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3012530� 2� SOIL K 09 I�BN�MG 30� 2� SOIL K 09 SLADDEN ENGINEERING Soil Engineers PLAN CL.Ci<C NUMBER PcN Please use this Pim Ch&t !c Nan- heF (PCN) on cozrespondence vj to 4ens use in plan check 6782 Stanton Ave., Suite E, Buena Park, CA 90621 • (562) 8 -1 �523.G952 39 -725 Garand Ln., Suite G, Pah-n Desert, CA 92211 • (760) 772 -3893 GEOTECHNICAL INVESTIGATION TENTATIVE TRACT NO. 30125 SEC OF EISENHOWER DRIVE AND AVENUE 50 LA QUINTA, CALIFORNIA - Prepared By - Sladden Engineering 39 -725 Garand Lane, Suite G Palm Desert, California 92211 (760) 772 -3893 _ Sladden Engineering 6782 Stanton Ave., Suite E, Buena Park;-CA 90621 (562) 864 -4121 (714) 523 -0952 Fax(714)523-1369 39 -725 Garand Ln., Suite G, Palm Desert, CA 92211 (760) 772 -3893 Fax(760)772-3895 March 14, 2001 Project No. 544 -1058 01 -03 -106 R. C. Hobbs Company ' 55 -487 Southern Hills La Quinta, California 92253 ' Attention: Mr. Roger Hobbs Project: Tentative Tract No. 30125 ' Eisenhower Drive and Avenue 50 La Quinta, California ' Subject: Geotechnical Investigation Presented herewith is the report of our Geotechnical Investigation conducted at the site of the proposed residential development located on the southeast corner of Eisenhower Drive and Avenue 50 along the La ' Quinta Resort Dunes golf course in the City of La Quinta, California. The investigation was performed in order to provide recommendations for site preparation and to assist in foundation design for the proposed residential structures and the related site improvements. ' This report presents the results of our field investigation and laboratory testing along with conclusions and recommendations for foundation design and site preparation. This report completes our original scope of services as understood. We appreciate the opportunity to provide service to you on this project. If you have any questions ' regarding this report, please contact the undersigned Respectfully submitted, ' SLADDEN ENGINEERING OQ�oFESQ� ' Brett L. Ande on Principal Engineer CD No. C 45389 ' SER/pc Exp. 9 -30 -2002 sr CIVIL �P �rIF F CAof�¢� ' Copies: 6 /R. C. Hobbs Company Y ' GEOTECHNICAL INVESTIGATION TENTATIVE TRACT NO. 30125 EISENHOWER DRIVE AND AVENUE 50 ' LA QUINTA, CALIFORNIA ' March 14, 2001 TABLE OF CONTENTS ' INTRODUCTION ........................................................................................ ............................... 1 SCOPEOF WORK ...................................................................................... ............................... 1 PROJECTDESCRIPTION ....................................:..................................... ............................... 1 ' SUBSURFACE CONDITIONS ................................................................... ............................... 2 CONCLUSIONS AND RECOMMENDATIONS ....................................... ............................... 2 FoundationDesign ................................................................................. ............................... 3 Settlements ............................................................................................. ............................... 3 ' LateralDesign ........... ..... -..................................................................................................... 4 RetainingWalls ...................................................................................... ............................... 4 ' Expansive Soils ...................................................................................... ............................... ConcreteSlabs -on- Grade ............................:.......................................... ............................... 4 4 SolubleSulfates ..................................................................................... ............................... 4 ' Tentative Pavement Design ................................................................... ............................... Shrinkage and Subsidence ..................................................................... ............................... 5 5 GeneralSite Grading .............................................................................. ............................... 5 ' 1. Clearing and Grubbing ................................................................ ............................... 2. Preparation of Building and Foundation Areas ..........:................ ............................... 5 5 3. Preparation of Surfaces to Receive Compacted Fill .................... ............................... 6 4. Placement of Compacted Fill ...................................................... ............................... 6 ' 5. Preparation of Slab and Paving Areas ......................................... ............................... 6 6. Testing and Inspection ................................................................. ............................... 6 GENERAL.................................................................................................... ............................... 