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Home My WebLink AboutCDP 2019-0015; SAUER RESIDENCE; LIMITED GEOTECHNICAL INVESTIGATION - PROPOSED NEW BUILDING ADDITIONS AND REAR YARD SITE IMPROVEMENTS, 2465 JEFFERSON STREET, CARLSBAD, CALIFORNIA; 2017-10-02LIMITED GEOTECHNICAL INVESTIGATION PROPOSED NEW BUILDING ADDITIONS AND REAR YARD SITE IMPROVEMENTS 2465 JEFFERSON STREET CARLSBAD, CALIFORNIA October 2, 2017 Prepared For: Carefree Holdings, LLC Mr. Chris Sauer 2465 Jefferson Street Carlsbad, California 92008 Prepared By: SM§ Geotechnical Solutions, Inc. 5931 Sea Lion Place, Suite 109 Carlsbad, California 92010 Project No. GI-17-09-139 TABLE OF CONTENTS PAGE I. INTRODUCTION ...................................................... 1 II. SITE DESCRIPTION ......................................•............ 1 III. PROPOSED BUILDING ADDITIONS AND IMPROVEMENTS ............... 2 IV. SITE INVESTIGATION ................................................. 3 V. GEOLOGIC CONDITIONS .............................................. 3 A. Earth Materials ..................................................... 4 B. Groundwater and Surface Drainage .................................... 4 C. Slope Stability ....................................................... 4 D. Faults/Seismicity .................................................... 5 E. Seismic Ground Motion Values ........................................ 7 F. Geologic Hazards .................................................... 7 G. Laboratory Tests and Test Results ...................................... 7 VI. SITE CORROSION ASSESSMENT ...................................... 11 VII. CONCLUSIONS ...................................................... 11 VIII. RECOMMENDATIONS ................................................ 14 A. Remedial Grading and Earthworks .................................... 14 B. Footings and Slab-on-Grade Foundations ............................... 19 C. Underpinning Grade Beam ........................................... 21 D. Soil Design Parameters .............................................. 21 E. Swimming Pool Construction ......................................... 23 F. Exterior Concrete Slabs, Pool Decking, Patios and Flatwork ............... 25 G. General Recommendations ........................................... 26 IX. GEOTECHNICAL ENGINEER OF RECORD (GER) ....................... 28 X. LIMITATIONS .........................•............•....•........... 28 FIGURES Regional Index Map ........................................................... 1 Geotechnical Map ............................................................ 2 Test Pit and Boring Logs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 -6 Geologic Cross-Section ........................................................ 7 Fault-Epicenter Map .......................................................... 8 Sieve Analysis ................................................................ 9 Typical Isolation Joints and Re-Entrant Corner Reinforcement ..................... 10 Typical Grade Beam Detail for Underpinning Wall Footings ......................•. 11 Typical Swimming Pool Construction Concept ................................... 12 Typical Retaining Wall Back Drainage .......................................... 13 APPENDIX Project No. GI-17-09-139 October 2, 2017 Carefree Holdings, LLC Mr. Chris Sauer 2465 Jefferson Street Carlsbad, California 92008 §.ff§ GEOTECHNICAL SOLUTIONS, INC. Consulting Geotechnical Engineers & Geologists 5931 Sea Lion Place, Suite 109 Carlsbad, California 92010 760-602-7815 smsgeosol.inc@gmail.com LIMITED GEOTECHNICALINVESTIGATION, PROPOSED NEW BUILDING ADDITIONS AND REAR SITE IMPROVEMENTS, 2465 JEFFERSON STREET, CARLSBAD, CALIFORNIA Pursuant to your request, 6.MS Geotechnical Solutions Inc. has completed the attached Limited Geotechnical Investigation report for the proposed new building additions and rear yard site improvements at the above-referenced property. The following report summarizes the results of our subsurface exploratory boring and test pit excavations, field in-situ testing and sampling, laboratory testing, engineering analysis and provides conclusions and recommendations for the proposed new building addition and site improvements, as understood. From a geotechnical engineering standpoint, it is our opinion that construction of the planned new building additions and site improvements substantially as proposed, is feasible provided the recommendations presented in this report are incorporated into the design and construction of the project. The conclusions and recommendations provided in this study are consistent with the site indicated geotechnical conditions and are intended to aid in preparation of final construction plans and allow more accurate estimates of associated costs. If you have any questions or need clarification, please do not hesitate to contact this office. Reference to our Project No. GI-17-09-139 will help to expedite our response to your inquiries. We appreciate this opportunity to be of service to you. LIMITED GEOTECHNICAL INVESTIGATION PROPOSED NEW BUILDING ADDITIONS AND REAR SITE IMPROVEMENTS 2465 JEFFERSON STREET CARLSBAD, CALIFORNIA I. INTRODUCTION The property investigated herein consists of an existing single-family residential development located at the referenced address within the limits of the City of Carlsbad. The project location is shown on a Regional Index Map attached to this report as Figure 1. The approximate study site coordinates are 33.1697°N latitude and -l 17.3488°W longitude. We understand that the existing building will be expanded with first and second floor additions, and the rear yard will receive new improvements, including a swimming pool. Consequently, the purpose of this investigation was to evaluate geotechnical conditions at the new building addition and site improvement locations to evaluate their influence upon the planned new construction. Exploratory borehole drilling and a test pit excavation, in-situ testing and soil sampling, laboratory testing, and engineering analysis were among the activities conducted in conjunction with this effort which has resulted in the geotechnical planning and foundation recommendations presented herein. The scope of this report is limited to those areas planned for new building additions and site improvements as specifically delineated in this report. Other areas of the property and existing structures/improvements, not investigated, are beyond the scope of this report. II. SITE DESCRIPTION A Geotechnical Map, reproduced from the project String Line Exhibit (Sheet A 1 ), showing existing site conditions and the proposed new building additions/rear yard improvements at the study property, is attached herein as Figure 2. In general, the project property is located in a coastal residential neighborhood, within the City of Carlsbad, on the eastern flank of a hillside along the Buena Vista Lagoon. Jefferson Street bounds the property along the eastern margin, while existing neighboring residential developments occur north and south. The existing nearly level building pad at the property is currently occupied by an older single-family building with associated structures and improvements. The level pad surfaces in the rear yard are marked with a minor graded slope which gives way to nearly flat areas that terminate at an existing retaining wall. The retaining wall marks the top of the western perimeter descending slope. The descending hillside is a large graded slope with drainage terraces, which descends nearly 40 feet at 2: 1 (to locally steeper) gradients to natural hillside terrain and the Buena Vista Lagoon embankment below. Rear slope areas are heavily overgrown with trees and shrubs. Evidence of slope instability is not readily apparent. Current site drainage is considered poor to marginal overall. Surface drainage at the eastern portions of the property appears to locally pond in front yard areas or flow toward Jefferson Street, while western rear yard drainage appears to flow Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page2 toward the retaining wall along the top of descending slope. Excessive scouring or erosion is not in evidence. The original residence at the property was apparently constructed more than 25 years ago. Subsequent additions and modifications were supposedly carried out since the original development. Engineering, construction, inspection, and testing records pertaining to the original site development and subsequent building additions and modifications are not available for our review. However, our project document search located a copy of a more recent geotechnical report for the neighboring property (2435/2433 Jefferson Street): Updated Preliminary Geotechnical Evaluation APN 155-140-41 Carlsbad, San Diego County, California Prepared by Geosoils, Inc. W.O. 5763-A-SC, dated October 15, 2008 The referenced report is on file with our firm and a copy can be obtained upon request. III. PROPOSED BUILDING ADDITIONS AND IMPROVEMENTS Proposed building additions and rear yard site improvements are depicted on enclosed Geotechnical Map Figure 2. As shown, the main building is planned for first floor expansion and second floor additions. First floor building expansion will include a new attached 2-car tandem garage on the southeast comer, a music room/ bedroom 2 on the southwest comer, and a dining room pop-out at the northwest comer. Second floor additions will include a home gym above the existing garage on the northeast corner, a home theater above the new garage on the southeast corner, an office with a terrace, bedroom/bathroom 3, and associated building modifications. The back yard improvements will include a new pool with a disappearing edge and a spa on the western pad margin, east of the existing retaining wall that marks the top of the rear descending slope. Associated improvements will include pool decking, patio, stairs, and landscaping features. The project property is subject to string-line setback requirements, as shown on the pertinent plans, and although the string-line may be located on the west of the existing retaining wall, the City Hillside Development Ordinance does not permit development on the perimeter downhill slopes. Consequently, the new pool, deck, and patio should be located east of the existing retaining wall. Based on current plans, the existing retaining wall will mostly remain in-place, except where removed and replaced as a part of the new pool construction, subject to approval by the City of Carlsbad. In addition, the City of Carlsbad also requires a building setback from the top of slope. The setback is an imaginary line measured at 0.7:1 gradients (horizontal to vertical) from the top of slope. The indicated imaginary building setback line is shown on Figure 2. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page3 Significant cut-fill grading and ground modifications are not anticipated with the new building additions and pool final grades established at or near existing grades. Earthwork operations are . expected to mostly consist of minor to modest remedial bearing and subgrade soil preparation efforts, pool excavations approaching 4 feet deep maximum, and minor filling for achieving rear patio grades. Detailed foundation and building plans are also not yet available. However, the use of a conventional wood-frame with exterior stucco type construction supported on shallow continuous strip and spread pad footings, and/or grade beam type foundations with slab-on-grade floors is anticipated. In order to minimize ground disturbance, facilitate construction near the top of rear descending slope, and reduce remedial grading earthwork quantities, the new swimming pool and spa are recommended for support on a structural concrete platform which spans over cast-in-place (CIP) drilled caissons. IV. SITE INVESTIGATION Subsurface conditions at the property were substantially determined by the excavation of three exploratory test borings drilled with a limited access tri-pod mounted rotary beaver drill rig, and one hand-dug test pit near the eastern building perimeter foundation. The purpose of our exploratory test pit excavation was to evaluate the immediate foundation bearing soils and locally expose existing building foundations to measure footing depth and width. Based on our limited exposures, the existing foundation was measured approximately 9 inches deep below the adjacent ground surface (BGS) and roughly 12 inches wide. Test pit and boring excavations were logged by our project geologist, who also directed in-situ testing and retained representative subsoil samples at frequent intervals for subsequent laboratory testing. Test pit and boring locations are shown on the attached Figure 2. Logs of the test pit and borings are enclosed with this report as Figures 3 through 6. The subsurface profile based on the exploratory test excavations is illustrated in the enclosed Geologic Cross-Section, Figure 7. Laboratory test results and engineering properties of selected soil samples are summarized in a following section. V. GEOTECHNICAL CONDITIONS The study property is mostly characterized by a nearly level graded building surface which terminates along the western perimeter with a relatively large descending graded slope. The existing building pad was likely originally created by minor remedial grading efforts along with minor filling in the western reaches of the property. Grading records for the development of the existing pad were not available for our review The following geotechnical conditions are apparent at the site: Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California A. Earth Materials October 2, 2017 Page 4 Terrace Deposits (Qt) -The study locations are underlain at shallow depths by Pleistocene Age Terrace Deposits which are wide spread in coastal areas of Carlsbad. As exposed, site Terrace Deposits typically consist of red brown colored sandstone deposits that occur in massive and medium dense to dense conditions near surface. Deeper exposures in Boring 1 (B-1) also encountered local "running