should be the responsibility of the contractor to maintain safe conditions during excavation, backfilling and compaction operations. . Trench backfill shall not be placed, spread or rolled during unfavorable weather conditions. When the work is interrupted by heavy rain, fill operations shall not be resumed until field tests by the project's geotechnical consultant indicate that the moisture content and density of the fill are as previously specified. 14.0 CLOSURE The findings a'nd recommendations of this report are provided in accordance with generally accepted professional engineering and engineering geologic principles and practice in effect at this time in Southern California. Our conclusions and recommendations are based on field observation, field and laboratory testing performed in accordance with applicable industry standards, data analysis/interpretation and our experience. We. make no other warranty, either express or implied. Although the grading for lots was considered suitable at the time of completion, natural weathering and degradation of the near-surface soils may occur with time. It has been our experience that significant deterioration of surficial soils, in particular, growth of vegetation and erosion, may occur if a significant period of time elapses before construction. We recommend that the conditions of impacted lots, if any, be reevaluated by a qualified geotechnical engineer prior to construction. This report has been prepared for the sole benefit and exclusive use of the Newland Associates and no one else may utilize or rely on this report, or any portion thereof, in connection with any pending or contemplated transaction or for any other purpose without the express written consent of Converse. In the event that there is any legal action or proceeding arising out of or related to this report or any part thereof, between Converse and anyone who may utilize this report, with or without Converse's consent, the prevailing part shall be entitled to recover all of its expenses, including all reasonable attorneys fees and costs, incurred in connection with any such action or proceeding. 96-81-420-30 Converse Consultants \CCIENT\OFFICE\JOBFILE\ 1996\96-420-30 20 ~ I I I I I I I I I I I i I I I I I I I I REFERENCES ANNUAL BOOK OF ASTM STANDARDS (1995), Vol. 04.08, Soil and Rock; Dimension Stone; Geosynthetics. BOWLES, J. E., 1982, Foundation Analysis and Design, McGraw-Hili, Inc. CARTER, M. and BENTLEY, S. P. (1991), Correlations of Soil Properties, Pentech Press, London. CONVERSE CONSULTANTS INLAND EMPIRE (1996), Preliminary Geotechnical Investigation, Eastern and Southern Portion of "The Meadows", Approximately 800- Acre Site, City of Temecula, California, dated April 26, 1996, prepared for Newland Associates, Converse Project No. 96-81-420-01. CONVERSE CONSULTANTS INLAND EMPIRE (1997), As-Built Geology and Compaction Report of Rough Grading, Tract 24182 through 24186 and 24188-1, Paseo Del Sol Master Planned Community, Temecula, California, dated August 20,1997, prepared for Newland Associates, Converse Project No. 96-81-420-01. CONVERSE C.ONSUL TANTS INLAND EMPIRE (1988), Liquefaction Investigation , The Meadows at Rancho California, APN Nos. 926-13-9, -10, -12, -13, and -14, Rancho California", Dated December 9, prepared for Rancho California Development Company, Converse Project No. 88-81-148-02. DAY, R. W. (1998), Discussion on "Ground-Movement-Related Building Damage', Journal of Geotechnical and Geoenvironmental Engineering, ASCE, Vol. 124, No.5, pp. 462-463. INTERNA TIONAL CONFERENCE OF BUILDING OFFICIALS (1994), Uniform Building Code (UBC). KENNEDY, M. P. (1997), "Recency and Character of Faulting Along the Elsinore Fault Zone in Southern Riverside County, California", CDMG Special Report 131. LAMBE, T. W., and WHITMAN, R. V., 1979, Soil Mechanics, John Wiley & Sons. SEED, . S., TOKIMATSU, K., HARDER. L.F., and CHUNG, R. M. (1985), Influence of SPT Procedures in Soil liquefaction Resistance Evaluation. Journal of Geotechnical Engineering, ASCE, Vol. 111, No.1 2. pp. 1425-1445. STANDARD SPECIFICATIONS FOR PUBLIC WORKS CONSTRUCTION (1994), Building News, Inc., Los Angeles, California. TOKIMATSU, K. and SEED, H. B. (1987), Evaluation of Settlement in Sands Due to Earthquake Shaking, Journal of Geotechnical Engineering, ASCE, Vol. 113, No.8, pp. 861-878. UNIFORM BUILDING CODE (UBC), 1994, International Conference of Building Officials. 96-81-420-30 Converse Consultants ICCIENTIOFFICEIJOBFILEI1996196-420-30 21 z-1. I I I I I I I I I I I I I I I I I I I UNIFORM BUILDING CODE (UBC), 1997, International Conference of Building Officials. YOUD. T. L. and GARRIS, C. T. (1995), Liquefaction-Induced Ground Surface Disruption, Journal of Geotechnical Engineering, ASCE, Vol 121, No. 11, pp. 805-809. 96-81-420-30 Converse Consultants \CCIENT\OFFICEIJOBFILE\ 1996\96-420-30 22 1!i> I I !I I I I I I I I I I I I I I I I , I I I APPENDIX A FIELD DENSITY TESTING q.,. 0., I I I I I I I I I I I I I I I I I I I TABLE NO.1 SUMMARY OF FIELD DENSITY TE,ST RESUl.TS APPROX APPROX DRY %REl TEST TEST TEST LOCATION TEST FILL DENS. % SOIL REMARKS NO. DATE ELEV. DEPTH MOIST TYPE CQMP 90%RC Req'd 1ft) Iftl (pef) IRC) Tract 24182-' 1 OS/27/98 Pad #37 1125.0 0.0 117.9 9.2 1 94 2 OS/27/98 Pad #39 1130.0 0.0 115.3 9.5 1 92 3 OS/27/98 Pad #44 1127.0 0.0 117.4 9.0 1 93 4 OS/28/98 Pad #41 1130.0 0.0 116.4 9.1 1 92 5 OS/28/98 Pad #45 1125.0 2.0 113.9 9.0 1 90 6 OS/28/98 Pad #66 1105.0 0.0 115.6 8.8 1 92 7 OS/28/98 Pad #74 1105.5 5.0 114.7 9.0 1 91 8 OS/28/98 Pad #65 1105.0 3.0 113.6 9.5 1 90 9 OS/29/98 lot #65, W. Central Area 1106.0 2.0 117.2 10.6 2 93 10 OS/29/98 Lot #67, W. Central Area 1107.0 2.0 117.5 11.0 2 94 11 OS/29/98 Lot #69, W. Central Area 1110.0 2.0 118.1 11.5 2 94 12 OS/29/98 Lot #71, W. Central Area 1110.0 2.0 119.0 12.5 2 95 13 OS/29/98 Lot #73, W. Central Area 1108.0 2.0 117.6 13.5 2 94 14 OS/29/98 Lot #66, Slope Area 1107.0 2.0 120.6 11.3 2 96 15 OS/29/98 Lot #70, Slope Area 1110.0 2.0 117.9 12.0 2 94 16 OS/29/98 Lot #74, Slope Area 1109.0 2.0 117.4 11.5 2 91 17 OS/29/98 Lot #65, Slope Area 1108.0 4.0 126.3 10.3 4 96 18 OS/29/98 Lot #69, Slope Area 1112.0 4.0 117.7 13.0 2 94 19 OS/29/98 Lot #73, Slope Area 1110.0 4.0 117.2 12.4 2 93 20 OS/29/98 Lot #66, Central Area 1110.0 4.0 118.8 12.0 2 95 21 OS/29/98 Lot #68, Central Area 1109.0 4.0 118.0 12.5 2 94 22 OS/29/98 Lot #72, Central Area 1113.0 4.0 117.5 12.2 2 94 23 OS/29/98 Lot #69, West Area 1113.0 5.0 119.9 12.8 4 91 24 OS/29/98 Lot #71, West Area 1113.0 5.0 117.5 12.5 2 94 25 06/01/98 lot #20, Central Area 1099.0 0.0 119.9 12.0 4 91 Tract 24182-2 26 06/01/98 lot #23, Central Area 1100.0 0.0 119.0 11.5 2 95 27 06/01198 lot #26, Central Area 1100.0 0.0 119.2 11.1 2 95 96-81-420-30 Converse Consultants ICCI ENTlOFFI CE\JOBFILE\ 1996\96-81 \96-420-30. FDT ~ I I I I I I I I I I I I I I I I I I I TABLE NO.1 - SUMMARY OF FIELD DENSITY TEST RESU1.TS APPROX APPROX DRY % REL TEST TEST TEST LOCATION TEST FILL DENS. % SOIL COMP REMARKS NO. OATE ELEV. DEPTH (pet} MOIST TYPE {RC} 90%RC Req'd (ft} (ft} Tract 24182-2 28 06/01/98 Lot #19, Central Area 1100.0 1.0 120.3 10.6 2 96 29 06/01/98 lot #27. Central Area 1102.0 1.0 121.1 11.9 4 92 30 06/01 /98 lot #21, Central Area 1102.0 2.0 119.5 11.4 4 91 31 06/01/98 lot #24, Central Area 1102.0 2.0 123.5 11.5 4 94 32 06/01/98 Lot #27, Central Area 1103.0 2.0 122.8 11.3 4 93 33 06/01/98 lot #22, Central Area 1102.0 3.0 123.3 8.9 2 99 Tract 24182-1 34 06/01/98 Lot #68, Slope Area 1114.0 6.0 99.0 11.6 3 88 Fail. see Retest IRTI # 34A 35 06/01/98 lot #70, Slope Area 1114.0 6.0 106.7 13.3 3 95 36 06/01/98 Lot #74, Slope Area 1111.0 4.0 109.6 15.5 3 98 37 06/01/98 lot #72, Slope Area 1115.0 6.0 106.6 16.7 3 95 38 06/01/98 Lot #66, Slope Area 1111.0 6.0 107.2 15.0 3 96 39 06/01/98 lot #69, Slope Area 1117.0 8.0 109.9 15.6 1 89 Fail, see RT #39A 40 06/01/98 lot #67, Slope Area 1113.0 8.0 103.0 16.6 3 92 34A 06/01/98 Lot #68, Slope Area 1114.0 6.0 103.1 16.1 3 92 RT of #34 39A 06/01/98 Lot #S9, Slope Area 1118.0 8.0 114.4 10.2 1 92 RT of #39 Tract 24182-2 41 06/02/98 Lot #20. Central Area 1101.0 2.0 116.6 8.7 2 93 42 06/02/98 Lot #23, Central Area 1102.0 2.0 117.1 9.3 2 93 43 06/02/98 Lot #24, Central Area 1102.0 2.0 117.3 9.9 2 94 44 06/02/98 lot #26, Central Area 1103.0 2.0 116.9 10.6 2 93 45 06/02/98 Lot #38 , Central Area 1101.5 1.5 118.4 9.5 2 94 46 06/02/98 Lot #48, Central Area 1102.0 1.5 115.9 10.1 2 92 47 06/02/98 Lot #42, Central Area 1103.5 1.5 117.5 11.0 2 94 48 06/02/98 Lot #44, Central Area 1105.0 1.5 117.4 10.4 2 94 49 06/02/98 Lot #19, Central Area 1101.0 2.0 115.9 10.4 2 92 50 06/02/98 Lot #21, Central Area 1101.5 2.0 115.5 8.9 2 92 51 06/02/98 Lot #25, Central Area 1103.0 2.0 117.2 10.8 2 93 52 06/02/98 Lot #27, Central Area 1103.0 2.0 115.6 10.1 2 92 96-81-420-30 Converse Consultants ICCI ENT\O FFI CE\JOBFI LE\ 1996\96-81 \96-420-30. FDT 2 ,,?'