7 APPENDIX A - Site Plan and Boring Logs ' Field Exploration APPENDIX B - Laboratory Testing ' Laboratory Test Results APPENDIX C - 1997 UBC Seismic Design Criteria - Slodden Engineering ' . -- March 14, 2001 INTRODUCTION Project No. 544 -1058 01 -03 -106 This report presents the results of our Geotechnical Investigation performed in order to provide recommendations for site preparation and the design and construction of the foundations for the proposed residential structures. The project site is located on the southeast corner of Eisenhower Drive and Avenue 50 along the La Quinta Resort Dunes golf course in the City of La Quinta, California. The preliminary plans indicate that the proposed project will include 66 single family residences along with various associated site improvements. The associated site improvements are expected to include paved roadways, concrete driveways, walkways and patios, swimming pools, landscape areas and various underground utilities. SCOPE OF WORK The purpose of our investigation was to determine certain engineering characteristics of the near surface soils on the site in order to develop recommendations for foundation design and site preparation. Our investigation included field exploration, laboratory testing, engineering analysis and the preparation of this report. Evaluation of environmental issues or hazardous wastes was not within the scope of services provided. Our investigation was performed in accordance with contemporary geotechnical engineering principles and practice. We make no other warranty, either express or implied. PROJECT DESCRIPTION The project site is located on the southeast corner of Eisenhower Drive and Avenue 50 in the City of La Quinta, California. The preliminary plans indicate that the project will include 66 single family residences along with various associated site improvements. It is our understanding that the proposed residential structures will be of relatively lightweight wood -frame construction and will be supported by conventional shallow spread footings and concrete slabs on grade. The associated site improvements will include paved roadways, concrete walkways, patios and driveways, swimming pools, landscape areas and various underground utilities. The majority of the project site is presently vacant but the ^ sou thwestern portion of the site is presently being used as an employee parking lot for the nearby La Quinta Resort hotel. The subject site has been cleared and leveled most likely during the initial development of the adjacent La Quinta Resort Dunes - golf course. The southern portion of the site has been paved for use as a temporary parking lot for the La Quinta Resort and Club located to the west across Eisenhower Drive. The twelfth and thirteen holes of the Dunes course occupy the central and southwestern portions of the site. Three lakes exist along the golf course and residential lots are proposed along the lakes. The northern channel embankment for the La Quinta Evacuation Channel forms the south edge of the site. Eisenhower Drive and Avenue 50 are paved adjacent to the site. Based upon our previous experience with lightweight wood -frame structures, we expect that isolated column loads will be less than 30 kips and wall loading will be less than to 3.0 kips per linear foot. A grading plan prepared by MDS Consulting was utilized for our investigation. Grading is expected to include relatively minor cuts and fills to match the nearby elevations and to construct slightly elevated building pads to accommodate site drainage. This does not include removal and recompaction of the foundation bearing soils within the building areas. If the anticipated foundation loading or site grading varies substantially from that assumed; the recommendations included in this report should be reevaluated. Slodden Engineering March 14, 2001 -2- Project No. 544 -1058 01 -03 -106 SUBSURFACE CONDITIONS The near surface soils observed within our borings consist primarily of fine- grained silty sands and sandy clayey silts. The soils within the upper 2 to 3 feet consisted primarily of sandy clayey silts but fine grained silty sands were the most prominent soil type observed within our borings. The site soils were fairly consistent in composition but somewhat inconsistent in stratigraphy within our borings. In general, the site soils appeared somewhat loose throughout the depth of our borings but laboratory test results and sampler penetration resistance (as measured by field blowcounts), suggest that the site soils become somewhat firmer with depth. Relatively undisturbed samples indicated dry density varying from 83 to 107 pcf. The site soils were found to be somewhat dry throughout the upper portion of our borings but the deeper silt layers were wet. Moisture content varying from 0.5 to 40.9 percent was determined for the samples obtained. Laboratory classification testing indicates that the near surface soils consist primarily of a somewhat inconsistent combination of sandy clayey silts and very silty fine- grained sands. Expansion testing indicates that the majority of the near surface soils are considered non- expansive and fall within the "very low" expansion category in accordance with the Uniform Building Code classification system. Consolidation testing indicates that the near surface sandy silts and silty sands are 'potentially compressible and may be susceptible to hydroconsolidation and /or compression related settlements. Groundwater was not encountered within our borings that extended to a maximum depth of approximately 50 feet below the existing ground surface. Groundwater should not be a factor in foundation design or construction. CONCLUSIONS AND RECOMMENDATIONS Based upon our field and laboratory investigation, it is our opinion that the proposed residential -development is feasible from a soil mechanic's standpoint provided that the recommendations included in this report are considered in building foundation design and site preparation. Due to the somewhat loose and compressible conditions of the near surface soils,- remedial grading. including overexcavation and recompaction is recommended for the proposed building areas. —We recbmmend that remedial grading within the proposed building areas include overexcavation and recompaction of the primary foundation bearing soils. Specific recommendations for site preparation are presented in the Site Grading section of this report. Groundwater was not encountered within our borings that extended to a depth of approximately 50 feet below the existing ground surface. Due to the depth to groundwater, specific liquefaction analyses were not performed. Based upon the depth to groundwater the potential for liquefaction and the related surficial affects of liquefaction impacting the site are considered negligible. The site is located within an active seismic area of Southern California within approximately 11.8 kilometers of the San Andreas Fault system. Strong ground motion resulting from earthquake activity along the nearby San Andreas or San Jacinto fault systems is likely to impact the site during the anticipated lifetime of the structure. Structures should be designed by professionals familiar with the geologic and seismic setting of the site. As a minimum, structure design should conform to Uniform Building Code (UBC) requirements for Seismic Zone 4. Pertinent seismic design criteria as outlined in the 1997 UBC, is summarized in Appendix C of this report. Slcdden Engineering March 14, 2001 -3- Project No. 544 -1058 01-03-106 Caving did occur to varying degrees within each of our exploratory borings and the surface soils may be susceptible to caving within deeper excavations. All excavations should be constructed in accordance with the normal CalOSHA excavation criteria. On the basis of our observations of the materials encountered, we anticipate that the subsoils will conform to those described by CalOSHA as Type B or C. Soil conditions should be verified in the field by a "Competent person" employed by the Contractor. The majority of the surface soils encountered during our investigation were found to be generally non - expansive. Laboratory testing indicated an Expansion Index of 7 for the near surface sandy silts and 0 for the silty sands, which correspond with the "very low" expansion category in accordance with UBC Standard 18 -2. If imported soils are to be used during grading, they should have an Expansion Index of less than 20. The following recommendations present more detailed design criteria, which have been developed on the basis of our field and laboratory investigation. Foundation Design: The results of our investigation indicate that either conventional shallow continuous footings or isolated pad footings, that are supported upon properly compacted soils, may be expected to provide satisfactory support for the proposed residential structures. Overexcavation and recompaction should be performed as described in the Site Grading Section of this report. Footings should extend at least 12 inches beneath lowest adjacent grade. Isolated square or rectangular footings at least 2 feet square may be designed using an allowable bearing value of 1800 pounds per square foot. Continuous footings at least 12 inches wide may be designed using an allowable bearing value of 1500 pounds per square foot. Allowable increases of 200 psf for each additional 1 foot of width and 250 psf for each additional 6 inches of depth may be utilized if desired. The maximum allowable bearing pressure should be 2500 psf. The allowable bearing pressures are for dead and frequently applied live loads and may be increased by 1/3 to resist wind, seismic or other transient loading. Care should be taken to see that bearing soils are not.allowed to- become saturated from the ponding of rainwater or irrigation. Drainage from the building areas should be rapid and complete. The recommendations made in the preceding paragraphs are based on the assumption that all footings will be supported upon properly compacted soil. All grading shall be performed under the testing and inspection of the Soils Engineer or his representative. Prior to the placement of concrete, we recommend that the footing excavations be inspected in order to verify that they extend into compacted soil and are free of loose and disturbed materials. Settlements: Settlements may result from the anticipated foundation loads. These estimated ultimate settlements are calculated to be a maximum of 1 inch when using the recommended bearing values. As a practical matter, differential settlements between footings can be assumed as one -half of the total settlement. Slodden Engineering March 14, 2001 -4- Project No. 544 -1058 01 -03 -106 Lateral Design: Resistance to lateral loads may be provided by a combination of friction acting at the base of the slabs or foundations and passive earth pressure along the sides of the foundations. A coefficient of friction of 0.42 between soil and concrete may be used with dead load forces only. A passive earth pressure of 250 pounds per square foot, per foot of depth, may be used for the sides of footings, which are poured against properly compacted native soils. Passive earth pressure should be ignored within the upper 1 foot except where