sand" layers that are characterized by "clean" cohesionless granular deposits that resulted in caving within the borehole. Based on our SPT blow counts, the "running sand" layers occur in a tight condition overall and are local intermittent occurrences. Below the "running sand" layer, at a depth of approximately 15 feet, the sandstone changed to a dense tan to olive colored silty fine sandstone to sandy siltstone at the depth of 18 feet, that may be a reflection of the Eocene Age Santiago Formation which is known to be present beneath the Terrace Deposits (referenced Geosoils report). Project dense sandstone/siltstone are considered stable, competent deposits that will provide adequate support for new fills, structures, and improvements. Artificial Fill ( af) -Surface areas of the property are mantled by a shallow fill deposit likely placed during original and subsequent site development. As exposed, the fill deposits appear to be locally derived silty sand deposits that were found in dry and very loose to compacted conditions overall. Site existing fill deposits range to nearly 3 feet thick maximum, as exposed in our test excavations. Site existing fills and upper weathered loose Terrace Deposits are not suitable for structural support in their present condition and should be removed and recompacted as outlined in following sections. B. Groundwater and Surface Draina2e Subsurface water was not encountered in our test excavations to the depths explored and is not expected to impact site development as planned. Like all graded properties, the proper control of surface drainage is an important factor in the continued stability of the project redevelopment. Surface water should not pond upon graded surfaces, and irrigation water should not be excessive. Drainage ditches should be provided at the top of graded slopes and all site retaining walls should be provided with a well-functioning back drain system. C. Slope Stability The western perimeter graded slope, apparently constructed during the original site development more than 25 years ago, descends from the rear of the property to the Buena Vista Lagoon embankment below. Slope heights are nearly 40 feet with gradients approaching 2: 1. The slope is provided with level terraces, nearly 4 feet wide, as shown on the enclosed Figure 2. There is no indication of slope instability and rear hillside appear to continue performing well in its present condition. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Pages Slope analysis was performed by Geosoils, Inc. for the purpose of the development on the neighboring property (referenced report). Their analysis concluded overall gross and surficial conditions of stability for both static and pseudo-static conditions. Furthermore, the rear swimming pool development near the top of the descending hillside is recommended herein for support on a concrete platform and drilled CIP caissons to minimize ground disturbance and impacts on the adjacent slope. Consequently, the planned rear yard improvements and pool construction are not expected to have a significant impact or adverse effect on the stability of the rear slope. D. Faults/Seismicity Faults or significant shear zones are not indicated on or in close proximity to the project site. As with most areas of California, the San Diego region lies within a seismically active zone; however, coastal areas of the county are characterized by low levels of seismic activity relative to inland areas to the east. During a 40-year period (1934-1974), 37 earthquakes were recorded in San Diego coastal areas by the California Institute of Technology. None of the recorded events exceeded a Richter magnitude of 3. 7, nor did any of the earthquakes generate more than modest ground shaking, and did not produce significant damages. Most of the recorded events occurred along various offshore faults which characteristically generate modest earthquakes. Historically, the most significant earthquake events which affect local areas originate along well known, distant fault zones to the east and the Coronado Bank Fault to the west. Based upon available seismic data, compiled from California Earthquake Catalogs, the most significant historical event in the area of the study site occurred in 1800 at an estimated distance of 12 miles from the project area. This event, which is thought to have occurred along an offshore fault, reached an estimated magnitude of 6.5 with estimated bedrock acceleration values of 0.138g at the project site. The following list represents the most significant faults that commonly impact the region. Estimated ground acceleration data compiled from Digitized California Faults (Computer Program EQF AULT VERSION 3 .00 updated) typically associated with the fault is also tabulated. TABLE 1 MAXIMUM FAULT ZONE DISTANCE FROM SITE :PROBABLE ACCELERATION <R.H.) Rose Canyon Fault 5.1 miles 0.243g Newport-Inglewood Fault 4.7 miles 0.252g Elsinore-Julian Fault 24.1 miles 0.142g Coronado Bank Fault 21.3 miles 0.184g Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page6 The locations of significant faults and earthquake events relative to the study site are depicted on a Fault -Epicenter Map attached to this report as Figure 8. More recently, the number of seismic events that affect the region appears to have heightened somewhat. Nearly 40 earthquakes of magnitude 3 .5 or higher have been recorded in coastal regions between January 1984 and August 1986. Most of the earthquakes are thought to have been generated along offshore faults. For the most part, the recorded events remain moderate shocks which typically resulted in low levels of ground shaking to local areas. A notable exception to this pattern was recorded on July 13, 1986. An earthquake of magnitude 5.3 shook County coastal areas with moderate to locally heavy ground shaking resulting in $700,000 in damages, one death, and injuries to 30 people. The quake occurred along an offshore fault located nearly 30 miles southwest of Oceanside. A series of notable events shook County areas with a (maximum) magnitude 7.4 shock in the early morning of June 28, 1992. These quakes originated along related segments of the San Andreas Fault approximately 90 miles to the north. Locally high levels of ground shaking over an extended period of time resulted; however, significant damages to local structures were not reported. The increase in earthquake frequency in the region remains a subject of speculation among geologists; however, based upon empirical information and the recorded seismic history of County areas, the 1986 and 1992 events are thought to represent the highest levels of ground shaking that can be expected at the study site as a result of seismic activity. In recent years, the Rose Canyon Fault has received added attention from geologists. The fault is a significant structural feature in metropolitan San Diego that includes a series of parallel breaks trending southward from La Jolla Cove through San Diego Bay toward the Mexican border. Test trenching along the fault in Rose Canyon indicated that at that location the fault was last active 6,000 to 9,000 years ago. More recent work suggests that segments of the fault are younger having been last active 1000 -2000 years ago. Consequently, the fault has been classified as active and included within an Alquist-Priolo Special Studies Zone established by the State of California. Furthermore, a more recent study concluded that the coastal region of San Diego may experience earthquakes up to magnitudes 7.3 and 7.4 (Sahakian et al, 2017). This study used Newport-Ingelwood/Rose Canyon fault offshore. Although, an earthquake of this magnitude has likely not occurred in the 100,000 years, according to the data. Fault zones tabulated in the preceding table are considered most likely to impact the region of the study site during the lifetime of the project. The faults are periodically active and capable of generating moderate to locally high levels of ground shaking at the site. Ground separation as a result of seismic activity is not expected at the property. I Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California E. Seismic Ground Motion Values October 2, 2017 Page7 Seismic ground motion values were evaluated as part of this investigation in accordance with Chapter 16, Section 1613 of the 2016 California Building Code (CBC) and ASCE 7-10 Standard using the web-based United States Geological Survey (USGS) ground motion calculator. Generated results including the Mapped (Ss, S1), Risk-Targeted Maximum Considered Earthquake (MCER) adjusted for Site Class effects (SMs, SM1) and Design (Sos, Sm) Spectral Acceleration Parameters as well as Site Coefficients (Fa, Fv) for short periods (0.20 second) and I-second period, Site Class, Design and Risk-Targeted Maximum Considered Earthquake (MCER) Response Spectrum, Mapped Maximum Considered Geometric Mean (MCEo) Peak Ground Acceleration adjusted for Site Class effects (PGAM) and Seismic Design Category based on Risk Category and the severity of the design earthquake ground motion at the site are summarized in the enclosed Appendix. F. Geologic Hazards Geologic hazards are not presently indicated at the project site. The most significant geologic hazards at the property will be those associated with ground shaking in the event of a major seismic event. Liquefaction or related ground rupture failures are not anticipated. G. Field and Laboratory Tests and Test Results Earth deposits encountered in our exploratory test excavation were closely examined and sampled for laboratory testing. Based upon our exploratory boring and field exposures site soils have,been grouped into the following soil type: TABLE2 Soil Tiee I Descrietion I I Brown to red brown silty sandy (Fill/Terrace Deposits) 2 Tan grey to off-while coarse sand with pebbles (Terrace Deposits) 3 Tan to olive silty fine sandstone to sandy siltstone (May be Santiago Formation) The following tests were conducted in support of this investigation: 1. Standard Penetration Tests: Attempts were made to perform Standard Penetration Tests (SPT), at selected depths, at the time ofborehole drilling in accordance with ASTM standard procedw-e D-1586 using rope and cathead. The procedure consisted of a standard 51 MM outside diameter sampler without liner, 457 MM in length and 35 MM in inside diameter driven with a 140-pound hammer, dropped 30 inches using 5-foot long I I Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page8 ML drill rods. The bore hole was 150 MM ( 6 inches) in diameter and water was locally used to aid drilling. The test results are indicated at the corresponding locations on the attached Boring Logs. 2. Grain Size Analysis: Grain size analysis was performed on a representative sample of Soil Type 1. The test results are graphically presented on the attached Figure 9 and tabulated in Table 3 below. TABLE3 Sieve Size I 2" 1½" 1" ¾" ½" #4 #10 #20 #40 #100 #200 Location I Soil Type II Percent Passing TP-1 @2.5' 1 100 100 100 100 100 99 98 84 32 25 B-1ca210' 2 100 100 100 99 95 85 70 54 9 6 3. Maximum Dry Density and Optimum Moisture Content: The maximum dry density and optimum moisture content of Soil Type 1 was determined in accordance with ASTM D-1557. The results are presented in Table 4. TABLE4 Location Soil MaximumDry Optimum Moistur.e Type Density (r m-pcf) Content (<a>opt-%) TP-1 (@. 2.5' 1 132.9 9 4. Unit Wei2ht & Moisture Content Tests: In-place dry density and moisture content of representative soil deposits beneath the site were determined from relatively undisturbed ring samples using the Direct Measurement test method (Method B) in accordance with ASTM D7263, and Water Content of Soil and Rock by Mass test method in accordance with ASTM D2216. The test results are presented in Table 5 and tabulated on the attached Boring Logs at corresponding locations. I I Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page9 TABLES Sample Soil Field Moisture Field Dry Max.Dry In-Place Degree of I.;ocation Type Content Density Density Relative Saturation (6.)-o/o) (Td-pcf) (Tm-pcf) C.ompaction 8(%), TP-1@ l' 1 5 112.6 132.9 85 29 TP-1 @ 2.5' 1 7 116.2 132.9 87 44 B-1 @3' 1 3 119.8 132.9 90 20 B-1 @6' 1 3 -132.9 SPT Sample - B-1@ 10' 2 3 --Sample Disturbed - B-1@ 18' 3 13 --SPT Sample - B-2@2.5' 1 6 -+ 132.9 Sample Disturbed - B-2@5' 1 6 --SPT Sample - B-3@ l' 1 ---No Sample Recovery - B-3 @2' 1 5 --SPT Sample - Assumptions and relationships: In-place Relative Compaction = (Yd+ Ym) Xl00 Gs = 2.70 e = (Gs Yw + Yd) -1 S =(wGs)+e 5. Expansion Index Test: One expansion index (El) test was performed on a representative sample of Soil Type 1 in accordance with the ASTM D-4829. The test results are presented in Table 6. TABLE6 Sample Soil Molded Degree of Final Initial Dry Measured EI (,) Saturation (,) Density 50% Location Type (%) Wo) (o/o) (PCF.) EI Saturation TP-1 @2.5' I 1 I 8 I 44 I 15 I 114 I 0 I 0 I ( w) = moisture content in percent. Elso = Elmeas -(50 -Smeas) ((65 + Elmeas) + (220 -Smeas)) Expansion Index (EI) Expansion Potential 0 -20 Very Low 21 -50 Low 51 -90 Medium 91 -130 High ) 130 Very High Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 10 6. Direct Shear Test: One direct shear test was performed on a representative sample of Soil Type 1 in accordance with ASTM D3080. The prepared specimen was soaked overnight, loaded with normal loads of 1, 2, and 4 kips per square foot respectively, and sheared to failure in an undrained condition. The test result is presented in Table 7. TABLE7 Sample Soil Sample Unit Angle of Apparent Weight Int. Frie. Cohesion Location Type Condition (rw-pcf) (~-De!!.) (c-osf) TP-1 (@. 