- I I I I I I I I I I I I I I I I I I I TAELE NO.1 SUMMARY OF FIELD OENSITY TEST RESUl.TS APPROX APPROX DRY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90% RC Req'd (It I Iftl (pet) (Rei Tract 24182-2 53 06/02/98 lot #39, Central Area 1101.5 1.5 116.4 11.0 2 93 54 06/02/98 Lot #41, Central Area 1103.0 1.5 118.9 lOA 2 95 SS 06/02/98 Lot #43, Central Area 1104.5 1.5 118.2 10.5 2 94 56 06/02/98 Lot #45, Central Area 1106.0 1.5 116.0 8.8 2 92 Tract 24182-1 S7 06/02/98 Lot #55, Central Area 1109.0 0.0 117.8 8.8 4 90 58 06/02/98 Lot #58, Central Area 1112.0 0.0 118.8 10.7 4 90 59 06/02/98 Lot /154, Central Area 1109.0 1.5 119.8 9.9 4 91 60 06/02/98 Lot #55 1111.0 2.0 123.3 11.3 4 94 Sandcone (SC) 61 06/02/98 lot #56. South West Area 1113.0 3.0 121.3 11.0 4 92 SC 62 06/02/98 lot #57, South Area 1117.0 3.0 121.9 10.6 4 93 SC 63 06/02/98 Lot #58 1115.0 3.0 118.1 10.1 4 90 SC 64 06/02198 Lot #59 1112.0 3.0 119.2 10.5 4 91 SC 65 06/03/98 Lot #49, Central Area 1101.5 0.0 120.8 10.9 4 92 66 06/03/98 Lot #65, North West Area 1111.0 7.0 118.7 12.3 4 90 67 06/03/98 Lot #67, South West Area 1115.0 10.0 115.1 12.0 4 88 Fail, see RT #67A 67A 06/03/98 Lot #67, South West Area 1115.0 10.0 119.1 11.8 4 91 AT of #67 68 06/03/98 Lot #68, West Area 1116.0 10.0 114.8 10.0 2 91 69 06/03/98 Lot #70, Central Area 1118.0 10.0 115.5 10.2 2 92 70 06/03/98 Lot #72, South West Area 1117.0 8.0 121.0 11.3 4 92 SC 71 06/03/98 Lot #74, North West Area 1113.0 6.0 122.9 10.5 4 93 72 06/03/98 Lot #89, Central Area 1107.0 0.0 121.1 10.1 4 92 73 06/03/98 lot #87, Central Area 1106.0 0.0 114.5 11.0 2 91 74 06/03/98 lot #85, Central Area 1105.0 0.0 116.3 10.7 2 93 75 06/03/98 lot #76, Central Area 1106.0 0.0 122.0 11.3 4 93 76 06/03/98 lot #78, Central Area 1105.0 0.0 120.5 10.5 4 92 77 06/03/98 Lot #56, North Area 1114.0 2.0 120.8 10.9 4 92 SC 78 06/03/98 Lot #78, South East Area 1118.0 5.0 121.4 11.0 4 92 SC 79 06f03f98 Lot #59, South West Area 1114.0 3.0 119.0 11.1 2 95 96-81-420-30 Converse Consultants ICCIENT\OFFICE\JOBFI LE\ 1996\96-81 \96-420-30. FDT 3 ~;z", II , I I I I I I I I I I I I I I I I I I I TABLE NO.1 SUMMA RY OF FIELD DENSITY TE:ST RESUL.TS APPRoX APPRoX DRY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd lit! IItl (pefl IRe) Tract 24182-2 80 06/04/98 Lot #30, Central Area 1101.0 0.0 117.9 11.5 5 90 81 06/04/98 Lot #35, Central Area 1100.0 0.0 117.3 11.7 5 90 82 06/04/98 Lot #28. Central Area 11 03.0 1.5 118.3 11.1 5 91 83 06/04/98 Lot #29, Central Area 1102.0 1.5 117.7 12.0 5 90 84 06/04/98 Lot #31, Central Area 1102.0 1.5 118.0 11.0 5 90 85 06/04/98 Lot #32, Central Area 11 02.0 1.5 117.8 10.4 5 90 86 06/04/96 Lot #33, Central Area 1101.0 1.5 118.4 11.3 5 91 87 06/04/98 Lot #34, Central Area 1101.0 1.5 118.5 11.0 5 91 88 06/04/98 Lot #36, Central Area 1101.0 1.5 119.4 10.9 5 91 89 06/04/98 lot #37, Central Area 1100.0 1.5 120.2 10.6 5 92 Tract 24182-1 90 06/04/98 Lot #9, Central Area 1118.0 0.0 116.4 11.3 2 93 91 06/04/98 lot #11, Central Area 1125.0 0.0 117.7 11.5 5 90 92 06/04/98 lot #13, Central Area 1131.0 0.0 118.8 10.7 5 91 93 06/04/98 Lot 1110, Central Area 1123.0 2.0 116.9 11.1 5 90 94 06/04/98 Lot #15. Central Area 1135.0 2.0 118.0 11.4 5 90 95 06/03/98 Lot #38, Central Area 1132.0 3.0 119.1 11.0 5 91 96 06/04/98 lot #40 Central Area 1134.0 2.0 118.5 10.8 5 91 97 06/04/98 lot #61, Central Area 1108.0 0.0 117.9 11.3 5 90 Tract 24182-2 98 06/04/98 Lot #47, Central Area 1104.0 0.0 117.7 10.9 5 90 99 06/04/98 Lot #50, Central Area 1102.0 0.0 117.8 10.6 5 90 100 06/04/98 Lot #53, Central Area 1099.0 0.0 118.6 11.4 5 91 SC 101 06/05/98 Lot #37 Central Area 1129.0 4.0 117.8 8.9 5 90 Tract 24182-1 102 06/05/98 Lot #40, Central Area 1136.0 4.0 112.1 6.9 5 86 Fail. see RT t/1Q2A 102A 06/05/98 Lot #40. Central Area 1136.0 4.0 116.8 7.1 5 90 RT of #102 103 06/05/98 Lot #43, Central Area 1131.0 3.0 118.3 8.8 5 91 96-81-420-30 Converse Consultants ICCI ENT\OFF ICEIJOBFI LEI 1996196-81 196-420-30. FDT 4 <?'? I I I I I I I I I I I I I I I I I I I TAE,LE NO.1 SUMMA RY OF FIELD DENSITY TI:ST RESUL.TS - APPROX APPROX DRY % REL TEST TEST TEST LOCATION TEST FILL DENS. % SOIL COMP REMARKS NO. DATE ELEV. DEPTH (pct) MOIST TYPE (RC) 90%RC Req'd 1ft) lit) Tract 24182-1 104 06/05/98 Lot #13, Central Area 1129.0 1.5 118.4 10.4 5 91 105 06/05/98 lot #14, Central Area 1134.5 1.5 117.1 8.3 5 90 106 06/05/98 Lot 1147, Central Area 1120.0 2.0 119.5 8.1 5 92 107 06/05/98 lot #48, Central Area 1119.0 2.0 117.0 9.0 5 90 108 06/08/98 Opposite lot #29 Slope Area 1120.0 3.0 122.4 10.9 5 94 109 06/08/98 Opposite lot #30 Slope Area 1123.0 6.0 121.8 11.2 5 93 110 06/08/98 Opposite Lot #27 Slope Area 1124.0 8.0 122.2 11.5 5 94 111 06/08/98 Opposite Lot #29 Slope Area 1130.0 12.0 122.9 11.0 5 94 112 06/08/98 .Opposite lot #28 Slope Area 1127.0 10.0 121.6 11.4 5 93 113 06/08/98 Opposite Lot #31 Slope Area 1125.0 9.0 105.9 19.0 3 95 114 06/08/98 Opposite Lot #26 Slope Area 1123.0 9.0 108.4 18.4 3 97 115 06/08/98 Opposite Lot #31 Slope Area 1127.0 11.0 113.0 13.0 1 91 116 06/08/98 Opposite lot #34 Slope Area 1133.0 13.0 113.5 12.6 1 92 117 06/08/98 Opposite lot 1128 Slope Area 1131.0 15.0 112.0 12.9 1 90 118 06/08/98 lot #60, Central Area 1111.0 2.0 114.9 7.9 2 92 119 06/08/98 Lot #62, Central Area 1108.0 1.5 114.4 7.9 2 91 Tract 24182-2 120 06/08/98 lot #46, Central Area 1106.0 1.5 115.3 6.8 2 92 121 06/08/98 Lot #48, Central Area 1104.5 1.5 116.8 6.5 5 90 122 06/08/98 Lot #49, Centfal Area 1104.0 1.5 117.2 6.0 5 90 123 06/08/98 Lot #51, Central Area 1102.0 1.5 120.9 6.2 5 93 124 06/09/98 Opposite Lot #26, Slope Area 1131.0 17.0 110.7 14.5 6 92 , 125 06/09/98 Opposite Lot #34, Slope Area 1137.0 17.0 112.1 15.0 6 93 126 06/09/98 Opposite Lot #28, Slope Area 1136.0 19.0 114.7 12.9 6 96 127 06/09/98 Opposite Lot #29, Slope Area 1139.0 21.0 111.1 15.5 6 93 128 06/09/98 Opposite Lot #27, Slope Area 1137.0 21.0 107.7 14.0 6 90 129 06/09/98 Opposite Lot #30, Slope Area 1135.0 18.0 108.8 12.0 6 91 130 06/09/98 Opposite Lot #29, Slope Area 1141.0 23.0 111.0 11.0 1 90 96-81-420-30 Converse Consultants ICCI ENT\OFFI CEIJOBFI LEI 1996196-81 196-420-30. FDT 5 11'-- I I I I I I I I I I I I I I I I I I I TABLE NO.1 SUMMARY OF FIELD DENSITY T1'ST RESUl.TS APPROX APPROX DRY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd (It) Iftl (pcfl IRC) Tract. 24182-1 131 06/09/98 Opposite lot #27, Slope Area 1138.0 20.0 116.2 11.3 1 94 132 06/10/98 Opposite Lot #28, Slope Area 1141.0 24.0 112.8 11.0 1 91 133 06/1 0/98 Opposite lot #31, Slope Area 1143.0 25.0 111.0 109 1 90 134 06/10/98 Lot #84, Central Area 1105.0 1.5 112.4 6.7 2 90 135 06/10/98 lot #86, Central Area 1106.0 1.5 113.0 6.8 2 90 136 06/10/98 l?t #88, Central Area 1107.0 1.5 106.3 7.5 2 85 Fail, see RT #136A 136A 06/10/98 lot #88, Central Area 1107.0 1.5 t 12.9 7.0 2 90 Set RT of #136 137 06/1 0/98 Lot #90, Central Area 1107.0 1.5 114.4 6.9 2 91 138 06/1 0/98 Lot #53, Central Area 1107.0 2.0 115.4 8.9 2 92 139 06/10/98 Lot #75, Central Area 1107.0 2.0 123.3 8.4 2 95 140 06/1 0/98 lot #77, Central Area 1107.0 2.0 115.0 7.0 2 92 141 06/1 0/98 Lot #79, Central Area 1106.0 2.0 122.9 7.9 5 94 Tract, 24182-1 142 06/11/98 Lot 1/23, Central Area 1117.0 0.0 116.8 6.3 5 90 143 06/11/98 Lot #25, Central Area 1112.0 0.0 113.9 6.9 2 91 144 06/11/98 lot #24, Central Area 1112.5 2.0 114.5 10.0 2 91 145 06/11/98 lot #26, Central Area 1115.0 2.0 117.0 8.2 5 90 146 06/11/98 Lot #23, West Area 1120.0 3.0 122.7 11.3 5 94 147 06/11/98 Lot #25, South Central Area 1115.0 3.0 116.1 9.9 2 93 148 06/11/98 Lot #24, Central Area 1114.5 4.0 115.3 10.5 2 92 149 06/11/98 Lot #26, Central Area 1117.0 4.0 118.7 12.0 5 91 150 06/11/98 Lot #27, Central Area 1114.0 0.0 112.4 7.3 1 90 151 06/11/98 Lot #29, Central Area 1116.0 0.0 113.1 7.1 1 91 152 06/11/98 Lot #31, Central Area 1116.0 0.0 115.5 7.0 1 93 153 06/11/98 Lot #33, Central Area 1117.0 0.0 114.0 7.0 1 92 154 06/11/98 Lot 1135, Central Area 1120.0 0.0 113.3 11.0 1 91 96-81-420-30 Converse Consultants ICCI ENTiO FFICEIJOBFI LE\ 1996\96-81 \96-420-30.FDT 6 "fi I I I I I I I I I I I I I I I I I I I TAe-LE NO.1 SUMMARY OF FIELD OENSITY Tl'ST RESUl.TS APPROX APPROX DRY % REl TEST TEST TEST FILL % SOIL REMARKS NO. OATE TEST LOCATION ELEV. OEPTH DENS. MOIST TYPE COMP 90%RC Req'd lftl lftl (pef) {RCI Tract, 24182-2 Finish Cut into 155 06/12198 Lot #2, Central Area Grade mass 120.7 8.9 5 92 (FGI grading fill Cut into 156 06/12198 Lot #4, Central Area FG mass 122.1 7.3 5 94 grading fill Cut into 157 06/12/98 lot #6, Central Area FG mass 118.2 6.5 5 91 nradinn fill Cut into 158 06/12/98 Lot #8, Central Area FG mass 120.8 6.0 4 92 nradinn fill Cut into 159 06/12198 Lot #10, Central Area FG mass 124.4 7.3 4 95 nradinnfill Cut into 16D 06/12198 Lot #12, Central Area FG mass 121.1 7.0 4 92 nradinn fill Cut into 161 06/12/98 lot 1/ 14, Central Area FG mass 122.3 6.6 4 93 orad inn fill Cut into 162 06/12198 Lot.1I16, Central Area FG mass 121.5 6.0 4 92 nradinnfill Cut into 163 06/12/98 Lot #18. Central Area FG mass 121.3 6.3 4 92 "radin'" fill 164 06/12198 lot #20, Central Area FG 4.0 128.8 9.1 4 98 165 06/12/98 lot #22, Central Area FG 4.0 120.9 9.9 4 92 166 06/12/98 lot #24, Central Area FG 4.0 121.9 9.5 4 93 167 06/12198 Lot #26, Central Area FG 4.0 123.6 10.2 4 94 168 06/12/98 Lot #30. Central Area FG 3.0 126.3 9.2 5 97 169 06112/98 Lot #32. Central Area FG 3.0 123.3 9.5 5 95 170 06/12/98 lot #34, Central Area FG 3.0 123.6 9.0 5 95 171 06/12/98 lot #36, Central Area FG 3.0 120.4 9.9 5 92 172 06/12198 lot #38, Central Area FG 3.0 127.3 6.1 5 98 173 06112198 lot #40, Central Area FG 3.0 123.2 7.9 5 94 Tract, 24182-2 174 06/12/98 lot #42, Central Area FG 3.0 120.5 7.5 5 92 175 06/12/98 lot #44, Central Area FG 3.0 121.7 8.9 5 93 176 06/12/98 lot #46, Central Area FG 3.0 117.7 9.6 5 90 177 06/12/98 lot #48, Central Area FG 3.0 118.8 9.1 5 91 178 06112198 lot #50, Central Area FG 3.0 119.7 9.5 5 92 96-81-420-30 Converse Consultants ICCI ENT\OFFICEIJOBFI LEI 1996196-81196-420-30. FDT 7 + I I I I I I I I I I I I I I I I I ,I I I I TA8.LE NO.1 SUMMARY OF FIELD DENSITY TI:ST RESUl.TS APPROX APPROX ORY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd Iftl Iftl (pell IRCI Tract. 