confined (such as beneath a floor slab). When used in combination, either the passive resistance or the coefficient of friction should be reduced by one - third. Retaining Walls: Retaining walls may be required to accomplish the proposed construction. Cantilever retaining walls may be designed using "active" pressures. Active pressures may be estimated using an equivalent fluid weight of 35 pcf for native backfill soils with level free - draining backfill conditions. For walls that are restrained, "at rest" pressures should be utilized in design. At rest pressures may be estimated using an equivalent fluid weight of 55 pcf for native backfill soils with level free - draining backfill conditions. Expansive Soils: Due to the prominence of non - expansive soils on the site, special expansive soil design criteria should not be necessary for the design of foundations and concrete slabs -on- grade. Because the mixing and blending associated with the recommended remedial grading may change expansion potential, final design criteria should be established by the Structural Engineer based upon post grading expansion test results. Concrete Slabs -on- Grade: All surfaces to receive concrete slabs -on -grade should be underlain by recompacted soils as described in the Site Grading Section of this report. Where slabs are to receive moisture sensitive floor coverings or where dampness of the floor slab is not desired, we recommend the use of an appropriate vapor barrier. Vapor barrieis should be protected by sand in order to reduce the possibility of puncture and to aid in obtaining uniform concrete curing. Reinforcement of slabs -on -grade in order to resist expansive soil pressures may not be required. However, reinforcement will have a beneficial effect in containing cracking due to concrete shrinkage. Temperature and shrinkage related cracking should be anticipated in all concrete slabs -on- grade. Slab reinforcement and the spacing of control joints should be determined by the Structural Engineer. Soluble Sulfates: The soluble sulfate concentrations of the surface soils were determined to be vary from 115 to 1,999 parts per million (ppm). The test results indicate soluble sulfate content in excess of the usual allowable limits for the use of Type II cement and the use of Type V cement or special sulfate resistant concrete mixes may be necessary. Appropriate concrete mix designs should be established based upon post grading test results. Slcdden Engineering March 14, 2001 -5- Project No. 544 -1058 01 -03 -106 Tentative Pavement Design: All paving should be. underlain by .a. minimum compacted fill thickness of 12 inches (excluding aggregate base). This may be performed as described in the Site Grading Section of this report. The following preliminary pavement sections are based upon a design R -Value of 50 and the recornmended pavement design section corresponds with the typical minimum pavement section as determined by the City of La Quinta. Onsite Roadways (Traffic Index= 6.0) Use 3.0 inches of asphalt on 4'.5 inches of Class 2 base material Aggregate base should conform to the requirements for Class 2 Aggregate base in Section 26 of CalTrans Standard Specifications, January 1992. Asphaltic concrete should conform to Section 39 of the CalTrans Standard Specifications. The recommended sections should be provided with a uniformly compacted subgrade and precise control of thickness and elevations during placement. Shrinkage and Subsidence: Volumetric shrinkage of the material, which is excavated and replaced as controlled compacted fill should be anticipated. We estimate that this shrinkage should vary from 20 to 25 percent. Subsidence of the surfaces which are scarified and compacted should be between 0.2 and 0.3 tenths of a foot. This will vary depending upon the type of equipment used, the moisture content of the soil at the time of grading and the actual degree of compaction attained. These values for shrinkage and subsidence are exclusive of losses, which will occur due to' tile stripping of the organic material from the site, the removal of deleterious materials and the removal of debris, trees and other subsurface obstructions. General Site Grading: All grading should be performed in accordance with the grading ordinance of the City of La Quinta, California. The following recommendations have been developed on the basis of our field and laboratory testing: - 1: Clearing --and Grubbing: Proper clearing of any existing — vegetation, debris, foundations; -slabs, pavements and underground utilities -will- be-very- important. All surfaces to receive compacted fill should be cleared of roots, vegetation, debris, and other unsuitable materials that should be removed from the site. Soils that are disturbed due to site clearing should be replaced as controlled compacted fill under the direction of the Soils Engineer. 