2.5' 1 Remolded to 100% of in-place condition 127.0 38 273 7. pH and Resistivity Test: pH and resistivity of a representative sample of Soil Type 1 was determined using "Method for Estimating the Service Life of Steel Culverts," in accordance with the California Test Method (CTM) 643. The test result is tabulated in Table 8. TABLES I Sample Location Soil TyPe Minimum Resistivity (OHM-CM) pH I TP-1 @2.5' 4500 7.1 I I 8. Sulfate Test: A sulfate test was performed on a representative sample of Soil Type 1 in accordance with the California Test Method (CTM) 417. The test result is presented in Table 9. TABLE9 Sample Location Soil Ty,pe Amount of Water Soluble Sulfate In Soil(% by Weight) TP-1 @2.5' I 1 I 0.001 7. Chloride Test: A chloride test was performed on a representative sample of Soil Type 1 in accordance with the California Test Method (CTM) 422. The test result is presented in Table 10. TABLEl0 Sample Location Soil Type Amount of Water Soluble Ghloride In Soil (% by Weight) TP-1 @ 2.5' I 1 I No Detection I I Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California VI. SITE CORROSION ASSESSMENT October 2, 2017 Page 11 A site is considered to be corrosive to foundation elements, walls and drainage structures if one or more of the following conditions exist: * Sulfate concentration is greater than or equal to 2000 ppm (0.2% by weight). * Chloride concentration is greater than or equal to 500 ppm (0.05 % by weight). * pH is less than 5.5. For structural elements, the minimum resistivity of soil ( or water) indicates the relative quantity of soluble salts present in the soil ( or water). In general, a minimum resistivity value for soil ( or water) less than 1000 ohm-cm indicates the presence of high quantities of soluble salts and a higher propensity for corrosion. Appropriate corrosion mitigation measures for corrosive conditions should be selected depending on the service environment, amount of aggressive ion salts (chloride or sulfate), pH levels and the desired service life of the structure. Results oflimited laboratory tests performed on selected representative site samples indicated that the minimum resistivity is greater than 1000 ohm-cm suggesting presence of low quantities of soluble salts. Test results further indicated that pH levels are greater than 5.5, sulfate concentration are less than 2000 ppm and chloride concentration levels are less than 500 ppm. Based on the results of the corrosion analyses, the project site is considered non-corrosive. However, the project site is located in a close proximity to seawater and corrosion mitigation measures should be considered in the project designs, unless otherwise approved. Corrosion mitigation typically includes special high strength concrete, zinc or epoxy coated reinforcing steel and greater reinforcement cover, as required and appropriate. Based upon the result of the tested soil sample, the amount of water soluble sulfate (SO4) was found to be 0.001 percent by weight which is considered negligible according to AC! 318 (SO Exposure Class with Not Applicable severity). However, due to the project close proximity to seawater, as a minimum, Portland cement Type II with a minimum 28 days compressive strength (f c) of 4,000 psi and maximum water cement ratio of 0.50 (SI Exposure Class) should be considered, unless otherwise determined or approved by the project corrosion/structural engineer. VII. CONCLUSIONS Based upon the foregoing investigation, the proposed building additions and rear site improvements, substantially as proposed, are feasible from a geotechnical viewpoint. The property is underlain by stable Terrace Deposits at shallow depths and instability or adverse geologic conditions that could preclude the proposed new additions and site improvements are not indicated. Geotechnical factors presented below are unique to the project site and will most influence the planned new construction and associated costs: Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 12 * Landslides, hillside instability, faults or significant shear zones are not present at the project property and are not considered a major geotechnical factor in the planned new construction. The study site is not located within the Alquist -Priolo earthquake fault zone established by the State of California. Moderate to locally high levels of ground shaking, however, are expected at the site during occasional periods of seismic activity along distant active faults. * The project property is a developed parcel created over 25 years ago and currently supports an existing residential dwelling with the associated structures and improvements. Building additions and modifications were also apparently carried out subsequent to the original development. Records of engineering plans, observation and testing services during the original development and subsequent additions and building modifications are not available. * The property is underlain at shallow depths by stable and competent Pleistocene Age sandstone Terrace Deposits, which will provide adequate support for the planned new additions and site improvements. * Shallow artificial fills, on the order of 3 feet thick maximum, mantle the project site. Existing site fills occur in dry and very loose to somewhat compacted conditions overall, and are not considered suitable for structural support. These deposits should be removed and recompacted as a part of foundation bearing and subgrade soil preparation. As an alternative, new foundations may penetrate these deposits and adequately extend into the underlying dense Terrace Deposits as recommended in the following sections. * Evidence of a deep-seated or surficial instability which could preclude the planned backyard improvements and swimming pool construction is not indicated within the site rear descending slope. All structures and improvements planned near or at the top of the rear descending slope should be setback or provided with deepened foundations to provide an adequate setback to daylight as specified herein. * The main geotechnical concern at the site is the proximity of the planned new swimming pool at the top of the rear slope. The project property is subject to string-line setback requirements, and the City of Carlsbad Hillside Development Ordinance. In order to minimize significant ground disturbance and construction grading impacts on the adjacent descending hillside, the new swimming pool is recommended herein for support on a concrete platform and drilled CIP caissons. New site improvements will also be located on the east side of the existing retaining wall along the top of the rear slope. Consequently, the planned new rear yard improvements and pool construction are not expected to have a significant impact or adverse effect on the stability of the rear slope, provided our recommendations are followed. The imaginary 0. 7: 1 (horizontal to vertical) building setback plane from the top of slope, as required by the City of Carlsbad is also shown on the enclosed Figures 2 and 7. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 13 * Specific recommendations for the swimming pool caisson and concrete platform support are provided in the following sections. CIP caissons should be adequately extended a minimum of IO feet or %-height of the adjacent hillside, whichever is more but need not to exceed 40 feet, horizontal distance between the bottom outside edge to daylight. Due to the existence of"running sand" beneath the planned pool area, all caissons should be provided with casing to protect the boreholes from caving. * Final grades for the new building extensions will be at or very near existing grades and significant groung modifications or major grading efforts are not planned in connection with the project construction. Project earthworks are expected to primarily consist ofremedial foundation bearing and subgrade preparations and minor filling for achieving the rear yard improvement finish subgrade levels. * Existing building foundations were locally exposed in our exploratory test pit excavations TP-1 (see Figure 2). Based on our limited exposures, the existing foundation was measured approximately 9 inches deep (BGS) and roughly 12 inches wide. Existing building foundations are not suitable for second story loading conditions and foundation underpinning will be required where second floor additions are planned, as specified in the following sections. * Site soils are chiefly sandy to silty sand (SP/SM) deposits with very low expansion potential (expansion index less than 20) based on ASTM D-4829 classification, and expansive soils are not considered a geotechnical factor in the planned new constructions. * Added care will be required to avoid undermining or cause any damages to the nearby existing structures and improvements, adjacent neighboring properties and underground utilities due to site excavations, earthworks, grading and construction activities. Adequate excavation setbacks shall be maintained and temporary construction slopes laid back as specified herein. Added field recommendations, however, may also be necessary and should be given by the project geotechnical consultant for the protection of adjacent properties and should be anticipated. * Groundwater conditions were not encountered during this investigation to the depths explored and are not expected to impact the proposed new additions and site improvements. However, adequate site surface drainage control is a critical factor in the future stability of the redeveloped property, as planned. Drainage facilities should be designed and installed for proper control and disposal of surface runoff. Surface water should flow away from the project structures/improvements and top of the rear slope. Presence of an adequate back drainage system behind the existing western margin retaining wall should be confirmed and all new retaining walls provided with a well-functioning back drainage system as recommended herein. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 14 * Soil collapse and post construction total and differential settlements are not expected to be a geotechnical factor in the development of the project site provided our remedial grading and foundation recommendations are incorporated into the design and construction of the project. Post construction settlement after completion ofremedial efforts and site grading works as specified herein, is not expected to exceed approximately 1-inch and should occur below the heaviest loaded footings. The magnitude of post construction differential settlement as expressed in terms of angular distortion is not anticipated to exceed ½-inch between similar adjacent structural elements. * Liquefaction and seismically induced settlements will not be a factor in the planned new construction provided our remedial foundation bearing and subgrade soil preparation, and foundation recommendations are followed. * Minor cracking and separation may be anticipated between the new additions and existing adjacent building to remain. Improvements to such normal features for this type of construction can be made by tying the existing building to the new additions as recommended in the following sections. VIII. RECOMMENDATIONS The following recommendations are provided based on the available geotechnical data generated during this limited effort, and scheme of the proposed building addition and rear site improvements, as understood. Added or modified recommendations may also be appropriate and should be provided by the project geotechnical consultant at the time of final plan review phase, and should be anticipated: A. Foundation Bearin2 and Sub2rade Soil Preparation Major grading efforts or significant ground modifications are not planned in connection with the proposed new building additions and site improvements. However minor remedial bearing and sub grade soil preparations and grading is expected to achieve design grades and construct safe and stable building and improvement surfaces. All site excavations, remedial grading, earthworks, construction, and bearing/subgrade soil preparation should be completed in accordance with Chapter 18 (Soils and Foundations) and Appendix "J" (Grading) of the 2016 California Building Code (CBC), City of Carlsbad Ordinances, the Standard Specifications for Public Works Construction, and the requirements of the following sections wherever applicable. 1. Existing Underground Utilities and Structures: All existing underground waterlines, sewer lines, pipes, storm drains, utilities, tanks, structures and improvements at or nearby the project building addition construction site should be thoroughly potholed, identified and marked prior to the initiation of the actual remedial grading and earthworks. Specific Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 15 geotechnical engineering recommendations may be required based on the actual field locations and invert elevations, backfill conditions and final grades in the event of a remedial grading conflict. Utility lines may be needed to be temporarily redirected, if necessary, prior to excavations and earthwork operations, and reinstalled upon completion of remedial grading. Alternatively, permanent relocations may be appropriate as shown on the approved plans. Abandoned irrigation lines, pipes and conduits should be properly removed, capped or sealed off to prevent any potential for future water infiltrations into the foundation bearing and subgrade soils. Voids created by the removals of the abandoned underground pipes, tanks, structures, roots, and stumps should be properly backfilled with compacted fills in accordance with the requirements of this report. 2. Clearing and Grubbing: Remove all existing surface and subsurface structures and improvements, concrete flatwork and old foundations, vegetation, lawns, roots, stumps, and all other unsuitable materials and deleterious matter from all areas proposed new construction areas plus a minimum of 3 feet outside the perimeter envelop, where possible and as approved in the field. All trash debris and unsuitable materials generated from site demolitions and clearing efforts should be properly removed and disposed of from the site. Trash, vegetation and construction debris should not be allowed to occur or contaminate new site fills and backfills. The prepared grounds should be observed and approved by the project geotechnical consultant or his designated field representative prior to grading and earthworks. 