24182-2 179 06/12/98 Lot #52, Central Area FG 3.0 124.5 9.2 5 95 Cut into 180 06/12/98 Lot #60. Central Area FG mass 116.9 6.6 5 90 nradino fill Cut into 181 06/12/98 Lot #58, Central Area FG mass 116.8 6.9 5 90 nradinn fill Cut into 182 06/12/98 Lot #56, Central Area FG mass 122.4 11.7 5 94 gradlngfill Cut into 183 06/12/98 Lot 1154, Central Area FG mass 121.2 12.0 5 93 nradina fill Tract 24182-1 184 06/12/98 Lot #20, Central Area. 1127.0 0 114.0 10.2 2 91 185 06/12/98 Lot #22, Central Area 1120.5 0 115.1 8.6 2 92 186 06/12/98 lot #23, Central Area 1119.0 2 112.3 7.1 2 90 187 06/12/98 lot #21, Central Area 1126.0 2 112.5 11.0 2 90 188 06/12/98 Lot #20, Central Area 1129.0 2.5 112.7 10.6 2 90 189 06/12/98 Lot #22, Central Area 1123.0 2.5 115.4 9.9 2 92 190 06/12/98 Lot #23, Central Area 1120.0 3 113.8 9.6 2 91 Tract 24182.2 Cut into Fail, see RT 191 06/15/98 lot #3, Central Area FG mass 108.8 5.0 5 83 grading fill #191A SC Cut into 192 06/15/98 lot #5, Central Area FG mass 124.7 7.3 5 96 SC grading fill Tract 24182-2 Cut into 191A 06/15/98 lot #3, Central Area FG mass 116.8 6.0 5 90 AT of 11191 "rading fill Cut into 193 06/15/98 Lot #7, Central Area FG mass 121.5 9.1 5 93 SC gradinglill Cut into 194 06/15/98 Lot 119, Central Area FG mass 117.9 6.5 4 90 nradinnfill Cut into 195 06/15/98 Lot It 11, Central Area FG mass 120.3 6.3 4 92 gradinglill Cut into 196 06/15/98 Lot #13, Central Area FG mass 119.4 6.0 4 91 nradinn fill 96-81-420-30 Converse Consultants ICCI ENT\OFFICEIJOBFI LE\ 1996\96-81 \96-420-30. FDT 8 "v '\ I I I I I I I I I I I , I I I ,I I I I I TABLE NO.1 SUMMA RY OF FiElD DENSITY TE:ST RESUL.TS APPROX APPROX DRY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd lit} lIt} Ipell IRC} Tract, 24182-2 Cut into 197 06/15/98 Lot II 15, Central Area FG mass 119.6 6.1 4 91 aradina fill 198 06/15/98 Lot #32, Central Area 1119.0 2.5 116.6 10.7 2 93 199 06/15/98 Lot #34, Central Area 1122.0 2.5 112.6 11.0 2 90 SC 200 06/15/98 Lot #36, Central Area 1124.0 2.5 114.5 10.5 2 91 201 06/15/98 lot #42 , Central Area 1134.0 3.0 113.8 10.9 2 91 202 06/16/98 Lot #46, West Area 1124.0 3.0 112.7 7.1 2 90 Tract, 24182-1 203 06/16/98 Lot #74, Central Area FG 8.0 118.2 10.4 2 94 204 06/16/98 Lot #72, Central Area FG 9.0 116.2 7.8 2 93 205 06/16/98 Lot #70, Central Area FG 12.0 t 14.4 7.9 2 91 206 06/16/98 Lot #68, Central Area FG 13.0 112.5 9.7 2 90 207 06/16/98 lot #66, Central Area FG 10.0 114.5 9.9 2 91 208 06/1 6/98 lot #64, Central Area FG 2.0 124.4 6.7 5 95 209 06/16/98 lot #76, Central Area FG 2.5 123.3 10.9 5 94 210 06/16/98 Lot #78, Central Area FG 2.5 125.1 10.6 5 96 Cut into 211 06/16/98 Lot #80, Central Area FG mass 119.1 10.5 5 91 oradina fill Cut into 212 06/16/98 Lot #82, Central Area FG mass 116.9 10.0 5 90 gradino fill Cut into 213 06/16/98 Lot #52, Central Area FG mass 123.1 10.7 5 94 grading fill Cut into 214 06/16/98 Lot #50, Central Area FG mass 124.2 6.0 5 95 qradinqfiU 215 06/16/98 Lot #54, Central Area FG 4.0 118.8 6.3 5 91 216 06/16/98 Lot #56, Central Area FG 6.0 119.7 6.0 5 92 217 06/16/98 Lot #58, Central Area FG 8.0 125.1 6.9 5 96 218 06/16/98 Lot #28, Central Area 1118.0 2.5 111.3 9.7 1 90 219 06/16/98 Lot 1118, Central Area 1132.0 2.5 112.0 10.9 1 90 220 06/16/98 Lot #19, Central Area 1132.0 2.5 115.9 12.4 1 93 221 06/16/98 Lot 1146, South West Area 1125.0 6.0 117.1 7.3 5 90 96-81-420-30 Converse Consultants ICCI ENTiOFFICEIJOBFILE\ 1996\96-81 \96-420-30. FDT 9 4}> I I I I I I I I I I I I I I I I I I I TAELE NO.1 SUMMARY OF FIELD DENSITY TI:ST RESUL.TS APPROX APPROX ORY % REL TEST TEST TEST FILL % SOIL REMARKS NO. OATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd Iftl (It I Ipet) IRCI Tract, 24182-1 222 06/16/98 lot #46, West Area 1127.0 8.0 118.2 6.9 5 91 Tract, 24182-2 Cut into 223 06/1 6/98 Lot #17, Central Area FG mass 119.9 6.2 4 91 nradino fill 224 06/16/98 Lot #19, Central Area FG 4.0 118.4 8.0 4 90 SC 225 06/16/98 Lot #21, Central Area FG 4.0 112.3 6.8 2 90 226 06/16/98 Lot #23, Central Area FG 4.0 118.7 7.0 4 90 227 06/16/98 Lot #27, Central Area FG 4.0 118.9 9.9 4 90 228 06/16/98 Lot #25, Central Area FG 4.0 115.8 7.5 2 92 Tract. 24182-1 229 06/17/98 Lot #16, Central Area 1135.0 1.0 118.6 6.6 5 91 230 06/17/98 lot # 17. Central Area 1135.0 1.0 116.8 7.0 5 90 231 06/17/98 Lot #34, Central Area 1121.0 2.5 117.3 6.9 5 90 232 06/17/98 Lot #41, Central Area 1136.0 6.0 122.0 7.1 5 93 233 06/17/98 lot #44, Central Area 1131.0 5.0 117.1 8.5 5 90 234 06/17/98 Lot #45, South East Area 1127.0 6.0 116.9 8.8 5 90 235 06/17/98 Lot #45. South West Area 1129.0 8.0 117.5 7.8 90 236 06/18/98 Lot #73, Central Area FG 8.0 115.7 10.0 2 92 SC 237 06/18/98 Lot #71, Central Area FG to.O 122.2 9.7 5 93 238 06/18/98 Lot #69, Central Area FG 13.0 125.5 10.1 5 95 239 06/18/98 lot #67, Central Area FG 11.0 116.3 10.0 2 92 240 06/18/98 lot #65, Central Area FG 9.0 122.4 8.9 5 93 241 06/18/98 Lot #63, Central Area FG 3.0 121.3 8.9 2 96 242 06/18/98 lot InS, Central Area FG 3.0 131.4 8.5 4 99 243 06/18/98 lot #77, Central Area FG 3.0 114.5 7.6 2 93 244 06/18/98 lot #79, Central Area FG 3.0 131.5 8.0 4 100 CUI into 245 06/18/98 Lot #81, Central Area FG mass 127.0 9.3 5 97 grading fill Cut into 246 06/18/98 Lot #83, Central Area FG mass 122.2 10.4 5 93 oradina fill 96-81-420-30 Converse Consultants ICCI ENTiOFFICE\JOBFI LE\ 1996\96-81 \96-420-30. FDT 10 + I I I I I I I I I I I I I I I I I I I TABLE NO.1 SUMMARY OF FIELO OENSITY HST RESUl.TS APPROX APPROX ORY % REL TEST TEST TEST FILL % SOIL REMARKS NO. OATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd Iftl Iftl (pefl . (RCI Tract, 24182-2 Cut into 247 06/19/98 lot #1, Central Area FG mass 122.2 6.9 5 94 nradinnfi!l 248 06/19/98 Lot #37, Central Area FG 3.0 120.7 7.0 5 92 249 06/19/98 lot #35, Central Area FG 3.0 123.4 6.3 5 95 250 06/19/98 Lot #33, Central Area FG 3.0 128.5 7.1 5 98 SC 251 06/19/98 Lot #31, Central Area FG 3.0 119.1 6.6 5 91 252 06/19/98 Lot #29, Central Area FG 3.0 122.8 6.9 5 94 253 06/19/98 Lot #39, Central Area FG 3.0 123.9 6.5 5 95 254 06/19/98 Lot #41, Central Area FG 3.0 126.6 7.0 5 97 SC 255 06/19/98 Lot #43, Central Area FG 3.0 119.9 8.4 5 92 256. 06/19/98 lot #45, Central Area FG 3.0 116,9 8.0 5 90 257 06/19/98 Lot #47, Central Area FG 3.0 117.4 7.4 5 90 258 06/19/98 lot #49, Central Area FG 3.0 120.2 6.0 5 92 SC 259 06/19/98 Lot #51, Central Area FG 3.0 117.5 6.6 5 90 260 06/19/98 Lot #53, Central Area FG 3.0 118.4 6.5 5 91 Cut into 261 06/19/98 Lot #55, Central Area FG mass 117.4 6.3 5 90 nradinnfill Cut into 262 06/19/98 lot #57, Central Area FG mass 127.9 8.9 5 98 se gradingfilt Tract, 24182-' 263 06/19/98 lot #37, Central Area FG 5.0 120.3 9.6 5 92 264 06/19/98 Lot #38, Central Area FG 5.0 120.8 7.4 5 93 265 06/19/98 Lot #39, Central Area FG 5.0 120.5 7.3 5 92 266 06/19/98 lot #40, Central Area FG 5.0 130.3 7.9 5 99 267 06/19/98 lot #41, Central Area FG 8.0 126.4 6.9 5 97 SC 268 06/19/98 Lot #42, Central Area FG 6.0 126.0 9.7 5 97 269 06/19/98 Lot 1143, Central Area FG 6.0 124.6 7.4 5 96 270 06/19/98 Lot 1144, Central Area FG 6.0 120.6 11.1 5 92 271 06/19/98 Lot #45, Central Area FG 10.0 122.4 7.6 4 94 272 06/1 9/98 Lot 1/46, Central Area FG 10.0 117.4 9.3 4 90 96-81-420-30 Converse Consultants ICCI ENT\OFFI CE\JOBFI LE\ 1996\96-81 \96-420-30. FDT 11 bfJ I I I I I I I I I I I I I I I I I I I TAE.LE NO.1 SUMMA RY OF fiELD DENSITY TEST RESUl.TS APPROX APPROX DRY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd Iftl Iftl (pefl IRCI Tract, 24182-1 Cut into 273 06/19/98 lot #49. Central Area FG mass 116.8 6.5 5 90 grading fill Cut into 274 06/19/98 Lot #50. Central Area FG mass 119.8 8.6 5 92 oradinafill Cutlnto 275 06/19/98 Lot #51, Central Area FG mass 122.4 6.0 5 94 oradingfill Cut into 276 06/19/98 lot #52, Central Area FG mass 122.8 6.2 5 94 grading fill Tract, 24182.2 Cut into 277 06/19/98 Lot #61, Central Area FG mass 116.0 6.1 5 92 oradina fill Cut into 278 06/19/98 lot #59, Central Area FG mass 116.5 6.0 5 93 oradinl1fill Tract, 24182-1 279 06/22/98 lot #36, Central Area FG 5.0 121.0 7.2 5 93 SC 280 06/22/98 lot #35, Central Area FG 5.0 116.8 6.4 5 90 281 06/22/98 Lot #34, Central Area FG 5.0 117.0 7.5 5 90 282 06/22/98 Lot #33, Central Area FG 5.0 118.6 6.4 5 91 283 06/22/98 Lot #32, Central Area FG 5.0 122.7 8.1 5 94 284 06/22/98 lot #31. Central Area FG 5.0 116.9 6.0 5 90 285 06/22/98 Lot #30, Central Area FG 5.0 116.8 7.0 5 90 286 06/22/98 lot #29, Central Area FG 5.0 118.4 6.9 5 91 287 06/22/98 lot #11, Central Area FG 3.0 114.2 7.6 2 91 288 06/22/98 Lot # 12, Central Area FG 3.0 116.1 8.2 2 93 289 06/22/98 lot # 13. Central Area FG 3.0 114.5 7.8 2 91 290 06/22/98 lot #14, Central Area FG 3.0 121.9 7.3 2 97 SC 291 06/22/98 lot #15, Central Area FG 2.0 123.1 6.8 5 94 292 06/22/98 lot #16, Central Area FG 2.0 121.1 7.9 2 96 293 06/22/98 lot #17, Central Area FG 2.0 115.7 6.0 2 92 294 06/22/98 Lot #18, Central Area FG 5.0 123.9 6.2 5 95 295 06/22/98 lot # 19, Central Area FG 5.0 122.0 6.8 5 93 se 296 06/22/98 Lot #20, Central Area FG 5.0 124.9 9.1 5 96 96-81-420-30 Converse Consultants ICCI ENTlOFFICEIJOBFI LEI 1996196-81 \96-420-30.FDT 12 ~\. I I , I I I I I I I I I I I I I I I I I TAELE NO.1 SUMMARY OF FIELD DENSITY TEST RESUL.TS APPROX APPRO X DRY % REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. DEPTH DENS. MOIST TYPE COMP 90%RC Req'd Iftl Iftl Ipctl {RCI Tract, 24182-' 297 06/22/98 Lot #21, Central Area FG 5.0 128.9 9.2 5 93 298 06/23/98 Lot #84, Central Area FG 3.0 117.5 6.5 5 90 SC 299 06/23/98 Lot #85, Central Area FG 3.0 125.5 6.5 5 96 300 06/23/98 lot #86, Central Area FG 3.0 123.8 7.7 5 95 301 06/23/98 Lot #87. Central Area FG 3.0 129.1 6.0 5 99 302 06/23/98 Lot #88, Central Area FG 3.0 122.2 6.5 5 94 303 06/23/98 Lot #89, Central Area FG 3.0 125.6 6.1 5 96 304 06/23/98 lot #90, Central Area FG 3.0 123.8 8.1 5 95 Tract. 24182.2 305 06/23/98 Lot #28, Central Area FG 3.0 121.9 6.3 5 93 Tract, 24182-' 306 06/23/98 Lot #22, Central Area FG 5.0 125.5 8.2 5 96 307 06/23/98 Lot #23, Central Area FG 5.0 120.2 6.9 5 92 308 06/23/98 Lot 1/28, Central Area FG 5.0 125.4 8.1 5 96 309 06/23/98 Lot #27, Central Area FG 5.0 122.5 7.1 5 94 310 06/23/98 lot #26, Central Area FG 5.0 124.9 8.9 5 96 311 06/23/98 lot #25, Central Area FG 5.0 123.7 8.3 5 97 312 06/23/98 lot #24, Central Area FG 5.0 127.4 6.8 5 98 Cut into 313 06/24/98 lot 1110, Central Area FG mass 118.0 6.3 2 94 oradinafill Cut into 314 06/24/98 Lot 119. Central Area FG mass 112.7 7.3 1 91 nradinnfill 315 Cut into 06/24/98 Lot #8, Central Area FG mass 113.2 6.7 2 90 nradinn fill 316 Cut into 06/24/98 Lot #7, Central Area FG mass 120.5 9.2 5 92 grading fill Cut into 317 06/24/98 Lot #6, Central Area FG mass t 19.7 8.1 5 92 nradinnfill Cut into 318 06/24/98 lot 115. Central Area FG mass 120.8 9.2 5 93 nradinnfill 96-81-420-30 Converse Consultants ICCI ENTiOFFICEIJOBFILEI 1996196-81 196-420-30. FDT 13 1>IJ1/ I I I I I I I I I I I I I I I I I I I TAeLE NO.1 SUMMARY OF FiElD DENSITY TE:ST RESUl.TS APPROX APPROX DRY % REL TEST TEST TEST LOCATION TEST FILL DENS. % SOIL COMP REMARKS NO. DATE ELEV. DEPTH (pcfl MOIST TYPE IRe) 90%RC Req'd Iftl 1ft) Tract, 24182-1 Cut Into 319 06124198 lot #4, Central Area FG mass 114.1 10.1 1 92 oradino fill Cut into 320 06124198 Lot #3, Central Area FG mass 111.2 4.5 7 93 aradino fill Cut into 321 06/24/98 Lot #2, Central Area FG mass 111.0 15.5 7 93 oradino fill Cut into 322 06/24/98 lot #1, Central Area FG mass 113.5 6.3 2 90 aradino fill Cut into 323 06/24198 lot 1/95, Central