2. Preparation of Building and Foundation Areas: Building areas should be overexcavated to a depth of at least 3 feet below existing grade or 3 feet below the bottom of the footings, whichever is deeper. The exposed surface should be scarified, moisture conditioned and compacted so that a minimum of 90 percent relative compaction is attained. Once deleterious materials are removed, the native material may be placed as controlled compacted fill. Overexcavation should be observed by a representative of Sladden Engineering and compaction should be verified by testing. Wet soils removed during excavation along the existing lakes should be dried back to near optimum moisture content or mixed with dry soils prior to placement as engineered fill material. The bottom of the excavations should be stable and unyielding prior to fill placement. In wet areas that are expected along the existing lakes, additional stabilization efforts may be necessary in isolated areas. S116dden Engineering March 14, 2001 -6- Project No. 544 -1058 01 -03 -106 3: Preparation of Surfaces to Receive Compacted Fill: Other areas to receive compacted fill should be brought to near optimum moisture content and compacted to a minimum of 90 percent relative compaction. 4. Placement of Compacted Fill: Fill materials consisting of on -site soils or approved imported granular soils, should be spread in thin lifts, and compacted at near optimum moisture content to a minimum of 90 percent relative compaction. Imported material shall have an Expansion Index not exceeding 20. The contractor shall notify the Soils Engineer at least 48 hours in advance of importing soils in order to provide sufficient time for the proper evaluation of proposed import materials. The contractor shall be responsible for delivering material to the site, which comply with the project specifications. Approval by the Soils Engineer will be based upon material delivered to the site and not the preliminary evaluation of import sources. Our observations of the material encountered during our investigation indicate that compaction will be most readily obtained by means of heavy rubber - wheeled equipment and /or vibratory compactors. 5. Preparation of Slab and Paving Areas: All surfaces to receive asphalt concrete paving or concrete slabs -on- grade, should be underlain by a minimum compacted fill thickness of 12 inches. This may be accomplished by a combination of scarification and recompaction of the surface soils and placement of the fill material as controlled compacted fill. Compaction of the slab and pavement areas should be to a minimurn of 90 percent relative compaction. 6. Testing and Inspection: During grading tests and observations should be performed by the Soils Engineer or his representative in order to verify that the grading is being performed in accordance with the project specifications. Field density testing shall be - -- performed in accordance with acceptable ASTM test methods-.-T-he-min imum acceptable - - - &gree of compaction should be 90 percent of the maximum dry- density as obtained by. the - ASTM D1557 -91 test method. Where testing indicates insufficient density, additional- compactive effort shall be applied until retesting indicates satisfactory compaction. Siddden Engineering March 14, 2001 -7- Project No. 544 -1058 01 -03 -106 GENERAL The findings and recommendations presented in this report are based upon an interpolation of the soil conditions between the exploratory boring locations and extrapolation of these conditions throughout the proposed building area. Should conditions encountered during grading appear different than those indicated in this report, this office should be notified. This report is considered to be applicable for use by R. C. Hobbs Company for the specific site and project described herein. The use of this report by other parties or for other projects is not authorized. The recommendations of this report are contingent upon monitoring of the grading operation by a representative of Sladden Engineering. All recommendations are considered to be tentative pending our review of the grading operation and additional testing, if indicated. If others are employed to perform any soil testing, this office should be notified prior to such testing in order to coordinate any required site visits by our representative and to assure indemnification of Sladden Engineering. We recommend that a pre job conference be held on the site prior to the initiation of site grading. The purpose of this meeting will be to assure a complete understanding of the recommendations presented in this report as they apply to the actual grading performed. —Sladden Engineering v APPENDIX A Site Plan Boring Logs APPENDIX A FIELD EXPLORATION For our field investigation, 8 exploratory borings were excavated on February 26 and March 2, 2001, using a truck mounted hollow stem auger rig (Mobile B61) in the approximate locations indicated on the site plan included in this appendix. Continuous logs of the materials encountered were prepared on the site by a representative of Sladden Engineering. The boring logs are included in this appendix. Representative undisturbed samples were obtained within our borings by driving a thin - walled steel penetration sampler (California split spoon sampler) or a Standard Penetration Test (SPT) sampler with a 140 pound hammer dropping approximately 30 inches (ASTM D1586). The number of blows required to drive the samplers 18 inches was recorded in 6 inch increments and blowcounts are indicated on the boring logs. The California samplers are 3.0 inches in diameter, carrying brass sample rings having inner diameters of 2.5 inches. The standard penetration samplers are 2.0 inches in diameter with an inner diameter of 1.5 inches. Undisturbed samples were removed from the sampler and placed in moisture sealed containers in order to preserve the natural soil moisture content. Bulk samples were obtained from the excavation spoils and samples were then transported to our laboratory for further observations and testing. Y Slodden Engineering I� - 1' � ••.'