3. Stripping and Removals: Minor remedial and grading efforts will be required to establish final design grades and construct safe and stable building addition and improvement surfaces, and achieve final design grades. All existing loose and dry fills and upper weathered Terrace Deposits in areas of planned new fills, building additions, structures and site improvements plus a minimum of 3 feet outside the perimeter envelop, where possible and as directed in the field, should be stripped (removed) to the underlying dense Terrace Deposits, as approved in the field, and placed back as properly compacted fills. Based on our available subsurface exposures, removal depths are expected to be on the order of 1 to 3 feet deep maximum below the existing ground surfaces (BGS). However, locally deeper removals may also be necessary and should be anticipated. Bottom of all removals should be additionally ripped, prepared and recompacted as part of the initial fill lift placement. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 16 There should be at least 12 inches of compacted fills under all new slab-on-grade floors, however, all new building addition foundations should penetrate the upper fills and be adequately embedded into dense undisturbed Terrace Deposits as approved in the field. In the areas where dense and competent Terrace Deposits are not exposed (in-place densities less than 87%) at the bottom of foundation trenches, if any encountered, the bottom of the foundation excavation should be over-excavated to a minimum depth of 12 inches and reconstructed with well-compacted (minimum 90%) fills, as directed in the field. There should also be a minimum of 12 inches of compacted fills below rough finish subgrade in the planned site improvement areas, as approved in the field. The exposed bottom of all removals should be observed and approved by the project geotechnical consultant or his designated field representative. 4. Temporary Construction Slopes and Trenching: Excavations and removals adjacent to the existing foundations, improvements and structures should be performed under observations of the project geotechnical engineer. Undermining existing adjacent foundations, structures, improvements and underground utilities to remain shall not be allowed by the project removals, over-excavations and earthwork operations. Large open excavations, trenching and temporary construction slopes are not anticipated in connection with the planned construction and new building additions. Project excavations, trenching and temporary slopes are expected to be on the order of 3 feet deep maximum. Temporary excavations and trenching adjacent to existing foundations may be developed in limited alternating sections not more than 12 feet long, unless otherwise approved. Alternatively, temporary foundation support consisting of hydraulic jacks and beams/plates ( or similar techniques) may be used to prevent undermining existing foundations. Temporary jack and beams/plates foundation supports should have a minimum 2000 pounds capacity and installed at 6 feet on centers maximum, unless otherwise directed in the field. All excavations, trenching and temporary construction slopes will require geotechnical observations during the earthworks and construction operations. Additional recommendations including revised excavation slopes and setbacks, completing trenching and construction in more limited alternating sections, and the need for modified temporary foundations support method should be given at that time as necessary. The project contractor shall also obtain appropriate permits, as needed, and conform to Cal-OSHA and local governing agencies ' requirements for trenching and open excavations, as well as safety of the workmen during construction. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 17 5. Fill-Backfill Materials, Import Soils and Compaction: Soils generated from site stripping (removals) and over-excavations will mainly consist of sandy materials that typically work well as site new fills and backfills provided all debris, roots, rootles, stump and unsuitable materials are throughly removed and separated to the satisfaction of the project geotechnical consultant. Import soils, if necessary to complete grading and achieve final design grades, should be good quality sandy granular D.G. type (SM/SW), non-corrosive deposits with very low expansion potential (100% passing 1-inch sieve, more than 50% passing #4 sieve and less than 18% passing #200 sieve with expansion index less than 20). Import soils should be observed, tested as necessary, and approved by the project geotechnical engineer prior to delivery to the site. Import soils should also meet or exceed engineering characteristic and soil design parameters as specified in the following sections. Uniform bearing and subgrade soil conditions should be constructed at the site by the remedial grading operations. Site soils should be adequately processed, thoroughly mixed, moisture conditioned to above (2%) optimum moisture levels, as directed in the field, placed in thin (8 inches maximum) uniform horizontal lifts and mechanically compacted to minimum 90% of the corresponding laboratory maximum dry density per ASTM D1557, unless otherwise specified. 6. Surface Drainage and Erosion Control: A critical element to the continued stability of regraded building addition pad and site improvement surfaces is an adequate stormwater and surface drainage control. Presently, existing site drainage is considered poor to marginal. In general, perimeter drainage should be improved disallowing surface water to pond on pad surfaces or flow toward the building foundations or improvement sites. For this purpose, some fine or contour grading of the perimeter yards appear necessary to establish positive drainage (minimum 5%) away from the site building and improvements onto a suitable drainage collection and disposal facility. Roof gutters and area drains should be installed. Over- watering of the site landscaping and lawns shall also not be allowed. Only the amount of water to sustain vegetation life should be provided. A back drainage behind the existing western wall should be field verified and new retaining walls provided with a well-constructed back drainage system. Site drainage improvements should be shown on a site/drainage improvement plan prepared by the project design consultant. 7. Engineering Observations: All bearing and subgrade soil preparation and earthwork operations including excavations, stripping and removals, suitability of earth deposits used as new compacted fills and backfills, and compaction procedures should be continuously observed and tested by the project geotechnical consultant and presented in the final as-graded compaction report. The nature of finished bearing and subgrade soils should be confirmed in the final compaction report at the completion of grading. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 18 Geotechnical engineering observations should include but not limited to the following: * Initial Observation/Preconstruction Meeting -After the site clearing and staking of project building addition limits but before over-excavation/brushing starts. * Bottom of Over-Excavation and Stripping (Removal) Observation -After completion of over-excavation to the specified depth but before filling or backfilling. * Temporary Excavations and Trenching Observations -At the completion of the first section of trenching adjacent to existing foundations to evaluate exposed bearing soil conditions at existing foundations and the need for hydraulic jack and beam/plate support system. * Fill/Backfill Observation -After the fill/backfill placement is started over the approved bottom, but before the vertical height of fill/backfill exceeds 2 feet. All new fills and backfills should be compacted to minimum 90% compaction levels, unless otherwise approved. A minimum of one test shall be required for each 2 feet in vertical gain. Finish rough and final pad grade tests shall be required regardless of fill thickness. * Foundation Trench and Subgrade Soils Observation -After the foundation trench excavations and prior to the placement of steel reinforcing for adequate foundation embedment depth to dense and competent undisturbed Terrace Deposit bearing strata, and proper subgrade moisture and specified compaction levels, as appropriate. * Geotechnical Foundation/Slab Steel Observation -After the steel placement is completed but before the scheduled concrete pour. * Underground Utility/Plumbing and Storm Drain Trench Observation -After the trench excavations but before placement of pipe bedding or installation of the underground facilities. Local and Cal-OSHA safety requirements for open excavations apply. Observations and testing of pipe bedding may also be required by the project geotechnical engineer. * Underground Utility/Plumbing and Storm Drain Trench Backfill Observation -After the backfill placement is started above the pipe zone but before the vertical height of backfill exceeds 2 feet. Testing of the backfill within the pipe zone may also be required by the governing agencies. Pipe bedding and backfill materials and compaction level shall conform to the governing agencies' requirements and project soils report, where and as applicable. All trench backfills should be mechanically compacted to a minimum of 90% compaction levels unless otherwise specified. Plumbing trenches more than 12 inches deep maximum under the floor slabs should also be mechanically compacted and tested for a minimum of 90% compaction levels. Flooding or jetting techniques as a means of compaction method should not be allowed. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 19 * Improvement Subgrade Observation -Prior to the placement of concrete for proper subgrade preparations and specified compaction levels. B. Footings and Slab-on-Grade Foundations The following recommendations are consistent with the anticipated sandy to silty sand (SP /SM) bearing soils with very low expansion potential ( expansion index less than 20), and site indicated geotechnical conditions. All design recommendations should be further confirmed and/or revised as necessary at the completion of remedial bearing and sub grade soil preparations and presented in the final engineering observations and compaction testing report: 1. All new footings and underpinning grade beams, where necessary for the second floor additions, should penetrate the upper fills, and adequately embedded into the underlying dense and competent undisturbed Terrace Deposits, as approved in the field. In the areas where dense and competent Terrace Deposits are not exposed at the minimum specified depths (in-place densities less than 87%, if any encountered), the bottom of the foundation and underpinning grade beam trench should be over-excavated to a minimum depth of 12 inches and reconstructed with minimum 90% compacted fills, as evaluated and directed in the field. 2. New perimeter and interior continuous strip footings should be sized at least 15 inches wide and embedded a minimum of 18 inches into dense and competent undisturbed Terrace Deposits, as approved in the field, for single and two-story building loading conditions. Spread pad footings, if any, should be at least 24 inches square and also embedded 18 inches into approved undisturbed Terrace Deposits. Based on the available subsurface exploratory excavations, total foundation and underpinning grade beam trench depths on the order of 2 to 3.5 feet may be anticipated. Exterior continuous footings should enclose the entire perimeter. Perimeter continuous wall foundations should be reinforced by at least four #5 reinforcing bars. Place a minimum of two #5 bars 3 inches above the bottom of the footing and a minimum of two #5 bars 3 inches below the top. Reinforcement details for spread pad and isolated post footings should be provided by the project architect/structural engineer. Existing perimeter footings should be tied near the top and bottom to the new adjacent continuous footings with a minimum 18 inches long #4 dowels with minimum 6 inches deep drill and epoxy grout to existing footings and 12 inches into new footings. New interior continuous strip and spread pad footings, if any, should also be structurally tied to the adjacent existing concrete floor slabs with minimum 18 inches long #4 dowels spaced at 18 inches on centers maximum, drill and epoxy grouted at least 6 inches into surrounding slabs and 12 inches into new footings, unless otherwise specified or noted. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 20 3. Interior slabs should be a minimum of 5 inches in thickness reinforced with minimum #4 reinforcing bars spaced 18 inches on center maximum each way placed mid-height in the slab. Provide re-entrant comer reinforcement for all interior slabs depending on slab geometry and/or interior column locations, as generally depicted on the enclosed Figure 10. Interior slabs should be provided with a well-performing moisture barrier/vapor retardant (minimum 10-mil Stego) placed over the prepared sub grade and covered with minimum 2 inches of clean sand (SE 30 or greater). Alternatively, a 4-inch thick base of compacted ½-inch clean aggregate provided with the vapor barrier (minimum 15-mil Stego) in direct contact with (beneath) the concrete may also be considered provided a concrete mix which can address bleeding, shrinkage and curling is used. New interior slabs adjacent to existing footings/slabs, if any, should also be provided with a minimum 12 inches wide by 12 inches deep thickened edge reinforced with a minimum 1-#4 bar top and bottom, and tied at same spacing with the slab reinforcement, with #4 dowels as previously specified. Provide "softcut" contraction/control joints consisting of sawcuts spaced 10 feet on centers each way for the all interior slabs. Cut as soon as the slab will support the weight of the saw and operate without disturbing the final finish which is normally within 2 hours after final finish at each control joint location or 150 psi to 800 psi. The sawcuts should be minimum I-inch in depth but should not exceed 1 ¼-inches deep maximum. Anti-ravel skid plates should be used and replaced with each blade to avoid spalling and raveling. A void wheeled equipments across cuts for at least 24 hours. 