Area FG mass 121.8 7.3 5 93 oradinn fill Cut into 324 06/24198 Lot #94, Central Area FG mass 119.2 9.3 5 91 Qradinofill Cut into 325 06/24/98 lot #93, Central Area FG mass 119.2 11.1 5 91 aradino filJ Cut into 326 06/24/98 Lot #92, Central Area FG mass 128.5 9.2 5 99 nradion fill Cut into 327 06124198 lot #91, Central Area FG mass 116.9 8.1 5 90 oradinQfill 328 06126/98 Lot #48, Central Area FG 4.0 121.6 6.3 5 93 329 06126198 Lot #47, Central Area FG 4.0 119.9 6.0 5 92 330 06130/98 Park, North East Area 1011.0 0.0 112.5 7.4 1 91 331 06/30198 Park, South East Area 1100.0 0.0 114.9 8.3 1 93 332 06130198 Park. Central Area 1101.0 0.0 116.9 6.7 5 90 333 06130/98 Park, Central Area 1102.0 0.0 117.2 6.6 5 90 334 06130198 Park, West Area 1102.0 0.0 112.3 7.6 1 91 335 06/31/98 Park, North Area 1104.0 2.0 114.0 6.9 2 91 336 06131198 Park, East Area 1102.0 2.0 118.6 8.4 5 91 337 06131/98 Park. West Area 1103.0 2.0 117.2 7.9 5 90 338 06/31/98 Park, South Area 1100.0 2.0 120.2 7.7 5 92 339 06/31/98 Park, Central Area 1103.0 2.0 114.5 9.9 2 91 340 07/06/98 Park, North Area 1105.0 2.0 114.3 7.3 2 91 341 07/06/98 Park, East Area 1102.0 2.0 114.1 7.1 2 91 342 07/06/98 Park, North West Area 1105.0 2.0 113.7 6.8 2 91 96-81-420-30 Converse Consultants ICCI ENT\OFFICEIJOBFILEI 1996196-81 196-420-30.FDT 14 A.?:> I I I I I I I I I I I I il II I I I I I TAB.LE NO.1 SUMMA RY OF FIELD DENSITY TEST RESUI.TS APPROX APPROX DRY %REL TEST TEST TEST FILL % SOIL REMARKS NO. DATE TEST LOCATION ELEV. OEPTH DENS. MOIST TYPE COMP 90%RC Req'd Iftl 1ft} (pef) IRC} Tract. 24182-1 343 07106/98 Park, South Central Area 1103.0 2.0 116.8 6.9 5 90 344 07/06/98 Park, South Area 1102.0 2.0 118.6 6.6 5 91 345 07/16/98 Charmes Ct. FG 3.0 112.3 7.3 2 90 Opposite Lot #44 346 07/16/98 Volterra St., Opp. Lot #2 FG 1.0 116.8 7.1 5 90 347 07/16/98 Rovato St., Opp. lot #18 FG 1.0 119.4 11.1 5 92 348 07/16/98 Matera St., Opp. Lot #22 FG 1.0 117.0 6.6 5 90 349 07/16/98 Teramo St., Opp. lot #68 FG 1.0 116.8 6.0 5 90 350 07/16/98 . Caserta Dr., Opp. Lot #12 FG 1.0 120.2 8.7 5 92 351 07/16/98 Avala Ct., Opp. lot #78 FG 1.0 114.2 7.5 2 91 352 06/18/98 Pad #73 FG NA 115.7 10. 2 92 SC 353 06/18/98 Pad #71 FG NA 122.2 9.7 5 93 SC 354 06/18/98 Pad #69 FG NA 125.5 10.1 5 95 SC 355 06/18/98 Pad #67 FG NA 116.3 10.0 2 92 se 356 06/18/98 Pad #65 FG NA 122.4 8.9 5 92 SC 357 06/18/98 Pad #63 FG NA 121.3 8.9 2 96 se 358 06/18/98 Pad #75 FG NA 131.8 8.5 4 95 SC 359 06/18/98 Pad #77 FG NA 117.5 7.6 2 93 SC 360 06/18/98 Pad #79 FG NA 133. 8. 4 95 se 361 06/18/98 Pad 1/81 FG NA 127.0 9.3 5 93 SC 362 06/18/98 Lot #83 FG NA 122.2 10.4 5 97 SC 96-81-420-30 Converse Consultants ICCI ENTlOFFI CE\JOBFI LEI 1996\96-81196-420-30. FDT 15 ~ I I I I I I I I I I I I I I I I I I I APPENDIX B LABORATORY TESTING />..6 I I I I I I I I I I I I I I I I I I I APPENDIX B LABORATORY TESTING Laboratory tests were conducted on representative samples of the subgrade soils for the purpose of evaluating physical properties and engineering characteristics. A total of 19 samples, numbered 1 through 1 9, representing the subgrade soils of the various lots of the subject tracts were retrieved at the completion of grading. Grain-Size Analvsis The grain-size distribution covers the quantitative distribution of particle sizes in soils. The particle distribution is used to aid in the classification of the soils. The results of the gradation tests performed on representative samples of bulk samples are presented in Figure No. 8-1, Grain-Size Distribution. Laboratorv Maximum Densitv and Optimum Moisture Tests Laboratory maximum density and optimum moisture tests were performed on representative bulk samples of fill soils retrieved during grading. These tests were performed in accordance with the ASTM Standard 01557-91 Method. The results are presented in Table No. B-2, Summary of Laboratory Maximum Dry Density and Optimum Moisture Content Tests. Four (4) representative samples of the subgrade soils retrieved at the completion of grading were also tested to determine their laboratory maximum dry density and optimum moisture content. These test results were utilized in the preparation of ring samples for the direct and consolidation tests. Direct Shear Tests Four (4) direct shear tests were performed on reconstituted rings samples prepared from bulk samples retrieved at the completion of grading. The bulk samples were reconstituted at 90 percent of the laboratory maximum dry density and at optimum moisture content. Individual ring samples were prepared, soaked and a vertical surcharge was applied. Each ring was then sheared at a constant rate of strain. A range of normal loads was applied and the shear strength envelope was determined. Results of the tests are presented in Figure Nos. B-3 through 8-6, Direct Shear Test. Table No. B-1 SUMMARY OF LABORATORY MAXIMUM PRY PENSITY ANO OPTIMUM MOISTURE CONTENT TESTS Soil Soil Description Max Dry Density Optimum Moisture Type (pctl Content (%) 1 Silty Sand ISM), fine to medium-grained, some clay, brown 1Z4.0 10.0 2 Silty Sand (SM), fine. to coarse-grained, with some clay, light brown. 125.5 8.0 3 Sandy Silt (ML). with some clay, light brown 112.0 16.0 4 Silty Sand (SM), fine. to coarse-grained, trace clay, light brown 131.5 9.0 5 Silty Sand ISMl. fine- to medium-grained, trace clay. light brown 130.5 9.0 6 Sandy Silt IMLl. with clay, brown 120.0 12.5 ~ I I I I I I I I I I I I I I I I I I I Consolidation Tests Consolidation tests were performed on ring samples reconstituted from bulk samples of the representative subgrade soils. The reconstituted samples were prepared at 90 percent of the laboratory maximum dry densities and at optimum moisture contents. This test involved loading a ring sample into the test apparatus, which contained a porous stone to accommodate vertical drainage during testing. Vertical load in then applied and resulting deflection recorded at various time interval. The load was increased after the sample reached a reasonable state of equilibrium. The load was increased after the sample reached a reasonable state of equilibrium. The specimen was submerged after the sample reached equilibrium at 2.0 kips per square-foot (ksf) vertical stress. The samples were loaded to a maximum of 16.0 ksf street before unloading. Test results are presented in Figure Nos. 8-7 through 8-8, Consolidation Test. Expansion Index (Ell Test Representative samples of the pad soils were tested in accordance with UBC Standard 18- 2 to evaluate their expansion potential. Test results are presented in Table No. B-2, Results of Expansion Index Test. TABLE NO. B-2 SUMMARY OF EXPANSION INDEX TEST RESULTS Sample Lot No. , Representative Lots Soil Classification Expansion No. Index (El) Tract 24182-2 1 1 1-9 Silty Sand ISM), fine- to medium-grained, trace clay mica, brown 14 2 18 10-18 Silty Sand ISM), fine--grained, reddish brown 15 3 25 19-27 Clayey/Silty Sand ISC/SM). fine- grained, brown 36 4 32 28-37 Silty Sand ISM), fine- to medium-grained, trace clay, brown 12 5 41 38-45 Siltv Sand ISM), fine- grained. some clay, brown 21 6 60 54-61 Sandy Silt IMll, brown 11 7 52 46-53 Sandy Clav ICl), brown 48 Tract 24182-1 8 94 91-95 Silty Sand ISM), fine- to medium-grained, brown 9 9 2 1-7 Silty Clay ICl), brown 76 10 8 8 and 9 Clayey Sand ISCI, fine- to medium-grained. brown 46 11 10 10-23 Silty Sand (SM). fine- to medium-grained, trace, brown 10 12 25 24-36 Silty Sand (SM), fine- to medium-grained, trace clay, brown 12 13 40 37-48 Clayey Sand (Sel, fine- to medium-grained, brown 31 14 49 49-52 Silty Sand ISM), fine-grained, trace clay, brown 12 15 56 53-62 Silty Sand (SM), fine-grained, some clay, brown 16 16 68 63-74 Silty Sand (SM}, fjne- to medium-grained, trace clay, brown 13 17 78 75-79 Silty Sand ISM), fine-grained, some clay, brown 22 18 81 80-83 Clayey Sand ISC), fine- to medium-grained, brown 36 19 87 84-90 Silty Sand ISMI. fine- to medium-grained, trace clay, brown 15 f>...'\ 'I I I I I I I I I I I I I I I I I I I I Soil Corrosivitv Tests Two bulk samples of representative pad subgrade soils were tested for soil corrosivity. These tests were performed by M. J. Schiff and Associates, Claremont, California. Test results are included at the end of this appendix. ~ I I I I I I I I I I I I I I I I I I I UNIFIED SOIL CLASSIFICATION GRA VEL SAND COARSE FINE FINE COBBLES SILT OR CLAY U.S. SIEVE SIZE IN INCHES U.S. STANDARD SIEVE No. HYDROMETER 3/4 3/B 4 3 10 20 40 60 140 200 100 n~~ " "- '\ "\ ~ \ ~' \J\ I'\. \ \ \X: ~ 1\ " "- '1' T 80 E-' ~ 1.:) ~ r.:I ~ >-< CO 60 1.:) z ~ lfj lfj '" P.. E-' 40 Z r.:I U n:: r.:I P.. 20 o 103 10 1 lut GRAIN SIZE IN MILLIMETER 100 Hf2 1 US 102 Sample No.1 DEPTH SYMBOL Tract No. (ft) DESCRIPTION 0 #6/82-2 0-1 Sandy Silt (ML) 0 #7/82-2 0-1 Sandy Clay (CL) f\, #9/82-1 0-1 Silty Clay (CL) 0 #16/82-1 0-1 Silty Sand (SM) GRAIN SIZE DISTRIBUTION o 20 E-' ~ 1.:) ~ r.:I ~ >-< CO 40 Q r.:I Z :;: E-' r.:I n:: 60 E-' Z r.:I U n:: I'Ll P.. 80 Tract 14182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Converse Consultants Inland Empire Figure No. B-1 t>t,o... I I I I I I I I I I I I I I I I I I I r- 140 90 130 ~ 120 u 0.. Z ~ E-< ::r:: 0 ~ I'iI 110 "" E-< ~ Z. ~ >-< Cr: Q 100 80 0 5 10 15 20 MOISTURE CONTENT IN PERCENT Sample No.! Lot No.! DEPTH TEST OPTIMUM MAXIMUM DRY SYMBOL Tract No. (ft) DESCRIPTION METHOD MOISTURE (%) DENSITY (pcf) 0 6/60/82-2 0-1 Sandy Silt (ML), Brown DI557(A)-91 13.0 116.3 0 7/52/82-2 0-1 Sandy Clay (CL), Brown o I 557(A)-91 9.1 128.5 [0 9/8/82-1 0-1 Silty Clay (CL), Brawn o 1557(A)-91 13.3 1214 0 16/78/82-10-1 Silty Sand (SM). Brown DI557(A)-91 9.1 128.0 COMPACTION TEST Tract 24182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Converse Consultants Inland Empire Figure No. B-2 ")0 I I I I I I I I I I I I I I I I I II , II 2.0 ~ Ul ~ Z ~ Ul Ul 1.0 IOiI P:: b Ul P:: ~ ::c: Ul .0 .0 1.0 2.0 3.0 4.0 5.0 NORMAL STRESS IN KSF 4.0 -- ~ 0 ~ Ul ~ Z ~ Ul Ul IOiI 2.0 P:: b Ul P:: <<: IOiI ::c: Ul .0 .0 .1 .2 .3 .4 .5 Sample No.1 Lot No.lTract No. : 6/60/82-2 DESCRIPTION : Sandy Silt (ML), STRENGTH INTERCEPT (ksf) FRICTION ANGLE (degree) HORIZONTAL DEFORMATION IN INCH DEPTH (It) Brown 0-1 .020 (PEAK STRENGTH) (PEAK STRENGTH) 25.5 MOISTURE DRY DENSITY VOID NORMAL PEAK RESIDUAL SYMBOL CONTENT (%) (pef) RATIO STRESS (ksf) SHEAR (ksf) SHEAR (ksf) 0 14.8 115.7 .456 .50 .25 .24 0 14.7 116.6 .445 1.50 .75 .73 " 14.3 115.8 .455 300 1.44 1.44 DIRECT SHEAR TEST Tract 24182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Converse Consultants Inland Empire Figure No. B-3 '5\ I I I I I I I I I I I I I I I I I I I 4.0 .,,/ /' /' ,/ I'<< Ul ::<: Z ~ Ul &5 2.0 ~ ~ Ul ~ ~ "" :r:: Ul .0 .0 2.0 4.0 6.0 NORMAL STRESS IN KSF B.O 10.0 4.0 t: p y:r 'P- I'<< Ul ~ Z ~ Ul Ul "" 2.0 ~ E--< Ul ~ ~ "" ~ Ul .0 .0 .1 2 .3 .4 5 Sample No.1 Lot No.lTract No. : 7/52/82-2 DEPTH (It) DESCRIPTION : Sandy Clay (eL), Brawn STRENGTH INTERCEPT (ksf) .145 FRICTION ANGLE (degree) 31.7 HORIZONTAL DEFORMATION IN INCH 0-1 (PEAK STRENGTH) (PEAK STRENGTH) MOISTURE DRY DENSITY VOID NORMAL PEAK RESIDUAL SYMBOL CONTENT (%) (pel) RATIO STRESS (ksf) SHEAR (ksf) SHEAR (ksf) 0 16.1 115.4 .460 .50 .48 .43 0 15.8 116.0 .452 1.50 1.03 1.00 '" 15.9 115.7 .456 3.00 2.02 1.94 DIRECT SHEAR TEST Tract 24182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Converse Consultants Inland Empire Figure No. 8-4 ?'I/ I I I I I I I I I I I I I I I I I I I 2.0 V / V y -" ~ V ~ I'll ~ Z - I'll gJ LO ~ E-< I'll ~ ~ "" ::r:: I'll .0 .0 5.0 1.0 2.0 3.0 NORMAL STRESS IN KSF 4.0 4.0 ~ I'll ~ Z ~ I'll I'll ;:iI 2.0 ~ E-< Ul ~ ~ ;:iI ::r:: Ul .og .0 .5 .1 .2 .3 .4 HORIZONTAL DEFORMATION IN INCH Sample No.1 .'