�• lIq AVENUE 50 . 39 30. ' 4 LOGY'• ._.... .:�• -.__ —� _.. - - - ___ - - 29` io „ 12 40 J.. �� .�� fir'' �`..�.• . `� .•�- -, O > CID— Q�� Q• ' /cb R E M b r /. _' � •� ��.,� .... W .I r: CPII 3E 21 o PARCEL MAP'INa 20334 W .6 PAM 109129 -31 PA 2 ', LOT i ► MAP M0. �a !I - ••' •• 1 i<IlA eMOH P1AD. 1E9/29.3,SZ -? oLF?NOW1 fi96WOn EVACUATION ow++a O + Approximate Boring Locations z Boring Location Map Proposed Residential.Development' Tentative Tract 30125 Avenue 50 & Eisenhower'Drive La Quinta, California Sladden Engineering:_: °;. DATE: 3 -19 -01 JOB NO.: 544` - 10.58- MILES i AVENUE W 48th AVENUE N . F- PROJECT w w � SITE o N N 50th AVENUE w = 0 3 W o w � w W 52th AVENUE 3 0 x z W N W_._ ..._. ._ 54th AVENUE Tentative Tract 30125 Eisenhower Drive &Avenue 50 / La Quinta, California Date: 2 -26 -01 BorinLr No. l Job No.: 544 -1058 o � DESCRIPTION q � � � REMARKS A � r! U al r° � 5 -Z o U 0 Silty Sand: Brown, SM _ _ very silty, fine grained _ 5 5/5/10 Silty Sand: Brown, SM 103 5.8 ___ - fine grained io 4/5/7 99 3.1 --- 15 7/7/10 Silty Sand: Brown, SM 91 5.3 ___ very silty, fine grained 20 5/5/5 91 5.3 79 25 7/7/10 Silty Clay: Brown CL 97 18.3 - -- 4/4/5 - -- 40.9 - -- 35 4/417 - -- 31.6 40 5/5/5 - -- 40.0 45 5/5/8 Sandy Silt: Brown, ML' ___ 10.5 ___ - very sandy 50 5/5/5 Silty Clay: Brown CL - -- 28.2 - Total Depth = 51.5' ' -Recovered Sample No Bedrock - Note: The stratification lines No Groundwater 55 If Standard Penetration represent the approximate boundaries between.the soil types; - -. - Sample the transitions may be gradual. Tentative Tract 30125 Eisenhower Drive & Avenue 50 / La Quinta, California Date: 3 -2 -01 Boring No. 2 Job No.: 544 -1058 o DESCRIPTION q 0 0 REMARKS A ri U M M o U ° Silty Sand: Brown, SM _ very silty, fine grained 5 5/5/8 Sand: Grey brown, SP /SM 95 2.0 - -- - slightly silty, fine grained 10 4/5/7 Sandy Silt: Brown, ML 83 2.0 - -- very sandy 15 8/10/15 Silty Clay: Brown CL 90 22.7 - -- Total Depth = 16.5' _ - Recovered Sample No Bedrock 20 ®Standard Penetration No Groundwater Sample 25 35 40 45 50 Note: The stratification lines 55 represent the approximate ' boundaries between the soil types;. the transitions may be gradual. Tentative Tract 30125 Eisenhower Drive &Avenue 50 / La Quinta, California Date: 3 -2 -01 BorinLr No. 4 Job No.: 544 -1058 � a) o � DESCRIPTION q � � o REMARKS A � rn Cg PQ r° o �� U o _ Sandy Silt: Brown, ML _ very sandy 5 7/8/10 Clayey Silt: Brown, ML - -- 6.0 - -- - slightly sandy 10 5/5/7 Silty Sand: Brown, SM 92 1.5 89 - fine grained 15 _ 5/5/5 Clayey Silt: Brown, sandy ML 95 4.1 - -- 20 Silty Sand: Brown, SM _ 6/7/7 very silty, fine rained 94 3.5 ' 82 _ Total Depth = 21.5' - -Recovered Sample No Bedrock ®Disturbed Sample No Groundwater 25 35 40 45 50 _ Note: The stratification lines 56 represent the approximate boundaries between the soil types; the transitions may be gradual. Tentative Tract 30125 Eisenhower Drive & Avenue 50 / La Quinta, California Date: 3 -2 -01 Borin No. 5 Job No.: 544 -1058 � o > DESCRIPTION q c 0 Cz REMARKS 04 sue, o t A c U Pal c° �D 19 o. U 0 Sandy Silt: Brown, ML very sandy 5 4/4/6 " " 91 4.5 - -- 10 5/8/8 Silty Sand: Brown, SM 101 2.0 - -- fine grained 15 NM5/7/8 Silty Clay: Brown, CL 96 19.1 -__ slightly sandy 20 Silty Sand: Brown, SM 4/6/8 very silty, fine rained 93 6.0 Total Depth = 21.5' - Recovered Sample No Bedrock " No Groundwater 25 30 - -- - - - - 35 40 45 A 50 _ Note: The stratification lines 55 represent the approximate boundaries between the soil types; - the transitions may be gradual. Tentative Tract 30125 Eisenhower Drive & Avenue 50 / La Quinta, California Date: 3 -2 -01 Borine No. 6 Job No.: 544 -1058 a� > ° o m DESCRIPTION q REMARKS 4a `~ o� A �! U Pal U) ,� o U 0 _ Silty Sand: Brown, SM very silty, fine grained 5 7/8/8 96 2.0 - -- 3/3/5 �� - - .5 - -- 15 4/5/5 Silty Sand: Brown, SM - -- 2.0 - -- " fine grained 20 5/5/8 Sil ty Clay: Brown CL 9.3 Total Depth = 21.5' - Recovered Sample No Bedrock - No Groundwater mStandard Penetration - Sample 30 - — - -- - - - -- -- 35 40 45 50 . Note: The stratification lines 55 represent the approximate boundaries between the soil types; the transitions may be gradual. Tentative Tract 30125 Eisenhower Drive & Avenue 50 / La Quinta, California Date: 3 -2 -01 BorinLY No. 7 Job No.: 544 -1058 o DESCRIPTION �� REMARKS �w 0 0 o A rn U W 0 CO Q q15 o U 0 Silty Sand: Brown, SM _ very silty, fine grained 5 7/15/20 Silty Sand: Brown, SM 99 0.5 - -- fine grained 10 5/10/10 Clayey Silt: Brown, sandy ML 93 6.0 - -- 15 8/10/13 Silty Sand: Brown, SM _ -- 3.0 - -- - fine grained Total Depth = 16.5' - Recovered Sample No Bedrock 20 No Groundwater Standard Penetration Sample 25 30 - - - -- - - - - 35 40 45 50 Note: The stratification lines 55 represent the approximate boundaries between the soil types; the transitions may be gradual. . Tentative Tract 30125 Eisenhower Drive & Avenue 50 / La Quinta, California Date: 3 -2 -01 BorinLy No. 8 Job No.: 544 -1058 o w 0 DESCRIPTION A 0 o a REMARKS a . a A r% U Pal t° U � a 0 _ Silty Sand: Brown, SM very silty, fine grained 5 5/5/10 Sandy Silt: Brown, ML 96 2.0 ___ Interbedded slightly silty _ very sandy sand layer 4" thick 10 5/5/7 Clayey Silt: Brown, ML 97 8.7 - -- Interbedded fine grained - slightly sandy sand layer 3" thick 15 3/3/4 Silty Sand: Brown, SM -_- 5.3 - -- - fine grained 20 3/4/5 Clayey Silt: Brown, sandy ML --- 21.2 - -- Total Depth = 21.5' - Recovered Sample No Bedrock No Groundwater 