4. Adequate setback or deepened foundations shall be required for all foundations and improvements constructed on or near the top of descending slopes to maintain a minimum horizontal distance to daylight or adjacent slope face. For foundations and structural elements, there should be a minimum of 10 feet or % of the slope height, whichever is more, horizontal setback from the bottom outside edge of the footing to daylight, unless otherwise specified or approved. For site on-grade improvements, a minimum of 7 feet horizontal setback from the outside edge ofimprovement to daylight may be considered adequate, unless otherwise noted. For this purpose, site improvements should also be provided with a reinforced thickened edge to satisfy the minimum daylight setback requirement. 5. Foundation trenches and slab subgrade soils should be observed and tested for exposing suitable bearing strata, proper moisture and specified compaction levels and approved by the project geotechnical consultant prior to the placement of concrete. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California C. Underpinning Grade Beam October 2, 2017 Page 21 Based on our test pit exposures, existing building foundations are undersized for the support of a second story. Underpinning of the existing undersized footings, or a new independent foundation system in accordance with the requirements of this report will be necessary, where the second story building additions are planned. The following are appropriate in case of underpinning the existing undersized footings: 1. Existing foundations, at the project second floor building additions, should be underpinned with a new grade beam foundation member that extend into the underlying dense and competent undisturbed Terrace Deposits, per the requirements of this report. The new underpinning grade should be structurally tied into the existing footings. A schematic of an underpinning grade beam is included in this report as Typical Grade Beam Detail For Underpinning Wall Footings, Figure 11 . 2. The underpinning grade beam should at least 6 inches wide at the top and extend below the entire width of the existing footings (minimum 18 inches), as shown in Figure 11 . 3. The grade beam should be reinforced with minimum 2-#4 bars top and bottom and #3 ties at 18 inches on centers maximum. The underpinning grade beams should also be tied to the existing footings with minimum 26 inches long dowels drill and epoxy grout 6 inches into the existing footings and 10 inches into the new grade beam. Specific designs and actual construction details should be provided by the project structural engineering consultant. 4. Trenching for new grade beams and temporary support for existing foundations consisting of hydraulic jacks and beams/plates (or approved similar) should be carried out per the requirements of this report, and as approved in the field. D. Soil Design Parameters The following soil design parameters are based upon tested representative samples of onsite earth deposits and our experience with similar earth deposits near the project site. All parameters should be re-evaluated when the characteristics of the final as-graded soils have been specifically determined: * Design soil unit weight= 127 pcf. * Design angle of internal friction of soil = 38 degrees. * Design active soil pressure for retaining structures = 31 pcf (EFP), level backfill, cantilever, unrestrained walls. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 22 * Design at-rest soil pressure for retaining structures = 48 pcf (EFP), non-yielding, restrained walls. * Design soil passive resistance for retaining structures= 450 pcf (EPP), level surface on the toe side ( soil mass on the toe side extends a minimum of 10 feet or 3 times the height of the surface generating passive resistance). * Design passive soil pressure for retaining structures= 203 pcf (EFP), 2: 1 sloping down ground surface on the toe side. * Design coefficient of friction for concrete on soils = 0.45. * Design net allowable foundation pressure (minimum 12 inches wide footing embedded 18 inches into competent undisturbed Terrace Deposit) = 2000 psf. * Allowable lateral bearing pressure (all structures except retaining walls)= 200 ps£'ft. Notes: * Added lateral pressures caused by nearby foundations, improvements and surcharge loading should also be considered in the project wall designs, as applicable and appropriate. * An additional seismic force due to seismic increments of earth pressure should also be considered in the project designs, as necessary and where applicable. A seismic lateral inverted triangular earth pressure of 20 pcf (EFP) acting at O. 6H (His the retained height) above the base of the wall should be considered. Alternatively, seismic loading based on Mononobe-Okake (M-0) coefficients may be considered for seismic force due to seismic increments of earth pressure as follows: Kh = 0.16 Ka =0.24 Kae= 0.40 The seismic lateral earth pressure should be considered in addition to the specified static earth and surcharge loading pressures. * Use a minimum safety factor of 1.5 for wall over-turning and sliding stability. However, because large movements must take place before maximum passive resistance can be developed, a minimum safety factor of 2 may be considered for sliding stability particularly where sensitive structures and improvements are planned near or on top of retaining walls. * When combining passive pressure and frictional resistance, the passive component should be reduced by one-third. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 23 * The net allowable foundation pressures provided herein were determined based on minimum 12 inches wide footings embedded at least 18 inches into dense and competent undisturbed Terrace Deposits, and may be increased by 20% for each additional foot of depth, and 20% for each additional foot of width to a maximum of 5500 psf. The allowable foundation pressures provided herein also apply to dead plus live loads and may be increased by one-third for wind and seismic loading. * The lateral bearing earth pressures may be increased by the amount of designated value for each additional foot of depth to a maximum 1500 pounds per square foot. E. Swimmin~ Pool Construction The new swimming pool development is planned at the top of the rear descending hillside underlain by shallow fills, on the order of 3 feet maximum, over dense Terrace Deposits. The main geotechnical concern with respect to the pool construction is the close proximity of the planned new swimming pool at the top of the hillside and conforming to the City of Carlsbad Hillside Development Ordinance. In order to accommodate pool construction at the top of descending hillside, minimize ground disturbances, and alleviate potential impacts on the stability of the adjacent descending hillside, the new swimming pool is recommended herein for support on a concrete platform and drilled CIP caissons. Recommended swimming pool concrete platform and drilled CIP caisson support is conceptually illustrated on the enclosed Typical Swimming Pool Construction Concept, Figure 12. Detail design and construction plans for the proposed concrete platform and caisson supports should be provided by the project design-build contractor or structural engineer. The following parameters and minimum design values are based on the engineering properties of the subsurface soil profile, as encountered during this study and our experience with the similar projects in the vicinity of the project site and should be used in the design, where applicable: 1. The new pool should be supported on a structural platform (slab). The concrete pool shell should then be erected upon and structurally anchored and tied onto the concrete platform. The concrete platform slab shall not be less than 12 inches minimum. 2. The space (void) between the bottom of the pool shell and top of the concrete platform at the shallow end may be filled with Geofoam, 2.5-sack cement slurry, lightweight concrete or similar fillers (see Figure 12). 3. The concrete platform slab should span over drilled CIP caissons which are adequately embedded into the underlying competent Terrace Deposits to provide a minimum of20 feet setback from the bottom edge of the most outside caisson to daylight (% of the hillside height), but not less 12 feet minimum. Limited Geo technical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page24 4. Drilled CIP caissons should a minimum of2 feet in diameter with no less than 2½ times the diameter spacing, center to center. Maximum caisson spacing should not exceed 12 feet center to center, unless otherwise approved. 5. Point of fixity may be assumed at the depth of 2 feet into the underlying competent undisturbed Terrace Deposits (minimum 5 feet below the top of slope). A passive resistance of 450 psf may also be considered for the portion embedded below the point of fixity. The passive resistance can be increased by the amount of the designated value for each additional foot of depth to a maximum of 4500 psf. 6. A net allowable pile capacity of 1000 based on skin friction may be considered for dense and competent Terrace Deposits (the weight ofthepilemaybe assumed to be supported by end bearing. The net allowable pile capacity increase should be limited to a maximum of depth of 20 times pile diameter). 7. A coefficient of friction of 0.45 may be considered for the portion of the caisson embedded into the competent undisturbed Terrace Deposits. Use a minimum 4000 psi (fc) concrete for CIP concrete caissons and platform. 8. Underlying Terrace deposits include intermittent layers of"running sand" layers that are characterized by "clean" cohesionless deposits. Consequently, all caisson drill shafts should be provided with casing to protect the boreholes from caving. 9. Groundwater was not encountered in our test borings to the depths explored. However, subsurface water seeps may develop at the time of drilling and cannot be ruled out. Water seeps, if developed, shall be properly removed using suitable dewatering techniques from caisson shafts prior to concrete pour. 10. All shafts should be thoroughly cleaned to the satisfaction of the project geotechnical engineer using a "clean out bucket." Free fall of concrete in the drill shafts shall not be allowed. Concrete can be placed only upon the approval of the geotechnical engineer using the "tremie" techniques. All drilled shafts shall be plumb. Drill shafts which are more than 1 % of their height maximum out-of-plumb shall be rejected and required to be re-drilled. 11. All caisson shafts should be observed and approved by the project geotechnical consultant prior to the placement of steel cage and pouring the concrete. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California F. Exterior Concrete Slabs, Pool DeckinK, Patios and Flatwork October 2, 2017 Page 25 1. All exterior slabs (walkways, patios) supported on very low expansive subgrade soils should be a minimum of 4 inches in thickness, reinforced with #3 bars at 18 inches on centers in both directions placed mid-height in the slab. The subgrade soils should be compacted to minimum 90% compaction levels at the time of fine grading and before placing the slab reinforcement. In order to enhance performance of exterior slabs, pool decking and Flatwork, a minimum 8 inches wide by 8 inches deep thickened edge reinforced with a minimum of 1-#4 continuous bar near the bottom should be considered along the slab perimeter. 2. Reinforcements lying on subgrade will be ineffective and shortly corrode due to lack of adequate concrete cover. Reinforcing bars should be correctly placed extending through the construction joints tying the slab panels. In construction practices where the reinforcements are discontinued or cut at the construction joints, slab panels should be tied together with minimum 18 inches long #3 dowels at 18 inches on centers placed mid-height in the slab (9 inches on either side of the joint). 3. Provide "too] joint" or "softcut" contraction/control joints spaced 10 feet on center (not to exceed 12 feet maximum) each way. The larger dimension of any panel shall not exceed 125% of the smaller dimension. Tool or cut as soon as slab will support weight, and can be operated without disturbing the final finish which is normally within 2 hours after final finish at each control joint location or 150 psi to 800 psi. Tool or softcuts should be a minimum of ¾-inch but should not exceed I-inch deep maximum. In case of softcut joints, anti-ravel skid plates should be used and replaced with each blade to avoid spalling and raveling. Avoid wheeled equipments across cuts for at least 24 hours. Joints shall intersect free-edges at a 90° angle and shall extend straight for a minimum of 1 ½ feet from the edge. The minimum angle between any two intersecting joints shall be 80°. Align joints of adjacent panels. Also, align joints in attached curbs with joints in slab panels. Provide adequate curing using approved methods ( curing compound maximum coverage rate = 200 sq. ft./gal.). 4. Site improvements placed along the top of descending hillside should be provided with a reinforced thickened edge to satisfy the minimum daylight setback requirement, as specified in this report. 5. All exterior slab designs should be confirmed in the final as-graded compaction report. 6. Subgrade soils should be tested for proper moisture and specified compaction levels and approved by the project geotechnical consultant prior to the placement of concrete. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California G. General Recommendations October 2, 2017 Page 26 1. The minimum foundation design and steel reinforcement provided herein are based on soil characteristics and are not intended to be in lieu of reinforcement necessary for structural considerations. 