-Lot No.lTract No. : 9/8/82-1 DEPTH (It) iDESCRIPTION : Silty Clay (eL), Brown STRENGTH INTERCEPT (ksf) .166 FRICTION ANGLE (degree) 23.6 '0-1 (PEAK STRENGTH) (PEAK STRENGTH) MOISTURE DRY DENSITY VOID NORMAL PEAK RESIDUAL SYMBOL CONTENT (%) (pet) RATIO STRESS (ksf) SHEAR (ksf) SHEAR (ksf) 0 25.0 105.8 .593 .50 .31 .31 0 24.0 107.1 .573 1.50 .94 .92 to 26.4 106.8 .578 3.00 1.43 1.43 DIRECT SHEAR TEST Tract 24182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Converse Consultants Inland Empire Figure No. 8-5 ~'? I I I I I I I I I I I I I I I I I I I 4.0 I'c, Ul :>:: z ~ Ul Ul W D:: E-< Ul ~ <<: w :r:: rn 2.0 /v V/ .0 .0 2.0 10.0 4_0 6.0 NORMAL STRESS IN KSF 8.0 4.0 ;:., rn :>:: ~ rn rn W 2.0 ~ b rn D:: <<: ro'I :r:: rn ~ ~ :.--t:r per .0 .0 2 .1 .3 .4 5 HORIZONTAL DEFORMATION IN INCH Sample No.1 Lot No.lTract No. : 16/78/82-1 DEPTH (It) DESCRIPTION : Silty Sand (SM), Brown STRENGTH INTERCEPT (ksf) .192 FRICTION ANGLE (degree) 31.9 0-1 (PEAK STRENGTH) (PEAK STRENGTH) MOISTURE DRY DENSITY VOID NORMAL PEAK RESIDUAL SYMBOL CONTENT (%) (pcf) RATIO STRESS (ksf) SHEAR (ksf) SHEAR (ksf) 0 17.1 115.1 .463 .50 .50 .37 0 16.5 113.1 .490 1.50 1.14 1.08 {:, 16.3 114.7 .469 3.00 2.06 206 DIRECT SHEAR TEST Tract 24182-1 and -2 For: Newland Associates Project No 96-81-420-30 Converse Consultants Inland Empire Figure No. 8-6 fA. I I I, I I I I I I I I I I I I I I I I Z E-< ~ C'J - i:iI ~ Z - 4 Ii1 C'J Z <<: ~ u E-< Z 6 Ii1 U n:: Ii1 p, 8 10-1 o LOAD IN KIPS PER SQUARE FOOT 1 10 102 .515 10 C'" tl \ \ I ~ '- '" , ~ It. ~ , , ~- - \. -- ~- ... - .364 .485 .454 0 - E-< <<: n:: Q - 0 .424 :> .394 Sample No.1 Lot No.lTract No.: DEPTH (ft) 7/52/82-2 0-1 DESCRIPTION Sandy Clay (CL), Brawn MOISTURE CONTENT (%) DRY DENSITY (pet) INITIAL FINAL 9.2 14.3 115.2 124.5 Note: Solid circles indicate readings after addition of water CONSOLIDATION TEST Tract 24182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Figure No. B-7 -9 Converse Consultants Inland Empire I I I I I I I I I I I I I I I I I I I 2 b :r:: '-" - ;:iI :r:: z - 4 ;:iI '-" Z <t ~ U b Z 6 ;:iI U ~ ;:iI P, 8 10-1 o LOAD IN KIPS PER SQUARE FOOT 1 10 102 .673 10 ;....- ~ ~ --- '-.. , "" "'- , , , , , , , , , , , '\. , , ,\ .506 .640 .606 o - b <t ~ ~ - o .573 > .539 Sample No.! Lot No.!Tract No.: DEPTH (ft) 9/8/82-1 0-1 DESCRIPTION Silty Clay (CL), Brown MOISTURE CONTENT (%) DRY DENSITY (pet) IN1TIAL F1NAL 12.5 22.1 108.3 110.3 Note: Solid circles indicate readings after addition of water CONSOLIDATION TEST Tract 24182-1 and -2 For: Newland Associates Project No. 96-81-420-30 Figure No. B~8 '5~ Converse Consultants Inland Empire I M. J. Schiff & Associates, Inc. Consulting Corrosion Engineers - Since 1959 I I I I Sam pie ID I Soil Type I Resistivity as-received saturated I pH Electrical Conductivity I Chemical Analyses Cations calcium magnesium sodium Anions carbonate bicarbonate chloride sulfate I I I I Other Tests sulfide Redox ammonium nitrate I I I 1291 N. Indian Hill Boulevard Claremont, CA 91711-3897 Phone 909.626.0967 Table 1 - Laboratory Tests on Soil Samples Newland Your #96-81-420-30, MJS&A #98002-17 13-Jul-98 Tr. 24182-1 Sample #9 0-1' Units ohm-cm ohm-cm silt silt 790,000 2,350 2,500 660 6.9 7.2 0.03 0.28 "---'~--'-- '..~.~ -' -', ~:.;:..__ ;"'._' :.:.:1 Electrical conductivity in millisiemens/cm and chemical analysis were made on a 1:5 soil-ta-water extract. mg/kg ~ milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts NO ~ not detected oa = not analyzed I I I mS/em Ca2+ mglkg NO 32 Mg2+ mglkg NO 7 Nal+ mg/kg 11 218 CO.2- mglkg NO NO , HCO/- mglkg NO 134 C;'- mg/kg 18 337 SO./- mg/kg NO NO S2- qual na mv na NH41+ mglkg na NO," mg/kg na na na na na ~~~...,.c-.____~...,..__~.'C- -.-., - - .- ...........-- Page] of 1 ,.~ ? I I , I I I I I I I I I I I I I I I I I APPENDIX C SOil CORROSIVITY STUDY ~ I I I I I I I I I I I I I I I I I I I M. J. SCHIFF & ASSOCIATES, INC. Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711.3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOLCOM June 9, 1997 CONVERSE CONSULTANTS INLAND EMPIRE 10391 Corporate Drive Redlands, California 92374 Attention: Mr. Mohammed Islam Re: Soil Corrosivity Study Paseo Del Sol Temecula, California Your #96-81-420-03, MJS&A #97002-14 INTRODUCTION Laboratory tests have been completed on 46 soil samples you provided for the referenced single family residences project. The purpose of these tests was to determine if the soils may have deleterious effects on underground utilities and concrete foundations. The soil samples were provided from three of six tracts that compose the 830 acre site. The site is half hilly terrain and half a flat, alluvial plain. The hilly portion of the site is classified, geologically, as the Pauba Formation. The Pauba Formation is in a cut area and will be used as fill over the alluvial plain. We assume that the samples provided are representative of the most corrosive soils at the site. The scope of this study is limited to a determination of soil corroslVlty and general corrosion control recommendations for materials likely to be used for construction. If the architects and/or engineers desire more specific information, designs, specifications, or review of design, we will be happy to work with them as a separate phase of this project. TEST PROCEDURES The electrical resistivity of each sample was measured in a soil box per ASTM 057 in its as- received condition and again after saturation with distilled water. Resistivities are at about their lowest value when the soil is saturated. The pH of the saturated samples was measured. A 5: 1 water:soil extract from each sample was chemically analyzed for the major anions and cations. Test results are shown on Table 1. CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANAL YSIS . EXPERT WITNESS. CORRQSIVITY AND DAMAGE ASSESSMENTS ~ I I I I I I I I I I I I I I I I I I I CONVERSE CONSULTANTS INLAND EMPIRE MJS&A #97002-14 June 9, 1997 Page 2 SOIL CORROSIVITY A major factor in determining soil corrosivity is electrical resistivity. The electrical resistivity of a soil is a measure of its resistance to the flow of electrical current. Corrosion of buried metal is an electrochemical process in which the amount of metal loss due to corrosion is directly proportional to the flow of electrical current (DC) from the metal into the soil. Corrosion currents, following Ohm's Law, are inversely proportional to soil resistivity. Lower electrical resistivities result from higher moisture and chemical contents and indicate corrosive soil. A correlation between electrical resistivity and corrosivity toward ferrous metals is: Soil Resistivity in ohm-centimeters Corrosivity Category mildly corrosive moderately corrosive corrOSlve severely corrosive over 2,000 to ],000 to below 10,000 10,000 2,000 1,000 Other soil characteristics that may influence corrosivity towards metals are pH, chemical content, soil types, aeration, anaerobic conditions, and site drainage. Electrical resistivities were in mild]y and moderately corrosive and corrosive categories with as- received moisture. When saturated, the resistivities dropped into mildly through severely corrosive categories. The resistivities dropped considerably with added moisture because the samples were dry as-received. The wide variations in soil resistivity can create concentration type corrosion cells that increase corrosion rates above what would be expected from the chemical characteristics alone. The corrosive and severely corrosive resistivities measured on saturated soil samples are summarized in the following table. Tract Lot Saturated Resistivitv (ohm-cm) Soil Tvpe 24186-1 9 1,350 sil ty sand 24186-1 49 1,300 silty sand 24186-2 47 1,550 silty sand 24] 86-2 53 850 silty sand 24186-2 59 1,300 silty sand 24186-2 117 1,600 silty sand 24] 88-F ]0 980 silty sand 24188-F 13 1,350 silty sand 24l88-F 26 1,000 silty sand 24188-F 53 l,200 silty sand 24l88-F 61 850 clayey silty sand CP I I I I I I I I I I I I I I I I I I I CONVERSE CONSULTANTS INLAND EMPIRE MJS&A #97002-14 June 9,1997 Page 3 Soil pH values varied from 5.7 to 7.5. This range is moderately acidic to mildly alkaline and does not particularly increase soil corrosivity. The chemical content of the samples was low. No concentration was high enough to be of particular concem. Tests were not made for sulfide or negative oxidation-reduction (redox) potentials because they would not exist in these dry, aerated samples. This soil is classified as corrosive and severely to ferrous metals. CORROSION CONTROL The life of buried materials depends on thickness, strength, loads, construction details, soil moisture, etc., in addition to soil corrosivity, and is, therefore, difficult to predict. Of more practical value are corrosion