25 JU Standard Penetration - Sample 30 - - - - -- -- - - -- -- - 35 40 - 1 45 50 - Note: The stratification lines 55 represent the approximate boundaries between the soil types; - - the transitions may be gradual. . APPENDIX B LABORATORY TESTING Representative bulk and relatively undisturbed soil samples were obtained in the field and returned to our laboratory for additional observations and testing. Laboratory testing was generally performed in two phases. The first phase consisted of testing in order to determine the compaction of the existing natural soil and the general engineering classifications of the soils underlying the site. This testing was performed in order to estimate the engineering characteristics of the soil and to serve as a basis for selecting samples for the second phase of testing. The second phase consisted of soil mechanics testing. This testing including consolidation, shear strength and expansion testing was performed in order to provide a means of developing specific design recommendations based on the mechanical properties of the soil. CLASSIFICATION AND COMPACTION TESTING Unit Weight and Moisture Content Determinations: Each undisturbed sample was weighed and measured in order to determine its unit weight. A small portion of each sample was then subjected to testing in order to determine its moisture content. This was used in order to determine the dry density of the soil in its natural condition. The results of this testing are shown on the Boring Logs. Maximum Density - Optimum Moisture Determinations: Representative soil types were selected for maximum density determinations. This testing was performed in accordance with the ASTM Standard D1557 -91, Test Method A. The results of this testing are presented graphically in this appendix. The maximum densities are compared to the field densities of the soil in order to determine the existing relative compaction to the soil. This is shown on the Boring Logs, and is useful in estimating the strength and compressibility of the soil:. Classification Testing: Soil samples were selected for classification testing. This testing consists of mechanical grain size analyses and Atterberg Limits determinations. These provide information for .developing classifications for the soil in accordance with the Unified Classification System. This classification system categorizes the soil into groups having similar engineering characteristics. The results of this testing are -very useful in detecting variations in the soils and-in selecting samples for further testing. - - - SOIL MECHANIC'S TESTING Direct Shear Testing: Two bulk samples were selected for Direct Shear Testing. This testing measures the shear strength of the soil under various normal pressures and is used in developing parameters for foundation design and lateral design. Testing was performed using recompacted test specimens, which were saturated prior to testing. Testing was performed using a strain controlled test apparatus with normal pressures ranging from 800 to 2300 pounds per square foot. Expansion Testing: Two bulk samples were selected for Expansion testing. Expansion testing was performed in accordance with the UBC Standard 18 -2. This testing consists of remolding 4 -inch diameter by 1 -inch thick test specimens to a moisture content and dry density corresponding to approximately 50 percent saturation. The samples are subjected to a surcharge of 144 pounds per square foot and allowed to reach equilibrium. At that point the specimens are inundated with distilled water. The linear expansion is then measured until complete. Consolidation Testing: Six relatively undisturbed samples were selected for consolidation testing. For this testing one -inch thick test specimens are subjected to vertical loads varying from 575 psf to 11520 psf applied progressively. The consolidation at each load increment was recorded prior to placement of each subsequent load. The specimens were saturated at the 575 psf or 720 psf load increment. Slodden Engineering Job No.: 544 -1058 100 ' I I I 9 10 11 12 13 14 Moisture Content ( %) a METHOD OF COMPACTION ASTM D- 1557 -91, METHOD A OR C BORING MAXIMUM UNIT WEIGHT OPTIMUM MOISTURE CONTENT 2 @0 -5' 103 11.4 MAXIMUM DENSITY - OPTIMUM MOISTURE CURVE I 116 115 ¢ 114 C d A 113 A 112 111 4- 10 11 12 13 Moisture Content ( %) METHOD OF COMPACTION ASTM D- 1557 -91, METHOD A OR C BORING MAXIMUM UNIT WEIGHT 3 @1 -5' 115 Job No.: 544 -1058 14 15 OPTIMUM MOISTURE CONTENT 12.4 MAXIMUM DENSITY - OPTIMUM MOISTURE CURVE U-- - DIRECT SHEAR TEST 1.8 1.6 1.4 1.2 1.0 .8 .6 I � , .4 .2 00 .2 .4 .6 .8 1.0 1.2 1.4 1.6 1.8 0 = 30° c 150 psf where 0 = Shear Angle c = Cohesion Boring 2 @0 -5' Proposed Residential Development Tentative Tract 30125 Avenue 50 & Eisenhower Drive La Quinta, California Sladden Engineering DATE: 3 -18 -01 JOB NO.: 544 -1058 I � , 1.8 1.6 1.4 1.2 1.0 .8 .6 .4 .2 1 1 DIRECT SHEAR TEST .2 .4 .6 .8 1.0 1.2 1.4 1.6 1.8 0 =28° c = 200 psf where 0 =Shear Angle c = Cohesion Boring 3 @ 1 - 5' Proposed Residential Development Tentative Tract 30125 Avenue 50 & Eisenhower Drive La Quinta, California Sladden Engineering DATE: 3 -18 -01 JOB NO.: 544 -1058 I I 1 I I I 1 1 1 1 I 1 1 I I I I 1 I I I 1 1 1 i t 1 1 I 1 I 1 I t I I 1 1 t I 1 1 I 1 1 , 1 1 I I 1 I i t ' 1 I I I 1 � I I I 1 I I 1 I I I 1 i I 1 I 1 1 1 I I 1 I I I 1 1 t I I I 1 01 —I I I I 1 1 I 1 00, I I I I 1 I I 1 1 1 I I 1 1 1 I I I I I I I 1 I I 1 I I 1 .2 .4 .6 .8 1.0 1.2 1.4 1.6 1.8 0 =28° c = 200 psf where 0 =Shear Angle c = Cohesion Boring 3 @ 1 - 5' Proposed Residential Development Tentative Tract 30125 Avenue 50 & Eisenhower Drive La Quinta, California Sladden Engineering DATE: 3 -18 -01 JOB NO.: 544 -1058 Pressure in KIPS per Square Foot 0.000 0.720 2.880 5.760 z z 0.0 ffec�c@iul IT-Ti z )EMer Z4= L .01 z Z- .02 577 Rebound .03 z Cd .04 + z a. .05—� .06 0 .0 z z z z 7 z z z z + z o .07 CD 0 7- 0 .08 z z z z 7: z ..09 z Z 0.1 Z z z 7 z!