2. Adequate staking and grading control is a critical factor in properly completing the recommended remedial and site grading operations. Grading control and staking should be provided by the project grading contractor or surveyor/civil engineer, and is beyond the geotechnical engineering services. Staking should apply the required setbacks shown on the approved plans and conform to setback requirements established by the governing agencies and applicable codes for off-site private and public properties and property lines, utility easements, right-of-ways, nearby structures and improvements, leach fields and septic systems, and graded embankments. Inadequate staking and/or lack of grading control may result in illegal encroachments or unnecessary additional grading which will increase construction costs. 3. Footings located on or adjacent to the top of descending slopes should be adequately setback or extended to a sufficient depth to provide a minimum horizontal distance to the slope face, as specified in this report. Site concrete flatwork and improvements near the top of descending slopes should be provided with a thickened edge to satisfy this requirement, as specified. 4. Open or backfilled trenches parallel with a footing shall not be below a projected plane having a downward slope of 1-unit vertical to 2 units horizontal (50%) from a line 9 inches above the bottom edge of the footing, and not closer than 18 inches from the face of such footing. 5. Where pipes cross under-footings, the footings shall be specially designed. Pipe sleeves shall be provided where pipes cross through footings or footing walls, and sleeve clearances shall provide for possible footing settlement, but not less than I-inch all around the pipe. 6. Foundations where the surface of the ground slopes more than 1 unit vertical in 10 units horizontal (10% slope) shall be level or shall be stepped so that both top and bottom of such foundations are level. Individual steps in continuous footings shall not exceed 18 inches in height and the slope of a series of such steps shall not exceed 1 unit vertical to 2 units horizontal (50%) unless otherwise specified. The steps shall be detailed on the structural drawings. The local effects due to the discontinuity of the steps shall also be considered in the design of foundations as appropriate and applicable. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 27 7. All underground utility and plumbing trenches should be mechanically compacted to a minimum of 90% of the maximum dry density of the soil unless otherwise specified. Care should be taken not to crush the utilities or pipes during the compaction of the soil. Non-expansive, granular backfill soils should be used. Trench backfill materials and compaction levels beneath pavements within the public right-of-way shall conform to the requirements of governing agencies. 8. Expansive clayey soils should not be used for backfilling of any retaining structure. All retaining walls should be provided with a 1: 1 wedge of granular, compacted backfill measured from the base of the wall footing to the finished surface and a well-constructed back drainage system as shown on the enclosed Figure 13. Planting large trees behind site building retaining walls should be avoided. 9. Site drainage over the finished pad surfaces should flow away from structures onto the street in a positive manner. Care should be taken during the construction, improvements, and fine grading phases not to disrupt the designed drainage patterns. Roof lines of the buildings should be provided with roof gutters. Roof water should be collected and directed away from the buildings and structures to a suitable location. 10. Final plans should reflect preliminary recommendations given in this report. Final foundations and grading plans may also be reviewed by the project geotechnical consultant for conformance with the requirements of the geotechnical investigation report outlined herein. More specific recommendations may be necessary and should be given when final grading and architectural/structural drawings are available. 11. This report is subject to review and possible revisions in the case of plan changes particularly with respected to building additions and new improvement surfaces and final locations, design finish grades and heights of retaining walls. Additional recommendations and design parameters will also be necessary in case of added site improvements and structures. 12. All foundation trenches should be observed to ensure adequate footing embedment and confirm competent bearing soils. Foundation and slab reinforcements should also be observed and approved by the project geotechnical consultant. 13. The amount of shrinkage and related cracks that occurs in the concrete slab-on-grades, Flatwork and driveways depend on many factors the most important of which is the amount of water in the concrete mix. The purpose of the slab reinforcement is to keep normal concrete shrinkage cracks closed tightly. The amount of concrete shrinkage can be minimized by reducing the amount of water in the mix. To keep shrinkage to a minimum the following should be considered: Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 28 IX. * Use the stiffest mix that can be handled and consolidated satisfactorily. * Use the largest maximum size of aggregate that is practical. For example, concrete made with %-inch maximum size aggregate usually requires about 40-lbs. more (nearly 5-gal.) water per cubic yard than concrete with 1-inch aggregate. * Cure the concrete as long as practical. The amount of slab reinforcement provided for conventional slab-on-grade construction considers that good quality concrete materials, proportioning, craftsmanship, and control tests where appropriate and applicable are provided. 14. A preconstruction meeting between representatives of this office, the property owner or planner, city inspector as well as the grading contractor/builder is recommended in order to discuss grading and construction details associated with site development. GEOTECHNICAL ENGINEER OF RECORD (GER) §1.16 Geotechnical Solutions, Inc. is the geotechnical engineer ofrecord (GER) for providing a specific scope of work or professional service under a contractual agreement unless it is terminated or canceled by either the client or our firm. In the event a new geotechnical consultant or soils engineering firm is hired to provide added engineering services, professional consultations, engineering observations and compaction testing, §1.16 Geotechnical Solutions, Inc. will no longer be the geotechnical engineer of the record. Project transfer should be completed in accordance with the California Geotechnical Engineering Association (CGEA) Recommended Practice for Transfer of Jobs Between Consultants. The new geotechnical consultant or soils engineering firm should review all previous geotechnical documents, conduct an independent study, and provide appropriate confirmations, revisions or design modifications to his own satisfaction. The new geotechnical consultant or soils engineering firm should also notify in writing §1.16 Geotechnical Solutions, Inc. and submit proper notification to the City of Carlsbad for the assumption of responsibility in accordance with the applicable codes and standards (1997 UBC Section 3317.8). X. LIMITATIONS The conclusions and recommendations provided herein have been based on available data obtained from the review of pertinent reports and plans, limited subsurface exploratory excavations as well as our experience with the soils and formational materials located in the general area. The materials encountered on the project site and utilized in our laboratory testing are believed representative of the total building addition area; however, earth materials may vary in characteristics between excavations. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California October 2, 2017 Page 29 Of necessity, we must assume a certain degree of continuity underneath the planned construction areas. It is necessary, therefore, that all observations, conclusions, and recommendations be field verified during the project constructions and earthwork operation. In the event discrepancies are noted, we should be contacted immediately so that an observation can be made and additional recommendations issued if required. The recommendations made in this report are applicable to the site at the time this report was prepared. It is the responsibility of the owner/contractor to ensure that these recommendations are carried out in the field. It is almost impossible to predict with certainty the future performance of a new building addition to an existing older building. The future behavior of the new addition building pad is also dependent on numerous unpredictable variables, such as earthquakes, rainfall, and on-site drainage patterns. The firm of SlllS Geotechnical Solutions, Inc., shall not be held responsible for changes to the physical conditions of the property such as addition of fill soils or changing drainage patterns which occur without our observation or control. This report should be considered valid for a period of one year and is subject to review by our firm following that time. If significant modifications are made to your tentative construction plan, especially with respect to finish elevations, building additions and final improvements layout, this report must be presented to us for review and possible revision. This report is issued with the understanding that the owner or his representative is responsible for ensuring that the information and recommendations are provided to the project architect/structural engineer so that they can be incorporated into the plans. Necessary steps shall be taken to ensure that the project general contractor and subcontractors carry out such recommendations during construction. The project geotechnical engineer should be provided the opportunity for a general review of the project final design plans and specifications in order to ensure that the recommendations provided in this report are properly interpreted and implemented. If the project geotechnical engineer is not provided the opportunity of making these reviews, he can assume no responsibility for misinterpretation of his recommendations. SlllS Geotechnical Solutions, Inc., warrants that this report has been prepared within the limits prescribed by our client with the usual thoroughness and competence of the engineering profession. No other warranty or representation, either expressed or implied, is included or intended. Once again, should any questions arise concerning this report, please do not hesitate to contact this office. Reference to our Project No. GI-17-09-139 will help to expedite our response to your mqmnes. Limited Geotechnical Investigation, Proposed New Building Additions and Rear Site Improvements, 2465 Jefferson Street, Carlsbad, California We appreciate this opportunity to be of service to you. SM§ Geotechnical Solutions, Inc. Ste~<a~ CEG #2362 Distribution: Addressee (3, e-mail) Andrew Carlos Architect (e-mail) §.M§ GEOTECHNICAL SOLUTIONS. INC. October 2, 2017 Page 30 REFERENCES -Annual Book of ASTM Standards, Section 4 -Construction, Volume 04.08: Soil and Rock (I); D420 -D5876, 2016. -Annual Book of ASTM Standards, Section 4-Construction, Volume 04.09: Soil and Rock (II); D5877 -Latest, 2016. -Highway Design Manual, Caltrans. Fifth Edition. -Corrosion Guidelines, Caltrans, Version 1.0, September 2003 . -California Building Code (CBC), California Code of Regulations Title 24, Part 2, Volumes 1 & 2, 2016, International Code Council. -"The Green Book" Standard Specifications For Public Works Construction, Public Works Standards, Inc., BNi Building News, 2015 Edition. -California Geological Survey, 2008 (Revised), Guidelines for Evaluating and Mitigating Seismic Hazards in California, Special Publication 117 A, 108p. -California Department of Conservation, Division of Mines and Geology (California Geological Survey), 1986 (revised), Guidelines for Preparing Engineering Geology Reports: DMG Note 44. -California Department of Conservation, Division of Mines and Geology (California Geological Survey), 1986 (revised), Guidelines to Geologic and Seismic Reports: DMG Note 42. -EQFAULT, Ver. 3.00, 1997, Deterministic Estimation of Peak Acceleration from Digitized Faults, Computer Program, T. Blake Computer Services and Software. -EQSEARCH, Ver 3.00, 1997, Estimation of Peak Acceleration from California Earthquake Catalogs, Computer Program, T. Blake Computer Services and Software. -Tan S.S. and Kennedy, M.P ., 1996, Geologic Maps of the Northwestern Part of San Diego County, California, Plate(s) 1 and 2, Open File-Report 96-02, California Division of Mines and Geology, 1 :24,000. -"Proceeding ofThe NCEER Workshop on Evaluation of Liquefaction Resistance Soils," Edited by T. Leslie Youd and Izzat M. Idriss, Technical Report N CEER-97-0022, Dated December 31 , 1997. -"Recommended Procedures For Implementation ofDMG Special Publication 117 Guidelines For Analyzing and Mitigation Liquefaction In California," Southern California Earthquake Center; USC, March 1999. REFERENCES {continued) -"Soil Mechanics," Naval Facilities Engineering Command, DM 7.01. -"Foundations & Earth Structures," Naval Facilities Engineering Command, DM 7.02. -"Introduction to Geotechnical Engineering, Robert D. Holtz, William D. Kovacs. -"Introductory Soil Mechanics and Foundations: Geotechnical Engineering," George F. Sowers, Fourth Edition. "Foundation Analysis and Design," JosephE. Bowels. Caterpillar Performance Handbook, Edition 29, 1998. -Jennings, C.W., 1994, Fault Activity Map of California and Adjacent Areas, California Division of Mines and Geology, Geologic Data Map Series, No. 6. Kennedy, M.P ., 1977, Recency and Character of Faulting Along the Elsinore Fault Zone in Southern Riverside County, California, Special Report 131, California Division of Mines and Geology, Plate 1 (East/West), l 2p. -Kennedy, M.P. and Peterson, G.L., 1975, Geology of the San Diego Metropolitan Area, California: California Division of Mines and Geology Bulletin 200, 56p. -Kennedy, M.P. and Tan, S.S., 1977, Geology of National City, hnperial Beach and Otay Mesa Quadrangles, Southern San Diego Metropolitan Area, California, Map Sheet 24, California Division of Mines and Geology, 1 :24,000. Kennedy, M.P., Tan, S.S., Chapman, R.H., and Chase, G.W., 1975, Character and Recency of Faulting, San Diego Metropolitan Areas, California: Special Report 123, 33p. -"An Engineering Manual For Slope Stability Studies," J.M. Duncan, A.L. Buchignani and Marius De Wet, Virginia Polytechnic Institute and State University, March 1987. -"Procedure To Evaluate Earthquake-Induced Settlements In Dry Sandy Soils," Daniel Pradel, ASCE Journal Of Geotechnical & Geoenvironmental Engineering, Volume 124, #4, 1998. i'Minimum Design Loads For Buildings and Other Structures," ASCE 7-10, American Society of Civil Engineers (ASCE). -"Seismic Constraints on The Architecture of The Newport-Ingelwood/Rose Canyon Fault: Implications For The Length And Magnitude of Future Earthquakes," Sahakian, V., Bormann, J.,Driscoll, N., Harding, A. Kent, G. Wesnousky, S. (2017), AGU. doi:10.1002/2016 JB 013467 1 MEAN HIGH WATER ELEVATION = 4.49· DATE TAKE N: 11-09-2016 THIS MHW ELEVATION WAS DETERMINED BY PROJECTING EXISTING SLOPE DATA GATHERED ALONG THE UPLAN D AND SHORELINE AREA. NO~· HARD BOTTOM DATA WAS GATHERED FOR THE LAGOON AS PART OF THI S DATA. THE MHW ELEVATION IS APPROXIMATE IN NATURE. STRING LINE EXHIBIT " I / ------------~ 100'-0" SETBACK --------- / / EXIST. LIMIT OF WATER SURFACE __( ELEV A !ION = 8.33' ,1 DATE TAK EN: 11-09-201 6 I I I " / I I " / I I I I I I I ) I ) & I I I I I I I I ; I I / I I I j I I / I I :j/ o· -f ;;, 0 "' -, I -·-- I I I ~--,,' ,' . , , ,' ,/ I I I I I I I /.