control methods that will increase the life of materials that would be subject to significant corrosion. \ Steel Pipe l Abrasive blast underground steel utilities and apply a high quality dielectric coating such extruded polyethylene, a tape coating system, hot applied coal tar enamel, or fusion bonded epoxyl. Bond underground steel pipe with rubber gasketed, mechanical, grooved end, or othL nonconductive type joints for electrical continuity. Electrical continuity is necessary for corrosidn monitoring and cathodic protection. Electrically insulate each buried steel pipeline from dissimilar metals, cement-mortar coated and concrete encased steel, and above ground steel pipe to prevent dissimilar metal corrosion cells arid to facilitate the application of cathodic protection. Apply cathodic protection to steel piping as per NACE Intemational RP-O 169-96. As an alternative to dielectric coating and cathodic protection, apply a 3/4 inch cement mortar coating or encase in cement-slurry or concrete 3 inches thick, using any type of cement. Iron Pipe Encase ductile iron water piping in 8 mil thick low-density polyethylene or 4 mil thick higfu- density, cross-laminated polyethylene plastic tubes or "TaPS per A WW A Standard C I 05 or c01t with a high quality dielectric coating such as polyurethane or hot applied coal tar enamel. As k alternative, encase iron piping with cement slurry or concrete at least 3 inches thick surrounding tHe pipe. USIng any type of cement. Bond all nonconductive type joints for electrical continuityl 0;\ I I I I I I I I I I I I I I I I I I I CONvERSE CONSULTANTS INLAND EMPIRE MJS&A #97002-14 June 9, 1997 Page 4 Elecuically insulate underground iron pipe from dissimilar metals and above grOlmd iron pipe with insulated joints. Encase cast iron drain lines in 8 mil thick low-density polyethylene or 4 mil thick high-densirv - ., cross-laminated polyethylene plastic tubes or wraps per A WWA Standard CI05. As an alternative, encase iron piping with cement slurry or concrete at least 3 inches thick surrounding the pipe, using any type of cement. Electrically insulate underground iron pipe from dissimilar metals and above ground iron pipe with insulated joints. Copper Tube Copper tubing for cold water should be bedded and backfilled in sand with a saturated resistivity above 5,000 ohm-em. Hot water tubing may be subject to a higher corrosion rate. The best corrosion control measure would be to place the hot copper tubing above ground. If buried, encase in plastic pipe to prevent soil contact or apply cathodic protection. Plastic and Vitrified Clay Pipe No special precautions are required for plastic and vitrified clay piping placed underground from a corrosion viewpoint. Protect any iron valves and fittings with a double polyethylene wrap per A WW A C I 05 or as described below for bare steel appurtenances. Where concrete thrust blocks are to be placed against iron, use a single polyethylene wrap to prevent concreteliron contact and to eliminate the slipperiness of a double wrap. All Pipe On all pipe, coat bare steel appurtenances such as bolts, joint hamesses, or flexible couplings with a coal tar or elastomer based mastic, coal tar epoxy, moldable sealant, wax tape, or equivalent after assembly. \\!here metallic pipelines penetrate concrete structures such as building floors or walls, use plastic sleeves, rubber seals, or other dielecuic material to prevent pipe contact with the concrete and reinforcing steel. Concrete Any type of cement and standard concrete cover over reinforcing steel may be used for concrete structures and pipe in contact with these soils. ~'V I I I I I I I I I I I I I I I I I I I CONVERSE CONSULTANTS INLAND EMPIRE MJS&A #97002-14 Please call if you have any questions. Respectfully Submitted, M.J. SCHIFF & ASSOCIATES, INe. M-f- It, ~ Robert A. Pannell jsd Enc: Table I DOCS-97\97002-14.DOC June 9, ] 997 Page 5 Reviewed by: ~~kf ;f4~{~.1l- Paul R. Smith, P.E. ~<7 I M. J. SCHIFF & ASSOCIATES, INC. I I I I I I I I II I I I I I I I I I Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOL.COM Table 1 - Laboratory Tests on Soil Samples Page 1 of I Paseo del Sol, Tracl24l84 Your #96-81-420-03, MJS&A #97002-14 May 5,1997 Tract 24184-1 Tract 24184-1 Tract 24184-1 Tract 24184-1 Tract 24184-1 Sample ID Sample #3 Sample #4 Sample #7 Sample #8 Sample #9 Lot 10 Lot 13 Lot 72 Lot 67 Lot 61 . ,. ,~". . Soil Type silty silty silty silty silty sand sand sand sand sand Resistivity Units as. received ohm-em 49,000 24,500 14,000 25,000 3,800 saturated ohm-em 3,900 21,000 4,300 3,600 2.200 pH 7.0 6.4 6.9 6.9 7.1 Electrical Conductivity mS/cm 0.06 0.00 0.02 0.04 0.05 Chemical Analyses Cations calcium Ca2~ mglkg 16 NO NO NO NO magnesium Mo2- mg/kg NO NO NO NO NO ~ sodium Nal~ rng/kg 57 14 28 46 64 Anions carbonate CO,'" mglkg NO NO NO NO NO bicarbonate HCO-'- mglko 122 37 73 98 98 , ~ chloride CI'- mglkg 46 NO ND 14 43 sulfate SO!' mglkg NO NO NO ND ND Other Tests sulfide S2- qual na na na na na Redox mv na na na na na ammonium NH-\I-<- mg/kg na no na na na nitrate NO-" mg/kg na na na na na , Electrical conductivity in millisiemens/cm and chemical analysis are ofa 1:5 soil-ta-water extract. mg/kg =: milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts NO = not detected na = nor analyzed d()csl)7\970()~. J -+.\ls CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECiFICATIONS. FAILURE ANALYSIS. EXPERT WITNESS. CORROSIVITY AND DAMAGE ,';SSESSMENTS (}\ I M. J. SCHIFF & ASSOCIATES, INC. . Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 I E-mail SCHIFFCORR@AOL.COM Table 1 - Laboratory Tests on Soil Samples Page I of 4 I Paseo del So/ Your #96-81-420-03, MJSM #97002-14 I May 5, 1997 Tract 24186-1 Tract 24186-1 Tract 24186-1 Tract 24186-1 Tract 24186-1 I Sample ID Sample #2 Sample #4 Sample #6 Sample #10 Sample # I 3 lot 8 Lot 18 Lot 27 Lot 59 Lot 49 .-.."... . ~ J. I Soil Type silty silty silty silty silty sand sand sand sand sand Resistivity Units I as-received ohm-em 520,000 335,000 200,000 600,000 8,400 saturated ohm-em 6,700 8,200 4,500 5,350 1,300 I pH 6.8 6.2 6.7 6.8 6.4 Electrical I Conductivity mS/cm 0.02 0.01 0.03 0.04 0.08 Chemical Analyses I Cations calcium Ca~'" mglkg NO NO NO NO 16 magnesium Mo2-+ mglkg NO NO NO NO NO ~ I sodium Na" mgfkg 18 18 28 37 76 Anions carbonate CO/ mg/kg NO NO NO NO NO I bicarbonate HC031. rnglkg 49 49 49 73 49 chloride ci" mg/kg NO ND 14 14 99 I sulfate SO,'- mglkg NO NO NO NO 25 Other Tests I sulfide S2- qual na na na na na Redox mv na na na na na ammonium NH/,' mglkg na na na na na I nitrate NO)" mg/kg na na na na na Electrical conductivity in millisiemens/cm and chemical analysis are of a 1:5 soil-to-warer extract. I mg/kg = milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potentia] in millivolts NO = not detected I na =: not analyzed docs97\97002.14.xls <P I CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANAL YSIS . EXPERT WITNESS. CORROSIVITY AND DAMAGE ASSESSMENTS I M. J. SCHIFF & ASSOCIATES, INC_ I Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOL.COM I I Table I - Laboratory Tests on Soil Samples Page 2 of 4 I Paseo del Sol Your #96-8/-420-03, MJS&A #97002-/4 May 5, /997 I Tract 24186-1 Tract 24186-1 Tract 24186-1 Tract 24186-1 Tract 24186-1 Sample ID Sample # 15 Sample # 18 Sample # 19 Sample #21 Sample #23 Lot46 Lot 73 Lot 76 Lot 114 Lot 99 Soil Type silty silty silty silty silty sand sand sand sand sand Resistivity Units as-received ohm-em 240,000 14,000 36,000 420,000 230,000 saturated ohm-em 3,700 2.900 2,500 5,200 4,400 pH 6_7 5.7 6.3 6.4 6.8 Electrical Conductivity mS/cm 0.02 0.02 0.04 0.03 0_01 Chemical Analyses Cations calcium Ca2- mg/kg NO NO NO NO NO magnesium Mg:!* mglkg NO NO NO NO NO sodium Na1- mglkg 0' 0' 41 28 18 _0 _0 Anions carbonate CO-'- mglkg NO NO NO NO NO , bicarbonate HCO-" mglka 61 37 49 49 49 , ~ chloride ci" mglkg NO 14 35 14 NO sulfate SO./- mg/kg NO ND ND ND ND Other Tests sulfide S::'o qual na na na na na Redox mv na na na na na ammonium NH~I+ mglkg na na na na na nitrate NO/ mglkg no no na na na I I I I I I I I I I I Electrical conductivity in millisiemens/cm and chemical analysis are of a 1:5 soil-ta-water extract. mg/kg = milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction porentin! in millivolts ND = not detected nn = nor analyzed Jocs97\9700~-1 ~.x1s ~ I I CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLA.NS AND SPECIFICATIONS. FAILURE ANALYSIS . EXP~RT WITNESS. CORROSIVITY AND DAMAGE ASSESSMENTS ~ I M. J. SCHIFF & ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-ma'; SCHIFFCORR@AOL.COM Table 1 - Laboratory Tests on Soil Samples Page 3 of 4 Paseo del Sol Your #96-81-420-03, MJS&A #97002-14 May 5,1997 Tract 24186-1 Tract 24186-1 Tract 24186-1 Tract 24186-1 Tract 24186-1 Sample ID Sample #24 Sample #28 Sample #29 Sample #30 Sample #31 Lot 107 Lot 90 Lot 87 Lot 84 Lot 80 "'..--.-..._. . . .-.... .~,- . .. _.--- Soil Type silty silty silty silty silty sand sand sand sand sand Resistivity Units as-received ohm-em 590,000 9,400 250,000 70,000 16,000 saturated ohm-em 3,800 4,700 3,000 3,300 9,800 pH 6.8 6.9 6.5 6.9 6.9 Electrical Conductivity mS/cm 0.02 0.02 0.02 0.02 0.01 Chemical Analyses Cations calcium C ,. mglkg NO NO NO NO NO a- magnesium Mo2+ mg/kg NO NO NO NO NO ~ sodium Na" mglkg 28 28 ?' 28 18 -" Anions carbonate CO,'" mglkg NO NO NO NO NO bicarbonate HCO,'. mglkg 73 73 37 73 49 chloride ci'" rn glkg ND NO 14 NO ND sulfate S042- mglkg NO NO NO NO NO Other Tests sulfide S', qual no na na na na Redox mv na na na no na ammonium NH41+ mglkg na no na na no nitrate NO,'" mglkg na no na na na Electrical conductivity in millisiemens/cm and chemical analysis are of a 1:5 soil-ta-water extract. mg/kg 0:: milligrams per kilogram (parts per million) of dry soil. Redox 0:: oxidation-reduction potenrial in millivolts N 0 ~ not detected na 0:: not analyzed docs<'}7\9700:!-14.xls CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANALYSIS. EXPERT WITNESS' CORROSIVITY AND DAM,o.GE ASSESSMENTS eo"- I I I I I I 'I I I I I I I I I I I I I M. J. SCHIFF & ASSOCIATES, INC. Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-'4'9 E"mail SCHIFFCORR@AOLCOM Table 1 - Laboratory Tests on Soil Samples Page 4 of 4 Paseo del Sol Your #96-81-420-03, MJS&A #97002-14 May 5, 1997 Sample ID Tract 24186-1 Sample #39 Lot 9 Soil Type silty sand Resistivity as-received saturated Units ohm-em ohm-em 39,000 1,350 7.1 pH Electrical Conductivity mS/cm 0.01 Chemical Analyses Cations calcium C ,- NO a- mglkg magnesium Mo~'" mgfkg NO ~ sodium Nato- mglkg 18 Anions carbonate CO," mglkg NO bicarbonate HCO/ rnglkg 49 chloride ci'" mglkg NO sulfate SO,'" mglkg NO Other Tests sulfide S~- qual na Redox mv na ammonium NH~I" mglkg na nitrate NO,'- mglkg na Electrical conductivity in millisiemenslcm and chemical analysis are of a ]:5 soil-ta-water extract. mg/kg == milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts ND = not detected na = nor analyzed tlncs97\97002-I-lxls CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS A,~D SPECIFICATIONS' FAILURE ANAL YSIS . EXP"RT WITNESS' CORROSIVITY AND DAMAGE ASSESSMENTS cJ:> I M. J. SCHIFF & ASSOCIATES, INC. I Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621 -14 1 9 E-mail SCHIFFCORR@AOLCOM I I Table 1 - Laboratory Tests on Soil Samples Page I of 4 I Paseo del Sol Your #96-81-420-03, MJS&A #97002-14 May 5, 1997 I Tract 24186-2 Tract 24186-2 Tract 24186-2 Tract 24186-2 Tract 24186-2 Sample ID Sample # 1 Sample #3 Sample #4 Sample #6 Sample #8 Lot2 Lot9 Lot 14 Lot 24 Lot 32 co' ~." Soil Type silty silty silty clayey silty sand sand sand sand sand Resistivity Units as-received ohm-em 28,000 830,000 15,000 14,000 54,000 saturated ohm-em 5,900 2,300 3,500 2,000 3,200 pH 7.5 7.3 7.3 7.1 7.3 Electrical Conductivity mS/cm 0.02 0.06 0.03 0.06 0.04 Chemical Analyses Cations I I I I I calcium Ca> mglkg magnesium Mv2+ mglkg " sodium Na1+ mglkg Anions carbonate CO/" mglkg bicarbonate HCO." mglkcr , ~ chloride CI" m g/kg sulfate SO./- rng/kg Other Tests sulfide S~- qual Redox mv ammonium NH," mglkg nitrate NO," mglkg ND 16 ND ND ND ND ND ND ND ND 28 71 32 76 46 ND ND ND ND ND 73 98 85 98 85 ND 82 NO 60 21 ND ND ND ND ND I I I I na na na na na na na na na na na na na na na I no na no no na I Electrical conducrivity in millisiemenslcm and chemical analysis are of a 1:5 soil-ta-water extract. mg.lkg = milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts ND ~ not detected na = nO( analyzed I dllcs97\97002-14.xls I CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANALYSIS. EXPERT WITNESS. CORROSIVITY AND DAMAGE ASSESSMENTS <1\ I M. J. SCHIFF & ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOl.COM Table 1 - Laboratory Tests on Soil Samples Page 2 of 4 Paseo del Sol Yaur #96-81-420-03, MJS&A #97002-14 May 5,1997 Tract 24186-2 Tract 24186-2 Tract 24186-2 Tract 24186-2 Tract 24186-2 Sample ID Sample #9 Sample # II Sample #12 Sample # 13 Sample # 16 Lot 37 Lot 63 Lot 47 Lot 59 Lot 53 Soil Type silty silty silty silty silty sand sand sand sand sand Resistivity Units as-received ohm-em 13,000 28,000 13,000 10,200 81,000 saturated ohm-em 2,500 2,100 1,550 1,300 850 pH 7.3 7.1 7.3 7.4 6.8 Electrical Conductivity mS/cm 0.04 0.08 0.10 0.14 0.18 Chemical Analyses Cations calcium Ca> mglkg ND 16 ND 16 12 magnesium Moz- mglkg ND ND ND ND ND ~ sodium Nal'" mg/kg 48 74 116 146 192 Anions carbonate CO/, mglkg ND ND ND ND ND bicarbonate HCO," mglkg 98 49 49 134 61 ch loride C( mglkg 18 71 II3 113 245 su I fate 50/- mglkg ND 59 50 84 50 Other Tests sulfide S1- qual na na na na na Redox mv na na na na na ammonium NH"t+ mglkg na na na na na nitrate NO,'- mglkg na na na na na Electrical conductivity in millisiemensfcm and chemical analysis are ofa 1:5 soil-to-water extract. mglkg = milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts N D ~ not detected nJ = not analyzed docs97\97002-1-l.xls CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANAL YSIS . EXPERT WITNESS. CORHOSIVITY AND DAMAGE ASSESSMENTS "P_ , I I M. J. SCHIFF & ASSOCIATES INC. , I Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711.3897 Phone 909-626-0967 FAX 909-621-1419 I E-mail SCHIFFCORR@AOLCOM I Table 1 - Laboratory Tests on Soil Samples Page 3 of 4 Paseo del Sol Your #96-81-420-03, MJS&A #97002-14 .1 May 5, 1997 Tract 24186-2 Tract 24 I 86-2 Tract 24 I 86-2 Tract 24186-2 Tract 24186-2 I Sample ID Sample # 17 Sample # 19 Sample #20 Sample #21 Sample #25 Lot 67 Lot 78 Lot 81 Lot 84 Lot 113 I Soil Type silty silty silty _ silty silty sand sand sand sand sand Resistivity Units I as-received ohm-em 500,000 330,000 750,000 400,000 97,000 saturated ohm-em 3,100 2,600 3,900 3,600 2,600 I pH 7.0 7.4 7.1 6.8 7.3 Electrical I Conductivity mS/cm 0.03 0.07 0.02 0.04 0.08 Chemical Analyses I Cations calcium C ,- mglkg ND ND ND ND ND a- magnesium Mo2. mglkg ND ND ND ND ND ~ I sodium Na1<- mg/kg 37 80 28 46 92 Anions carbonate COo,. mg/kg ND ND ND ND ND I , bicarbonate HCOJ'. mglkg 49 49 49 49 61 chloride cl" mg/kg 28 74 14 43 85 I sulfate So..t mg/kg ND 28 ND ND 28 Other Tests I sulfide S2- qual na na na na na Redox mv na na na na na ammonium NH," mglkg na na na na na I nitrate NO]l- mg/kg na na na na na Electrical conductivity in millisiemens/cm and chern ical analysis are of a 1:5 soil-ta-water extract. I mg/kg = milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts NO = not detected I nn = not analyzed docs97\97002-14xls I "'\\ CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANAL YSIS . EXPERT WITNESS. CORROSIVITY AND DAMAGE ASSESSMENTS II I I I I I I 'I I ! I I I I II I I I I I I M. J. SCHIFF & ASSOCIATES INC. , Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOlCOM Table 1 - Laboratory Tests on Soil Samples Page 4 of 4 Paseo del Sol Your #96-81-420-03, MJS&A #97002-14 May 5, 1997 Somple ID Tract 24 I 86-2 Sample #26 lot 117 Soil Type silty sand Resistivity as-received saturated Units ohm-em ohm-em 390,000 1.600 6.8 pH Electrical Conductivity mS/cm 0.14 Chemical Analyses Cations calcium Ca> mglkg magnesium Mo2. mglkg ~ sodium No ,- mg/kg Anions carbonate CO/. mglkg bicarbonate HC031- mglkg chloride C( mglkg sulfate so,t mg/kg Other Tests sulfide S2- qual Redox mv ammonium NH.t' mglkg nitrate NO]'- mg/kg ND ND 162 ND 61 191 31 na na na no Electrical conductivity in millisiemens/cm and chemical analysis are of a 1:5 soil-to-\vater extract. mglkg == milligrams per kilogram (pans per million) of dry soil. Redox == oxidation-reduction potential in millivolts ND ~ not detected na = not analyzed docs97\97002-14.\ls CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND SPECIFICATIONS. FAILURE ANALYSIS. EXPERT WITNESS. CORROSIVITY AND DAMAGE ASSESSMENTS ",\1-- I I I I I I I I I I I , I I I I I I I I M. J. SCHIFF & ASSOCIATES, INC. Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOl.COM Table 1 - Laboratory Tests on Soil Samples Page I of 2 Paseo del Sol Your #96-81-420-03, MJS&A #97002-14 May 5,1997 Tract 24] 88-F Tract 24188-F Tract 24188-F Tract 24188-F Tract 24188-F Sample ID Sample # I Sample #5 Sample #8 Sample #9 Sample # I 0 Lot 13 Lot 10 Lot31 Lot26 Lot61 ~.;.;\":;:: 1..:. . Soil Type silty silty silty - sandy clayey sand sand sand silt silty sand Resistivity Units as-received ohm-em 600,000 14,000 42,000 5,300 46,000 saturated ohm-em 1,350 980 10,000 1,000 850 pH 7.1 7.1 7.1 6.9 6.6 Electrical Conductivity mS/cm 0.12 0.18 0.01 0.10 0.10 Chemical Analyses Cations calcium C " mglkg NO 16 NO NO NO a- magnesium Mo2+ mglkg NO NO NO NO NO 0 sodium Nal+ mglkg 143 184 18 117 108 Anions carbonate CO," mglkg NO NO NO NO NO bicarbonate HCO) 1- mglkg 49 49 49 49 49 chloride c1" mglkg 191 284 NO 152 138 sulfate 50..\2- mglkg NO NO NO NO NO Other Tests sulfide S2- qual na na na na na Redox mv na na na oa na ammonium NH," mglkg na na na na na nitrate NO,'. mglkg na no na na na Electrical conductiviry in millisiernens/cm and chemical analysis are ora 1:5 soil-ta-water extract. mg/kg::: milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potential in millivolts NO = not detected na = not analyzed docs97\9700~.I-I_xJs CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND S?ECIFICATIONS . FAILURE ANAL YSIS . EXPERT WITNESS. CORROSIV1TY AND DAMAGE ASSESSMENTS "\'? I I I I I I I I I I I I I I I I I I I M. J. SCHIFF & ASSOCIATES INC_ , Consulting Corrosion Engineers - Since 1959 1291 North Indian Hill Boulevard Claremont, California 91711-3897 Phone 909-626-0967 FAX 909-621-1419 E-mail SCHIFFCORR@AOL COM Table I - Laboratory Tests on Soil Samples Page:1 of 2 Poseo del Sol Your #96-81-420-03, MJS&A #97002-14 May 5, 1997 Sample lD Tract 24] 88-F Tract 24] 88-F Tract 24l88-F Tract 24188-F Sample #13 Sample#14 Sample #15 Sample #16 Lot 46 Lot 48 Lot 53 Lot 43 Soil Type silty silty silty- silty sand sand sand sand Resistivity Units as-received ohm-em 10,800 6,000 25,000 75,000 saturated ohm-em 2,350 3,050 1,200 3,] 00 pH 7.1 6.9 6.6 6.8 Electrical Conductivity mS/cm 007 0.05 0.08 0.04 Chemical Analyses Cations calcium C '. mglkg ND ND ND ND a- M '. m g1kg ND ND ND ND magneslum 0- e sodium Na 1- mg./kg 78 60 87 46 Anions carbonate CO," mglkg ND ND ND ND bicarbonate HCO)~- mglkg 49 49 49 49 ch loride CI'- mg/kg 92 64 ]06 43 su I fate SO/, mglkg ND ND ND NO Other Tests sulfide 52- qual na na na na Redox mv na na na no ammonium NH," mg!kg na na na na nitrate NO]I- mglkg na na na no Electrical conductivity in millisiemens/cm and chemical analysis are of a 1:5 soil-ta-water extract. mglkg = milligrams per kilogram (parts per million) of dry soil. Redox = oxidation-reduction potentia! in millivolts N D ~ not detected na = not analyzed dncs97\97002-14_xls CORROSION AND CATHODIC PROTECTION ENGINEERING SERVICES PLANS AND S?ECIFICATIONS . FAILURE ANAL YS1S . EXPERT WITNESS. CORROSIVITY AND DAMAGE ASS~SSMENTS 1~ I I I I I I I I I I I I I I I I I I I ! I APPENDIX D LIQUEFACTION POTENTIAL AND SEISMICALLY INDUCED GROUND SETTLEMENT ANALYSIS ""oj I I I I I I I I I I APPENDIX D LIQUEFACTION POTENTIAL AND SEISMICALLY-INDUCED GROUND SETTLEMENT ANAL YSIS An analysis was performed to evaluate the soil liquefaction potential and seismically- induced ground settlement for the graded site. This analysis was performed for the subsurface conditions at the locations of the BH-5 and BH-6 drilled during field exploration for the preparation of the "Preliminary Geotechnical Investigation' report, dated April 