= z z .12 z z t Z .13 rive & Avenue 50 La Quinta Eisenhower Eis hower Drive Consolidation Diagram 1 @ 5' EDate:3/18/01 10 SLADDEN ENGINEERING lJob No.: 544-1058 ` Pressure in KIPS per Square Foot 0.000 0.720 2.880 5.760 E Eisenhower Drive & Avenue 50 La Quinta isenhower Dr, Consolidation Diagram B 13 EDate:3/18/01 SLADDEN ENGINEERING 11 /01 -1058 0.= I Job No.: 544 =j Pressure in KIPS per Square Foot 0.000 .575 2.300 4.600 0.0 Z Effec--t=5f:Addi-7p—g F -W-a-t e f: Z .01 .02 Z Z z Z- .03 z ==�z z .04 7 z Z z z z C .05 Z Z r .06 z 0 41 Et co 0 .07 EEE E EE E EE� E Ej z I C.) .08 z ..09 z z z 0.1 z Z z z z .12 z Z .13 Z I Eisenhower Drive & Avenue 50 La Quinta E' senhower Dr Consolidation Diagram Boring 3 @ 10' EDate:3/18/01 I SLADDEN ENGINEERING 1"05 rJob No.: 54J48 t /I /Oj -1058 Pressure in KIPS per Square Foot 0.000 .575 2.300 4.600 0.0 =F-- z I [Z Z: Effee-V4 Mdq!� z z z z er- Z: .01 z z z I z .02 z -Z -Z .03 z =�Rebotffi-d 'z .04 Cl) c .05 + z .06 :7 x z z 7: z z 0 0 .07 0 Z. :1 I z z z Z .08 z z Z 7 z z .09 z z 0.1 ==4z z z� z 74= z z z z z 7 1 - 7w .12 z 7 Z Z: Z: z .13 7: z z z z Z Eisenhower Drive & Avenue 50 La Quinta E s hower Dn Consolidation Diagram Boring 3 @ 15' EDate:3/18101 SLADDEN ENGINEERING 11 101 I Job No.: 544 -1058 0.0 .01 0.000 z z 7z z Pressure in KIPS per Square Foot .575 2.300 E ffia5f Add ng z z =lWa t er - \S 4.600 z Z Z .02 :m 7. z .03 z z .04 Z z z Z .05 Z Z L .06 41 z q= Z o .07 z z -- - — - ----------- - - z I z .08 -Z z ..09 0.1 z .12 z z =--EEr Z: z .13 7- z z 7 Z 7 7 7 7 Eisenhower Drive & Avenue 50 La Quinta Ei s hower Dr Consolidation Diagram Boring 7 @ 10' EDate:3/18/011 SLADDEN ENGINEERING I Job No.: 544 -1058 0.0 .0, .02 0.000 z z Z - - - - - - - -- -------------- 77= Pressure in KIPS per Square Foot .575 2.300 z — 7- - - - - - - - :E z z X Z:� z Effdd�— Ad 9- 4.600 z z Z 7 7 .03 R-el�otihd=� .04 z .05 — - — - — - — - z i 9 .06 z z co o .07 U) 0 .08 z- — - — - — - z z z z .09 0.1 z --L: z z Z: .12 I Z z: .13 — - — - — - — - c z z E Eisenhower Drive & Avenue 50 La Quinta i senhower Dr Consolidation Diagram Boring 8 @ 5' EDate:3/18/01rJob L S SLADDEN ENGINEERING t . -1058 . 11 /03 No.: 544 I I Project No.: 544 -1058 R A IN' S I Z E, M M ACCUMULATION CURVE F I N E COARSE DATE : CLAY . }. SILT S AND--�—SANDVI GRAVEL I US STANDARD SIEVES - ON Y n V N V 7 Rnrincr t rnl S� 0 0 0 0 0 0 0, IC Z 9 I e V) 7 Q a a W 3 2 W I a PARTICLE SIZE, MM l CLAY-- = -- SILT E I N E COARSE SAND --�-- SAND- -- GRAVEL US STANDARD S.I E V ES --• N iV Q e V �j Z Z2 Q Boring 10' v 0 0 0 p. u ry g Z z z 7 7 7 7- Q$ O CS 0 0 PARTICLE 517-E, MM Slodden Engineering Project No.: 544 -1058 GRAIN S I 'Z E, M M ACCUMULATION CURVE F I NE COARSE D.�TE —CLAY SILT SAND _ • SAND S— IEGRAVEL- US VES- STANDARD N$ n 0 0 z Rnrma ?nn N 0 0 0 0 0 n 0 6 - z? 0 IC Z G � a 7 Q a a Z W 3 w 2 W I E PARTICLE SIZE, MM • MIN W,/ lslimiSmo11mimill mllmm:,FA iniimlmmmiimlm.ol MEN • EmsI��I��I��I�I�� • ��1� ■ �INS lislimimmo1 =lMlIll • IOS�11�11�1��1 • �mmmm��I��I��II�1��1 • • • • • • • • • • • • • • • PARTICLE SIZE, MM Slodden Engineering �• E Ell o on ME PARTICLE SIZE, MM Slodden Engineering ANAHEIM TEST LABORATORY 3008 S. ORANGE AVENUE SANTA ANA. CALIFORNIA 92707 PHONE (714) 549 -7267 TO SLADDFN ENGINE.ERTNG: 6782 STANTON-AVE. SUITE R BUFNA PARK; CA. 9.0621 ATTN: BRETT ANDERSON PROJECT: # 544 -1058 F.TSENNOWER A AVE. 50. ANALYTICAL REPORT SOLUBLE SULFATES per CA_ 417, N1 r3ULK -H -2 - @" 0 -5' 115 ppm M2 HULK 11 -3 @ 1 -5' 1,999 ppm DATE: 3/13/01 DO. No VERBAL tShipoet No. Lab No B 8010 1- 2 Soecilicclion. Malei-ol.. SOIL CTFULI' SUS TIED rl �i p.2 APPENDIX C 1997 UBC Seismic Design Criteria Stcdden Engineering 1997 UNIFORM BUILDING CODE INFORMATION The International Conference of Building Officials 1997 Uniform Building Code contains substantial revisions and additions to the earthquake engineering section summarized in Chapter 16. Concepts contained in the 1997 code that will likely be relevant to construction of the proposed residential structures are summarized below. Ground shaking is expected to be the primary hazard most likely to affect the site, based upon proximity to significant faults capable of generating large earthquakes. Major fault zones considered to be most likely to create strong ground shaking at the site are listed below. Based on our field observations and understanding of local geologic conditions, the soil profile type judged applicable to this site is S ►�, generally described as stiff or dense soil. The site is located within UBC Seismic Zone 4. The following table presents additional coefficients and factors relevant to seismic mitigation for new construction upon adoption of the 1997 code. r Slcdden Engineering Fault Zone Approximate Distance From Site Fault Type 1997 UBC San Andreas 12 km A I San Jacinto 30 km A Near - Source Near - Source Seismic Seismic Seismic Acceleration •Velocity .Coefficient Coefficient Source Factor, Na Factor, N,. Ca C„ San Andreas 1.0 1.15 0.44 Na 0.64 N„ San Jacinto 1.0 1.0 0.44 N� 0.64 N,,