26, 1996. These borings were drilled within the Pauba Valley area near Highway 79 and adjacent to the subject tracts (see Drawing No.1 of the April 26, 1996 report). The logs of these borings are included at the end of this appendix. At least the upper 10 feet of the existing soils from the area adjacent to Highway 79 were over excavated during mass grading. The overexcavation was backfilled with compacted soils. At last seven (7) feet of additional compacted fills were placed within this area to raise the ground surface elevation to the finish grade level. The present liquefaction analysis was performed incorporating these backfill and fill into the subsurface conditions. Liquefaction analysis was performed in accordance with the method suggested by Seed et. al (1985). Resu'lts of this analysis are presented in Table No. 0-2, Results of Liquefaction Analysis at BH-5 and Table No. 0-3, Results of Liquefaction Analysis at BH-6. Various soil and ground motion parameters selected for this analysis are also included in these tables. I I I I I I I I I Based on these results, soil layers at the BH-5 between the depths of 29 feet and 39 feet from the original ground surface (i.e. 36 feet and 46 feet below current ground surface) are prone to liquefaction during earthquakes. The sandy soils layers at BH-6 between the depths of 20 feet and 34 feet below original ground surface (i.e. 27 and 42 feet below existing ground surface) are prone to liquefaction. The dense sandy soils layers below 50 feet from the current ground surface at both locations are not considered susceptible to liquefaction. Tokimatsu and Seed (1987) present a simplified method for the evaluation of settlement in sands due to earthquake loading. Analysis for seismically induced settlement incorporating current site conditions at BH-5 and BH-6 are presented in Table No. 0-3, Results of Seismically-Induced Ground Settlement at BH-5 and Table No. 0-4, Results of Seismically Induced Ground Settlement at BH-6. Based on these results, the estimated seismically induced ground settlement near Highway 79 ranges from about 1.0 to 3.0 inches. ~ I I I I I I I I I I I I I I I I I I Checked by: MSI ]40 Ib I 30 inch 20.0 , AMPlES "" '#. "" , 0 5 0 w "" '"- cr: - ;:) Z .(fJ W 5 "" ;:) 0: ~ ~ (fJ W --l 0 0 >--=- I cr: ;:) --l 0:<.J "" 0 co co ~ 0.9- 0 36 12 117 Log of Boring No. BH-5 Dates Drilled: Logged by: !BC 4/2/96 Equipment: 5 SAND (SP): fine-grJined, grayish brown 13 2 '~<; <:1';:: *'~' ;,;,<;: '^. :~;:: 14 2 10 l ',y - fine- to coarse-grained I I I I I - fin~-gr:lind IXl " 7 14 15 1 , I I .'^ <Y'/ ~* ~' 0 ~<~: :::>~: :P% - finc::- to mdium-grained, with clav '?<,' 45 6 113 20 ~ ' :::;;:: 15 30 Driving Weight and Drop: 8" H.S.A. Ground Surface EIevation(ft): 1084.0 Depth to Water(ft): 14 20 108 c ~ - SU1,IMARY OF SUBSURFACE CONDITIONS This log is part of the report prepared by Converse for this project and should be re.:ld together with the report. This summary applies only at: the location of the boring and at the time of drilling. Subsurface conditions may differ at ocher loc:ltions and may change at this location with the passage of time. The data presented is a simplification of actual conditions encountered. 15 19 I "" !l. W o U I !l. <(l9 0:0 19--l o r;l\vi ng N (J. A-Sa '\~ Al T T lVTI 1M (QaIJ CLAYEY SAND (SC): fine- to medium-grained. brown I 25 SAND (SP): lint:- to cn;lrsc-gnind, light brown ..------..-------------- S-ANDY CLA Y (CL):- ~ith- ~~-ry- fwe-gr:linc;:d sand, gray 30 I I : r.::/>/>~. j - - CL-P. YE"Y "SAND (SC)~ fint.:- tn mt.:Jium-gr:lint.:J, gr:l"/."..".." - - - -"..""""""""" i7 ~ Converse Consultants ~ Inland Empire Project Nome. EASTEREN AND SOUTl-f\-VESTER,'J PORTION OF THE MEADO\VS T.:rnccul:l. California Project No. %-31-.,0-01 I Dates Drilled: I Equipment: Log of Boring No. BH-5 4/2/96 Logged by: lBC 8" H.S.A. Driving Weight and Drop: Ground Surface Elevation(ft): I I I I I I I I I I I I I I I ~ - U T 1L <Cl a:o Cl...J 1084.0 Depth to Water(ftl: SUMMARY OF SUBSURFACE CONDITIONS This log is part of the report prepared by Converse for this project and should be read together with the report. This summary applies only at the location ofche boring and at the time of drilling. Subsurface conditions may differ at other locations and may change at chis location with the passage of time. The data presented is a simplification of actuill conditions encountered. CLAYEY SAND (SC): fine- to medium-grained, gray SAi'lD (SP): fine. to medium-grained, grayish brown - interbedded 6" thick Sandy Cl::Ly (CL) layer - line- to coarse-gr:l.ined End or" boring :l.t 50 feet. GroundwJter encountered at 20 feet. Borehole backfillc=d with native soil cuttings on 4/2/96. I ~ Converse Consultants ~ Inland Empire Project Name. EASTEREN AND SOUTHWESTER:--J PORTIQN OF THE MEADO\VS T~m.:cuJo, Californio I l- e.. w o 40 45 50 Checked by: 140 Ib I 30 inch 20.0 , AMPLES w > 0.: a: :5 o m Project N(). 96-31-4:20-0 I MSI I- ~ ~ 0 0 s 0 w u.. a: I- - ::J Z (j) I- a: S (j) ::J w 0 0 >-~ I ...J a: " ?- m :2 0.3- 0 36 13 26 18 114 21 14 114 DrJwing No. A-5b "8> I I Log of Boring No. BH-6 Dates Drilled: 4/2/96 Logged by: IEC Checked by: MSI I Equipment: 8" H.S.A. Driving Weight and Drop: 140 Ib I 30 inch Ground Surface Elevation(ft): 1094.0 Depth to Water(ft): 20.0 I SUlvlMARY OF SUBSURFACE CONDITIONS , ~ AMPlES f- >'? 0 This log is part of the report prepared by Converse for this project a.nd should be 0 S I .::: re3d together with the report. This summary applies only at the location oftht: 0 LU f- U u.. a: I boring and at the time of drilling. Subsurface conditions may differ at other - :J Z I (f) f- 0.. locations and may change at this location with the pasS.'lge of time. The data S f- :J a: <(9 presented is a simplification of actual conditions enCQuncered. (f) LU 0.. 0 >-~ I LU a:O ..J 0 a:u f- I 0 (9..J en 2 0.3- 0 All TTVTlfM (<PI) CLAYEY SAND (SC): very flne- to fme-grained, dark brown I 29 12 113 SAND (SP): fine- to medium-grained, grayish brown 5 16 2 97 I I 33 SANDY CLA Y (CL): dark brown 43 10 I I SAND (SP): fine-grained, gnyish brown 32 6 104 c 15 I I . fme- to medium.gfJint:d 6 21 ma 20 ~ I I 20 7- -) I I 8 19 I 30 \ I I Ie 11111I11i, SANDY SILT (ML): gr:1;t 15 40 83 I ~ Converse Consultants Project N3me. Project No. Drawing No. ~ Inland Empire EASTERE:-J AND SOUTH\VESTER,'J 96-8l--l.20-Q 1 A-6J ,1\ PORTION OF THE j\.IEADOWS T<.:m;:~u!J. ClIlifornill I I I I I I I I I I I I I I I I I I I I Log of Boring No. BH-6 Dates Drilled: Logged by: IBC 4/2/96 Equipment: 8" H.S.A. Driving Weight and Drop: Checked by: 140 Ib / 30 inch MSI Ground Surface Elevation(ft): Depth to Water(ft): 1094.0 20.0 SUMMARY OF SUBSURFACE CONDITIONS , ,.: AMPLES l- t!- This log is pan of the report prepared by Converse for this project and should be a - ~ .::: read together with the report. This summary applies only at the location of the a UJ I- U u.. I!: boring and at the time of drilling. Subsurface conditions may differ at other - ~ Z :r: :r: locations and may change at this location with the passage of time. The data (/J l- I!: "- UJ ~ ~ I- <1:(9 presented is a simplification of actual conditions encountered. ~ '" (/J UJ "- ...J a >-~ T UJ I!: a I!: ~ ...J a I!:U j:: 0 (9...J 0 ill ill ::;;; oc. a SANDY SlL T (ML): gray . . SAND (SP): fine- to medium-grained, gray ~ 18 25 l- 40 -I' ...... ..' .. . ....... . :'. - 45 22 16 117 - . - fine- to coarse-grJ.ined, brown '. ..... . I I' . I ~ 45 13 I 50 I End of boring at 50 feet. I I Groundwater encountered at 20 feet. ! I I Borehole backfilled with native soil cuttings on 4/2/96. I I I I I , I I I i I I I I I 1 I I I , I i , I I I I I I I I , I i I , , ~ Converse Consultants ~ Inland Empire Project Name. EASTEREN AND SOUTfNIESTERN PORTION OF THE l\.IEADO\i/S T..::m..::cul:J., C.1!ifornill Project Nil. 96-3 l--CO-Q I Dr:nving 0io. A-6b tbO I I I I I I I I I I I I I I I I I I I OJ co OJ to ro ;I]~;;?~0g> I I I I -; o,o,a,rn z 0 - ;::;. Cll (tl 0 =.: ~ ;! ::l'" '" rD 5 C Ol 0 Z ~ C> n".g 0 -< a. ~. 0- ^ OJ 0 :I:l :E ...... CD m~;3~.~~ g ~ sa..': ~ c6" Z WNI'VN " :;: <~~~*~~ 0 ..p. CD.p. 0 ~ 0000 ; ~ ~ffi~.g~~- 0 I ~7:B.~ ::~ , ('\l OJ - ~ ~ - ro p O' ~ :0 "' ~ (f)(j)()(f) ~ 0 CD n-Ur-o "' r iD" '" rn .~ C ;::; ~ rn ~ ~ f:>f"WW g m 0 0 "' -...)--'0)--> "' ~ " ~ ...., 01 (.0 N-...J C ~ -....J~rn~--' ~ r C m -..,J ()l 0) 0 0 W ~ m .0 ~ ~ C NNNW m ~ "' m CD Wo,<o-> "' () "" "' ...., O...../'V-...J c ~ Ol ;:; i; 0 .-+ () OJ 0 Z ""'0 ,. 0 5' "' =r -< !l) C ...... ~ ~ W ~ ~ .. 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Of; ~W~o ~qJ~ 0000 :::-~;: . r ! i -n 0 { 9909 fi~ .; ~fg~~ ~6~ .1 ':IJ 5: " 0000 ~"l() /- ~u,:::"w ~~ri o rn ~ 0> - (/) ,.... ~ooo..... o(/)n . :-':-':-':-' 51:' / 0000 0 !J 0000 :0 :f "' ~ I 0000 :t>- :t>- o . . 0 -n 0 () " ~w"w m"TI~ OOCD~"'" -l 0 ~ ~, i \10 , I I - I I I I I I I I I I I I I I I I - Table No. D-3, Results of Seismically-Induced Ground Settlement at BH-5 Soil Unit Weight (pc!): 113.00 Project: Newland/Tr 24182-1 &2 Groundwater Depth (feet): 20.00 Number: 96-81-420-30 Energy Ratio (%): 60.00 Date: 07/28/98 Peak Ground Acceleration (g): 0.60 By: HSUEH-HSIN(William) CHU Earthquake Magnitude: 7.50 Checked by: QSH Fill Thickness (feet): 7.00 ACTURAL SOIL THICKNESS PENETR CYCLIC VOLUMETRIC TOTAL BORING OEPTH CLASSIF. RESIST STRESS STRAIN SETTLEMENT SETTLEMENT (No.1 (feet) (inches) (N1160' RATIO (%) (inches) (inchesl BH-5 20.00 SP 48.00 37.0 0.400 0.00 0.00 BH-5 24.00 Cl BH-5 29.00 SP 60.00 16.0 0.630 1.90 1.14 BH-5 .34.00 SC 1.14 Table No. D-4, Results of Seismically-Induced Ground Settlement at BH-6 Soil Unit Weight (pcf): 113.00 Project: Newland/Tr 24182-1 &2 Groundwater Depth (feet): 20.00 Number: 96-81-420-30 Energy Ratio (%): 60.00 Date: 07/28/98 Peak Ground Acceleration (g): 0.60 By: HSUEH-HSIN(William) CHU Earthquake Magnitude: 7.50 Checked by: QSH Fill Thickness (feet): 7.00 ACTURAL SOIL THICKNESS PENETR CYCLIC VOLUMETRIC TOTAL BORING DEPTH CLASSIF. RESIST STRESS STRAIN SETTLEMENT SETTLEMENT (No.1 (feet) (inches) INl160' RATIO (%) {inches} (inches) BH-6 20.00 SP 48.00 16.0 0.400 1.80 0.86 BH-6 24.00 SP 60.00 17.0 0.500 1.70 1.02 BH-6 29.00 SP 60.00 13.0 0.631 2.00 1.20 BH-6 34.00 SP 3.08 01/