------,-EXISf. BOUNDARY , LL- ---~EXIST. BU ILDING GEOTECHNICAL LEGEND af Qt q Approx. Location of Test Boring Approx. Location of Hand-Dug Test Pit Geologic Cross-Section Fill (Primarily Wall Backfill) Terrace Depos it [ GEOTECHNICAL MAP l EXISL CONC. fROSION CONTROL , ' SlflUCIURE Al BOllOMOF kOCK ~- LINED SWALE ~, \ ' . \\;u \\U C N 89°58'20"1_ 230.29', I z 0 r ~ I ~ L EXIST. P /EXIST.MU LTI-FAMILY RESIDENTIA L HOUSING ~ I I I I I I I I I I I I I I I I I '.:3 0 0 Q_ 0 ~, ;:; "' V, z w w ~ w ru w z ::; EXI CONC EX IST. POOL F.XIST. CONC SHEET INDEX A-1 STRINGLINE EXHIBIT SHEET 1 OF 1 TOPOGRAPHIC SURVEY L-1 LANDSCA PE CONCEPT PLAN A-2.0 FIR ST FLOOR CONCEPT PLAN A-2.1 SECOND FLOOR CO NCEPT PLAN A-2.3 ROOF PLAN RETAINING WALL '--WIIH CHAINLINK fENG B-3 _, o, 0 ' cl. lij · i: >?·~:._ :ii . , " : 0 CXIST. CUkll SU BSECTION 21 2ll~ 0SC (B '1 OF THE CARL SBAD i\,1UNICIP.".L CClDE I-w w 0::: I-(/) z 0 (/) 0::: w LL LL w I -, (3--J 11EW DEVEi OPMEHT FR O,iTliK THE OC EM, SHALL OBSERVE AT A wllNIMUM, AN 0C EM,1 SET8A.CK BAS ED m,1 ·' '\TRll1GI 11,E " METHOD OF MEASUREMENT. l·m EflCL0SED PORTIONS OF A. STRUCTURE SHALL BE PEFJv·IITTEO FURThE 9 SEAW.~F<D THAI\J THOS[ ALLCWEU Br' .C.. Ll11E DRAWfl BETW EEN THE A0 .. JACENT STRU CTURE TO THE NORTH Al,IQ SO UTH; 1,10 DECKS OR OTHER AP PURTEHAl•ICES SH1\LL BE PERi,;IITTED FURTHER SEAWARD TdMI THOSE ALLOWED BY /1 Ll11E IJRAWl1 BETWli:_N THOSE Ol·I TH E ADJA.CEHT STR UCTU RES TO THE 1,10RTH Al✓0 SOUTH REFER TO TOPOGRAPHIC SURVEY PREi'ARED [1'/ PLUMB Lll,E SUR\/E'i lNG li·IC Fi;R ,A RECORD OF COl,IPLETE EXISTll1G SITE C0N0ITI0l1S ~ SCALE: 1/16" 0 1'-0" CI D D "--B D E l >-_J ~ <( LL w _J (.9 z -(J) I-w w 0:::: I- (J) z 0 (J) 0:::: w LL LL w ---:, I.() <O -.:::I" N I- 0 w ---:, 0 0:::: (L □ctl r □□ TI ITTI□ Dr □□ITIIJ□□ to r Mll[GifilM (J) CX) I- C) z C) w N ~ 0) <( w 05 0 0:::: <( (L m~ (J) _J w 0:::: I-<( - 0 (J) I-0 w z w <( 0:::: _J I-w (J) 0 zO 0~ (J) w 0:::: 0:::: w 0:::: LL Q LL ---:, w <( ---:, ~ I.() <O z _J -.:::I" <( N 0 I-(J) I-z (J) 0.. w w 0:::: 0 -0:::: 0 (J) 0 (J) w ow 0:::: <( 0 R LJ[,lliJQJOO J D CJIRLi□rrVHR.oocoo J [C:01?.007 l DLR lJWC [ FIGURE 2 □ uR JIJ □ ITO[]]] u □□□ JI][]]] J JCJL'UI J M rnJR A-1 z 0 M M M co ... M M z 0 " \0 \0 \0 .... M M z 0 0 0 0 Ill .... M' M ',. Di ' . \ ' ' t \ ·-, \ \ , .. \ 16 \ \ \ \ ' TOPO! map printed on 09/05/17 from "SanDiego.tpo" and "Untitled.tpg" 117.36667° w 117.35000° w \ \ ..... '\ --- ' \ 1, ':,~ \ \ 6'.:, "" ' 84 ~ ' ' ·-" ' \ ..__~ ' \ . \ \ ' ' \ ' ...... '. \ \ '- \ '\ \_ \ \ \ \ " \ \ \ Q C. \' ,C--) <" ' ~~-\ " 7 0 ~ ' ·- \ \ I \ ,. '\ \ WGS84 117.33333° W 117 .36667° w 117.35000° W WGS84 117.33333° W ~==i==:::::=:c===:!~====z==:====lMU I I 1!!°° Fm 1 I I I I ¥m I I F I 1000"' Pril!ted from TOPO! C!999 Wild.flo,nr Productions ("""·-topc.eom) z 0 M M M (X) .... M M z 0 " \0 \0 \0 ... M M KEY TO BORING/ TEST PIT LOGS DRILLING & SAMPLING SYMBOLS: B Split Spoon -1-3/8" 1.0., 2" 0.0., Unless otherwise noted HS: Hollow Stem Auger □ Chunk Sample ST: Thin-Walled Tube -2" O.D., Unless otherwise noted PA: Power Auger T Sandcone Density Test IZI Ring Sampler -2.375" 1.0., 2.5'' 0.0., Unless otherwise noted HA: Hand Auger DB: Diamond Bit Coring -4", N, B RB: Rock Bit ■ Bulk Sample or Auger Sample WB: Wash Boring or Mud Rotary The number of blows required to advance a standard 2-inch 0.0. split-spoon sample (SS) the last 12 inches of the total 18-inch penetration with a 140-pound hammer falling 30 inches is considered the "Standard Penetration" or "N-value". For 2.5" O.D. ring samplers (RS) the penetration value is reported as the number of blows required to advance the sampler 12 inches using a 140-pound hammer falling 30 inches, reported as "blows per foot" and is not considered equivalent to the "Standard Penetration" or "N-value". WATER LEVEL MEASUREMENT SYMBOLS WL: Water Level WCI: Wet Cave in DCI: Dry Cave in AB: After Boring WS: WO: BCR: ACR: While Sampling While Drilling Before Casing Removal After Casing Removal N/E: Not Encountered Water levels indicated on the boring logs are the levels measured in the borings at the times indicated. Groundwater levels at other times and other locations across the site could vary. In pervious soils, the indicated levels may reflect the location of groundwater. In low permeability soils, the accurate determination of groundwater levels may not be possible with only short-term observation. DESCRIPTIVE SOIL CLASSIFICATION: Soil classification is based on the unified classification system. Coarse Grained Soils have more than 50% of their dry weight retained on a #200 sieve; their principal descriptors are: boulders, cobbles, gravel or sand. Fine Grained Soils have less than 50% of their dry weight retained on a #200 sieve; they are principally described as clays if they are plastic, and silts if they are slightly plastic or non-plastic. Major constituents may be added as modifiers and minor constituents may be added according to relative proportions based on grain size. In addition to gradation, coarse-grained soils are defined on the basis of their in-place relative density and fine-grained soils on the basis of their consistency. CONSISTENCY OF FINE-GRAINED SOILS Unconfined Standard Compressive Penetration or N- Stren~h, gu, psf value (SS) Blows[Ft. Consisten9: < 500 <2 Very Soft 500-1000 2 -3 Soft 1001-2000 4-6 Medium Stiff 2001 -4000 7-12 4001-8000 13-26 8000+ 26+ RELATIVE PROPORTION OF SAND AND GRAVEL Descriptive Term(s) of other Stiff Very Stiff Hard RELATIVE DENSITY OF COARSE-GRAINED SOILS Standard Penetration or N-Ring Sampler (RSI value (SS) Blows[Ft. Blows/Ft. Relative Densitl 0-3 0 -6 Very Loose 4-9 7-18 Loose 10-29 19-58 Medium Dense 30-49 59-98 Dense so+ 99 + Very Dense GRAIN SIZE TERMINOLOGY constituents Trace With Modifiers Percent of Ory Weight < 15 Major Component of Sample Boulders Particle Size Over 12 in. (300 mm) 15-29 >30 RELATIVE PROPORTION OF FINES Descriptive Term(s) of other constituents Trace With Modifiers Percent of Dry Weight < 15 15-12 >12 Cobbles Gravel Sand Silt or Clay Term Non-plastic Low Medium High 12 in. to 3 in. (300 mm to 75 mm) 3 in. to #4 sieve (75 mm to 4. 75 mm) #4 Sieve to #200 Sieve (4.75 mm to 0.075 mm) Passing #200 Sieve (0.075 mm) PLASTICITY DESCRIPTION Plasticity Index 0 1 -10 11 -30 30+ ~~~ Geotechnical Solutions, Inc. UNIFIED SOIL CLASSIFICATION SYSTEM (USCS) Criteria for Assigning Group Symbols and Group Names Using Laboratory TestsA Soil Classification Group Group Name Symbol Gravels Clean Gravels Cu ~ 4 and 1 5 C. < 3' GW Well-graded gravel' More than 50% of coarse Less than 5% fines' Not meeting above gradation for GW GP Poorly graded gravel' Coarse Grained Soils fraction retained on #4 Gravels with Fines Fines classify as ML or MH GM Silty gravel'·•·" More than 50% sieve More than 12% fines' Fines classify as CL or CH GC Clayey gravel'-0•" retained on #200 Sands Clean Sands Cu~ 6 and 15 C. :S 3' sieve* Less than 5% fines0 Not meeting above gradation for SW 50% or more of coarse Sands with Fines Fines classify as ML or MH SW Well-graded sand' SP Poorly graded sand1 SM Silty sandG·"·' fraction passes #4 sieve More than 12% fines0 Fines classify as CL or CH SC Clayey sandG,H) inorganic Pl> 7 and plots on or above "A" line' Silts and Clal£S Pl < 4 and plots below "A" line' CL Lean clay•·~"' ML SiltK.~M Fine Grained Soils Liquid limit less than 50 organic Liquid Limit -oven dried 50% or more passes Liquid Limit -not dried the #200 sieve• inorganic Pl plots on or above "A" line Silts and Clal£S Pl plots below "A" line <0.75 OL Organic clay'•'·"·• Organic silt'·~"'-0 CH Fat clay'·'<"' MH Liquid limit 50 or more organic Liquid Limit -oven dried Liquid Limit -not dried <0.75 OH Organic clay•-~M.P Organic silt'-~"'-0 Highly organic soils Primarily organic matter, dark in color, and organic odor PT Peat * For soils having 5 to 12 % passing the No. 200 sieve, use a dual symbol such as GW-GC. A Based on the material passing the 3 in. (75 mm) sieve. 8 If field sample contained cobbles or boulders, or both, add "with cobbles or boulders, or both" to group name. c Gravels with 5% to 12% fines require dual symbols: GW-GM well-graded gravel with slit, GW-GC well-graded gravel with clay, GP-GM poorly graded gravel with silt, GP-GC poorly graded gravel with clay. 0 Sands with 5% to 12% fines require dual symbols: SW-SM well-graded sand with silt, SW-SC well-graded sand with clay, SP-SM poorly graded sand with silt, SP-SC poorly graded sand. For classifications of fine-grained soils and fine-grained fraction of coarse- grained soils. Equation of "A" line. Horizontal at Pl=4 to LL=25.5, then Pl=0.73 (LL-20). Equation of "U" line. Vertical at LL=16 to Pl=7, then Pl = 0.9 (LL-8) 60 so :::::-40 Cl. X QJ D E 30 c E V, "' 1i: 20 10 7 4 0 If soil contains ?:15% sand, add "with sand" to group name. G If fines classify as CL-ML, use dual symbol GC-GM, or SC-SM H If fines are organic, add "with organic fines" to group name. If soil contains ?:15% gravel, add "with gravel" to group name. If Atterberg limits plot in shaded area, soil is a CL-ML, silty clay. If soil contains 15% to 29% plus No. 200, add "with sand" or "with gravel" whichever is If soil contains ?:30% plus No. 200 predominantly sand, add "sandy" to group name. M If soil contains ?:30% plus No. 200 predominantly gravel, add "gravelly" to group name. N Pl ?:4 and plots on or above "A" line. 0 Pl <4 or plots below "A" line. Pl plots on or above "A" line. 0 Pl plots below "A" line L H 0 10 16 20 30 40 50 60 70 80 90 100 I iquid lirnit (l l ) ~~~ Geotechnical Solutions, Inc. SM S Geotechnical Solutions, Inc. Test Pit: TP-1 PROJECT: Proposed Building Additions CLIENT: Carefree Holdinm;. LLC PROJECT No.: Gl-17-09-139 PROJECT LOCATION: 2465Jefferson St. Carlsbad Date Excavated: __ 9/_18/_1_7_ Logged By: ---=S=.J.=M:..:.... __ Equipment: _H~a,=dc....:-d=iQ=·------------------------------1 Remarks: No cavina. No aroundwater. Adia::a,t foundation: 9"± dAPn bv 12"± (?) wide. t) DEPTH ~8 (ft) ti:-' (!) . ·-·.:: ..... :~··. ·.··:-· ·::·~>: /:: ,·:•:···.· MATERIAL DESCRIPTION Fl LL (aO: . .-. .... Silty fine to mooium-grainoo said. Brown color. -_.:•.•:·:.-. Dry to . · ... ·.·.-.·. danp. Blocky. Loose to mooium den93. /<·:;> ST-1 ~ 1 )Vi 'TERRACE DEPOSITS(Qt) ... ,. ,• .. •,·• ... . ·:-.. -:_. -:_.·, .. •,•.' .. Fine to mooi um-grai noo saidstone. Si I ty. Roo-brown color. Weatheroo. Friable. Porous. Some.vhat blocky at 1.5feet. Moderately canentoo. Damp. Massive. M ooi um den93 to den93. ST-1 I SM J 5 112.6 85 29 ISP/SM t----"·,..;...:::? ..... :: :: ..... ~ _,__:: -----""""l'"l==:;-:::::i:-..:::=-=-=-...,.-r~:=-------]_J [ 7 116.2 87 44 tjOTIOm OT lest pit ac £.~ Teel. ■ BULK SAMPLE □ CHUNK DENSITY W DENSITY n GROUND T TEST ~ WATER FIGURE 3 SMS GEOTECHNICAL SOLUTIONS, INC. PROJECT: Proposed Building Additions Boring: B-1 CLIENT: Carefree Holdinas LLC PROJECT No.: Gl-17-09-139 PROJECT LOCATION: 2465 Jefferson St. Carlsbad DATE LOGGED: 9/20/2017 BOREHOLE DIA: ---6" LOGGED BY: S.J.M. CONTRACTOR: -'-P~a=ci=fic~D~r=illi=ng~----DRILL METHOD: Tri-Pod Mounted Beaver Drill. Solid Stem Auoer. SAMPLE METHOD: 140 LB. Hammer dronned 30-inches bv race & cathead. 5-Foot ML rods. REMARKS: Some ca vino of the borehole at 1 0' and 15'. No oroundwater. t} bEPTH IC!) (ft) ~g (!) --:·: :·.• ·.: MATERIAL DESCRIPTION Fl LL (af} : Silty fine Scl"ld. Brown color. Dry. Loose to relatively compact. Wci..er Wffi ooded to aid dri 11 i ng. Dcrnp at 2 feet. cti () cti ::i SM ::, .. :-·. \ ST -1 1r1--1-r1";;:;;;;:!-----t-----t----t---t----t I.II 1111111! 30-50/3" 3 11s.a oo 20 -10 : ::::ti<.;: ..... 11 _ :_::::.-::.-:-:.::.: ..... 12-/MII .... . .... . • ..... 13_ ).\J:/ ._ 14 _ ::::/(}:: -.. TERRACE DEPOSITS(Qt): Fine-grained saidstone. Silty. Locally indudes rounded pebbles. Red-brown color. Wea:hered. Frici:>le. Massive. Wf£J<ly to moderately cemented. Dense to very dense. At 6 feet, very low cohesion (running said). Dry. Continues medium dense. ST-1 At 10 feet, running coa-seto medium-grained said. "Clem". Tight. Moist to dry . Semple disturbed cl.. 10 feet . At 13 feet, becomes tai-gray to off-white color . Continuescoa-se-grained said with rounded pebbles. Moist a,d dense. At 15 feet, cave-in. Grooes to dayey saidstone. Conti nues off-white col or with rust-colored staining. lndudesday binder. ST-2 ~my tine sanustoneto saioy si11scone. 1 a, to 011ve color. Very dense to very tight. (May be&rlti~o Formation?) ~ ............ .J....I...J._\ST-3 / ,__ ___ .... t:Sre:o=no=m,....,o:e.:,r-.:00=1ren=o...,1e,....,c1::r-ll1""""" l::l.o,....,r=ea:,..... ___ __, a STANDARD IT! MODIFIED ■ BULK GROUND ~ PENETRATION 1AJ CALIFORNIA SAMPLE 5l.. WATER TEST SAMPLER - SP/SM i.X SP/OC 8-10-11 (21) 50/6" 3 3 ~/ML~ f--'~t----t---;---;!---t----t 36-50/6" 13 FIGURE 4 SMS GEOTECHNICAL SOLUTIONS, INC. Boring: B-2 PROJECT: Proposed Building Additions CLIENT: Carefree Holdinas. LLC PROJECT No.: Gl-17-09-139 PROJECT LOCATION: 2465 Jefferson St .. Carlsbad DATE LOGGED: 9/20/2017 BOREHOLE DIA: 6" LOGGED BY: S.J.M. CONTRACTOR: Pacific Drilling DRILL METHOD: Tri-Pod Mounted Beaver Drill. Solid Stem Auaer. SAMPLE METHOD: 140 LB. Hammer dro□□ed 30-inches bv rooe & cathead. 5-Foot ML rods. REMARKS: No cavina. No aroundwater. () cli w id~ w ... ~'R ~/:: u.6 OEPTH ~(!) ic It' OCz O;:: MATERIAL DESCRIPTION ti oz ~~~ :::,_ ~~i lli,2.-(fl) ~g Vi ::; >-.J:::, -Z~ 1;:...: u1ai-;~-~ ... 100 00 (!) ::::) u ::;U oS: ocO . :;;:; FILL (af): I-1 -SM . Silty fine sand. Light brown color. Dry to moist. Loose .... 2 :,•: . . : : to rela:ively comped . I . . ~ .:•·. -.-·._:•:. ... ST-1 IAi,,.l .JU/'t 0 . . . .... 3 . . ';, . : : :·-.-..:· '•,•' ·,: . TERRACE DEPOSITS (Qt): .. · ... .... 4 .. . : : :,-.. ·: ... :::~-: '.· ·. BP/SM -5 _(/ . . Fine to medium-grained sa1dstone . Silty. Red-brown . : : ........ . .-:::-color . Moist to slightly moist. Very tight to very dense. . . ' ., ' Sanple disturbed ct 2.5 feet. ~ 13-15-15 ::::.\ . : : 6 _6_ (30) . -. : :-·. ST-1 .·.· ., '. tjOnom OT uurt::1101e a: o.o 1t:ltll. B STANDARD !XI MODIFIED ■ BULK "SL GROUND PENETRATION CALIFORNIA FIGURE 5 TEST SAMPLER SAMPLE -WATER SMS GEOTECHNICAL SOLUTIONS, INC. PROJECT: Proposed Building Additions Boring: B-3 CLIENT: Carefree Holdinas LLC PROJECT No.: Gl-17-09-139 PROJECT LOCATION: 2465 Jefferson St .. Carlsbad DATE LOGGED: 9/20/2017 BOREHOLE DIA: -----=-6"_ LOGGED BY: --=S=.J=.M=·----1 CONTRACTOR: ~P~a~c_ifi~c ~D~ril=lin~g~----DRILL METHOD: Tri-Pod Mounted Beaver Drill. Solid Stem Auaer. SAMPLE METHOD: 140 LB. Hammer droooed 30-inches bv rooe & cathead. 5-Foot ML rods. REMARKS: No cavina. No aroundwater. <.J bEPTH iC!l (ft) ~ g (!) MATERIAL DESCRIPTION Silty fine sand. Light brown color. Dry. Mooium denrn to relc:tively comped. ST-1 TERRACE DEPOSITS(Qt): Fine to mooium-grainoo sandstone. Roo-brown color. SI i ghtl y moist. At 1 foot, no sa11ple recovery. Very tight to very dense a,d cementoo. Weter a::!doo tc aid drilling. Very slow to difficult drilling. ST-1 tsouom OT uurt:i1101e a: J.o Tee(. 1iii::jji STANDARD !Tl MODIFIED ■ BULK ~ PENETRATION 1AJ CALIFORNIA SA.MPLE TEST SA.MPLER D GROUND -¥-WATER w ui !C~ <..i 0 ::!: >-1}j I-:::> SM - SM - (/) WI-.... _ :ii: I-ll:z ~] oz ~~* _,:, -Z-~~ mo 00 (.) ::;<.> c:i: OU/'L OU/4 0 u FIGURE 6 ~ u.5 O;:: ~l ~~at (!):,-w C ~~ -- SCALE: l" = 10' EXT'G WALL 70 ~ 60 60 50---'---~T_'E~CE D_EPQSIT [Qt] 50 40 40 SANTIAGO FORMATION {Tsa]? 30 30 -~-- 20 1 20 10 10 FIGURE 7 .. \ \ ' .. \ FAULT-EPICENTER MAP SAN DIEGO COUNTY REGION Indicated Earthquake Events Through A 200 Year Period EPICENTER MAP LEGEND I Ii -;; ¥; ;}. -= 8('0 · 1~Q -~w-a 1!::-'.il _. ; 'J -6! .i!:1 • F "': F. 4 • ~; ~ :: • H,·. "'Ir.,;,,-:. ~.1111· 1Q 1-f _.1\\·.1,•:, •'·'-·· .11: -• • • • -• • • • --------- Map is reproduced from California Division of Mines and Geology, "Epicenters of/ and Areas Damaged by M ~ 5 California Earthquakes, 1800-1999". FIGURE 8 SMS Geotechnical Solutions, Inc. 5931 Sea Lion place, Suite 109 Carlsbad, CA 92010 Project Supervising Lab Tech Supervising Lab Manager 100 90 80 70 l:lO 60 C V) V) ro Cl.. .._. 50 C Q) u .... 40 Q) Cl.. 30 20 10 0 500 100 Carefree Holdings, LLC S.8. S.M.S. ~ 00 ------M M "' Sieve Analysis ASTM D 6913 -04 0 ..-i =1:1: Job# Address Date 0 N =1:1: so 10 5 1 Grain Size (mm) 9/28/2017 I I I I II i I I : I : I : ' : I I 0.5 Gl-17-09-139 2465 Jefferson St., Carlsbad 0 0 ..-i '# Tech 0 0 N =1:1: .... 0.1 0.05 F.A. .... .... ..... 0.01 Cobbles Gravel Sand Coarse I Fine Coarse I Medium I Fine Silt or Clay TP@2.5' 8-1@ 10' D60 0.28 D60 0.5 D60 D60 D30 0.14 D30 0.25 D30 D30 D10 0.016 D10 0.15 D10 D10 Location Depth Symbol uses NAT,w% LL PL Pl Cu (D60/D10) Cc (D230/ D60*D10) TP-1 2.5' -SP/SM 7 17.50 4.38 8-1 10' 0 SP/SW 3 3.33 0.83 Figure# 9 (a) (b) ISOLATION JOINTS CONTRACTION JOINTS NOTES: RE-ENTRANT CORNER REINFORCEMENT NO. 3 BARS PLACED MID-HEIGHT IN SLAB (c) I NO SCALE I RE-ENTRANT CORNER CRACK 1. Isolation joints around the columns should be either circular as shown in (a) or diamond shaped as shown in (b). if no isolation joints ore used around columns, or if the corners of the isolation joints do not meet the contraction joints, radial cracking as shown in (c) may occur (reference ACI). 2 . In order to control crocking of the re-entont corners ( + /-270 degree corners), provide reinforcement as shown in (c). 3. Re-entrant corner reinforcement shown herein is herein is provided as o general guideline only and is subject to verification and changes by the project architect and /or structural engineer based upon slab geometry, location, and other engineering and construction factors. 6116 GEOTECHNICAL SOLUTIONS. INC. Consulting Geotechnical Engineers & Geologists 5931 Sea Lion Place, Suite 109 Carlsbad, California 92010 760-602-7815 smsgeosoLinc@gmail.com lifftl~Al i~O~VION JO[Nf§ ~Ni) i~0 ~NTetAN'f ~ORN~~ ~~[NfORC~M~NV PIOJEC'f WO: FIGURI N~: Gl-17-09-139 10 5o - 40 - 3o -' 2o 10 TYPICAL SWIMMING POOL CONSTRUCTION CONCEPT SCHEMATIC ONLY -NOT FOR CONSTRUCTION SCALE: 1' = 10' Toporslo~ ( T':f P',) 7o I • 12 min. so 40 -20 10 FIGURE 12 DRILL 5/8" DIA. X 6" DEEP HOLES @ 18" C.C., THOROUGHLY CLEAN, DOWEL W/#4 BARS AND EPOXY GROUT I 1_11_1j l MOISTURE BARRI MID-HEIGHT IN S EXISTING/NEW WALL· FOOTING (TYP) EXISTING SLAB (TYP) 2-#4 BARS TOP AND· NOTES: BOTTOM UNDISTURBED SOIL OR · COMPACTED FILL PER GEOTECHNICAL ENGINEER (SEE REPORT} 1'-6" (MIN) I NO SCALE I EXTERIOR WALL (TYP.) 2 CLR (MIN.) I ROUGHEN EXISTING CONCRETE, CLEAN AND APPLY EPOXY BEFORE POURING NEW CONCRETE. RADE ~-- -,--I #4 CONTINUOUS #4116" DOWELS@18" C.C #3 TIES @ 18" C.C. 1. THIS DETAIL IS PROVIDED AS A GENERAL GUIDELINE AND IS NOT FOR CONSTRUCTION. 2. DETAILED GRADE BEAM DESIGN FOR UNDERPINNING SHOULD BE PROVIDED BY THE PROJECT STRUCTURAL ENGINEER. 3. ALL GRADE BEAM DETAILS AND DIMENSIONS SHOULD BE CONFIRMED AND CERTIFIED BY THE PROJECT STRUCTURAL ENGINEER PRIOR TO CONSTRUCTION. §H§ GEOTECHNICAL SOLUTIONS, INC. 5931 Sea Lion Place, Suite 109 Ca rlsbad, California 92010 760-602-7815 smsgeosol.inc@gmail.com TYPICAL GRADE BEAM DETAIL FOR UNDERPINNING WALL FOOTINGS PROJECT NAME: FIGURE NO: Gl -17-09-139 11 SPECIFICATIONS FOR CALTRANS CLASS 2 PERMEABLE MATERIAL (68-1.025) U.S. STANDARD SIEVE SIZE l" 3/4 3/8 No. 4 No. 8 No. 30 No. 50 No. 200 % PASSING 100 90-100 40-100 25-40 18-33 5-15 0-7 0-3 SAND EQUIVALENT> 75 RETAINING WALL --- FILTER /\1\ATERIAL, 3/4" -11" CRUSHED ROCKS (WRAPPED IN FILTER FABRIC OR CAlTRANS CLASS 2 PERMEABLE /\1\ATERIALS (SEE SPECIFICATIONS) WATERPROOFING (TYP) FINISH GRADE 6"MIN. CONCRETE-LINED DRAINAGE DITCH FILTER MATERIAL, 3/4" • lf' CRUSHED ROCKS (WRAPPED IN FILTER FABRIC OR CAL TRANS CLASS 2 PERMEABLE MATERIALS (SEE SPECIFICATIONS) WATERPROOFING [TYP) PROPOSED GRADE 6"MIN. CONSTRUCTION SPECIFICATIONS: I NO SCALE I I NO SCALE I GROUND SURFACE MIN. 90% COMPACTED FILL (TYP) APPROVED FILTER FABRIC (MIRAFI i:o'" 140N) 12" OVERLAP, TYP. z~ ~o = z CX) w ~w ~ 4' PVC PERFORATED PIPE MIN. (SCH 40 OR SDR35) MIN. 1 /2% FALL TO APPROVED OUTLET (SEE REPORT) NATURAL OR GRADED SLOPE TEMPORARY 1 : 1 CUT SLOPE PROPERLY COMPACTED (MIN. 90%) BACKFILLED GROUND ----BENCH AND TIGHTLY KEY INTO TEMPORARY BACKCUT AS BACKFILLING PROGRESSES APPROVED FILTER FABRIC (MIRAFI 140N) 12' OVERLAP, TYP. ------4' PVC PERFORATED PIPE MIN. (SCH 40 OR SDR35) MIN. 1 /2% FALL TO APPROVED OUTLET (SEE REPORT) l. Provide granular, non-expansive backfill soil in l : l gradient wedge behind wall. compact backfill to minimum 90% of laboratory standard. 2. Backdrain should consist of 4" diam1;ter PVC pipe (Schedule 40 or equivalent) with perforations down. Drain to suitable at minimum!%. Provide 3/4" -l ~" c(ushed rocks filter materials wrapped in fabric (Mirofi 140N or equivalent). Delete filter fabric wrap if Coltrans Closs 2 permeable material is used. Compact Class 2 permeable material to minimum 90% of laboratory standard. 3. Seal back of wall with approved waterproofing in accordance with architect's specifications. 4. Provide positive drainage to disallow ponding of water above wall. Drainage to flow away from wall at minimum 2%. Provide concrete-lined drainage ditch for slope toe retaining walls. 5. Use 1 ~ cubic feet per foot with granular backfill soil and 4 cubic foot per foot if expansive backfill is used. 8.116 GEOTECHNICAL SOLUTIONS, INC. Consulting Geotechnical Engineers & Geologists 5931 Sea Lion Place, Suite 109 Carlsbad, California 920 I 0 760-602-7815 smsgeosol.inc@gmail.com TYPI CAL RETAINING WALL BACK DRAINAGE PROJECT NO: FIGURE NO: Gl-17-09-139 13 APPENDIX Design Maps Summary Report r.lUSGS Design Maps Summary Report User-Specified Input Report Title Mr. Christopher Sauer, 2465 Jefferson St., Carlsbad Jue September· 5, 20111/:05:1/ LJIC Building Code Reference Document ASCE 7-10 Standard (wt,ich utilizes LJSGS hazard data available in 2008) Site Coordinates 33.1697°N, 117.3488°W Site Soil Classification Site Class D -"Stiff Soil" Risk Category I/II/III 1¥111..l 1•our.ritw Oceansidl Carlsba'· :rs -Vista S~n Marcos _I Escondido' USGS-Provided Output Ss = 1.145 g s, = 0.439 g SMs = 1.193 g SM1 = 0.685 g Sos= 0.795 g So1 = 0.457 g Page 1 of 2 For information on how the SS and 51 values above have been calculated from probabilistic (risk-targeted) and deterministic ground motions in the direction of maximum horizontal response, please return to the application and select the "2009 NEHRP" building code reference document. J .:. ~ :i ._ ~ J(( For PGAM, T,, c.s, and c., values, please view the detailed report. https://earthquake. usgs.gov /cn2/designmaps/us/summary. php?template=minimal&latitude=... 9/5/2017 Design Maps Detailed Report lilJSGS Design Maps Detailed Report ASCE 7-10 Standard (33.1697°N, 117.3488°W) Site Class D -"Stiff Soil", Risk Category I/II/III Section 11.4.1 -Mapped Acceleration Parameters Page 1 of 6 Note: Ground motion values provided below are for the direction of maximum horizontal spectral response acceleration. They have been converted from corresponding geometric mean ground motions computed by the USGS by applying factors of 1.1 (to obtain Ss) and 1.3 (to obtain S,). Maps in the 2010 ASCE-7 Standard are provided for Site Class B. Adjustments for other Site Classes are made, as needed, in Section 11.4.3. From Figure 22-1 111 Ss=l.145g From Figure 22-2 121 s, = 0.439 g Section 11.4. 2 -Site Class The authority having jurisdiction (not the USGS), site-specific geotechnical data, and/or the default has classified the site as Site Class D, based on the site soil properties in accordance with Chapter 20. Ta ble 20.3-1 Site Classification Site Class A. Hard Rock B. Rock C. Very dense soil and soft rock D. Stiff Soil E. Solt clay soil F. Soils requiring site response analysis in accordance with Section 21.1 Vs Nor Nch Su >5,000 ft/s N/A N/A 2,500 to 5,000 ft/s N/A N/A 1,200 to 2,500 ft/s· >SO >2,000 psf 600 to 1,200 lt/s 15 to SO 1,000 to 2,000 psf <600 lt/s <15 <1,000 psf Any profile with more than 10 It of soil having the characteristics: • Plasticity index PI > 20, • Moisture content w 2:: 40%, and • Undrained shear strength Su < 500 psf -------- See Section 20.3.1 For SI: 1~/s = 0.3048 m/s llb/ft2 = 0.0479 kN/m2 https://earthquake.usgs.gov/cn2/designmaps/us/report.php?template=minimal&latitude=33.... 9/5/2017 Design Maps Detailed Report Page 2 of 6 Section 11.4.3 -Site Coefficients and Risk-Targeted Maximum Considered Earthquake (MCER) Spectral Response Acceleration Parameters Table 11.4-1: Site Coefficient F. Site Class Mapped MCE • Spectral Response Acceleration Parameter at Short Period Ss $ 0.25 Ss = 0.50 Ss = 0 .75 Ss = 1.00 Ss ~ 1.25 A 0.8 0 .8 0.8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 C 1.2 1.2 1.1 1.0 1.0 D 1.6 1.4 1.2 1.1 1.0 E 2.5 1.7 1.2 0.9 0.9 F See Section 11.4.7 of ASCE 7 Note: Use straight-line interpolation for intermediate values of Ss For Site Class = D and Ss = 1.145 g, F. = 1.042 Table 11.4-2: Site Coefficient F. Site Class Mapped MCE • Spectral Response Acceleration Parameter at 1-s Period S1 $ 0.10 S1 = 0.20 S1 = 0.30 S1 = 0.40 s, ~ 0.50 A 0.8 0.8 0.8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 C 1.7 1.6 1.5 1.4 1.3 D 2.4 2.0 1.8 1.6 1.5 E 3.5 3.2 2.8 2.4 2.4 F See Section 11.4. 7 of ASCE 7 Note: Use straight-line interpolation for intermediate values of S1 For Site Class = D and S1 = 0.439 g, F. = 1.561 https://earthquake.usgs.gov/cn2/designmaps/us/report.php?template=minimal&latitude=33.... 9/5/2017 Design Maps Detailed Report Equation (11.4-1): SMs = F.Ss = 1.042 X 1.145 = 1.193 g Equation (11.4-2): SMl = fvS1 = 1.561 X 0.439 = 0,685 g Section 11.4.4 -Design Spectral Acceleration Parameters Equation (11.4-3): Sos =½ SMs = ½ X 1.193 = 0.795 g ------------------------- Equation (11.4-4): Soi =½SM! = ½ X 0.685 = 0.457 g Section 11.4.5 -Design Response Spectrum From Figure 22-12 131 TL = 8 seconds Figure 11.4-1: Design Response Spectrum T < T0 : S0 = S011 ( 0.-4 + 0.6 T /T0 ) T0 STST9 :S,=S05 T6 <TS TL: S1 = S0,JT T>TL:S,=S0,TL/Tl Su, ~0-457 _..._ ___ -------, ______ ---- ' I I io-0.115 1.00:) Pe,,oa. T (,~) Page 3 of 6 https ://earthquake. usgs.gov /cn2/designmaps/us/report. php?template=minimal&latitude=3 3.... 9/5/2017 Design Maps Detailed Report Page 4 of 6 Section 11.4.6 -Risk-Targeted Maximum Considered Earthquake (MCER) Response Spectrum The MCE, Response Spectrum is determined by multiplying the design response spectrum above by 1.5. S,,, ~ 1.19 3 --...-------. s,,. ~ 0.685 -1-----------0 ---------- I I I I I I 7,.~0.115 https://earthquake.usgs.gov/cn2/designmaps/us/report.php?template=minimal&latitude=33.... 9/5/2017 Design Maps Detailed Report Page 5 of 6 Section 11.8.3 -Additional Geotechnical Investigation Report Requirements for Seismic Design Categories D through F From Figure 22-7 141 PGA = 0.452 Equation {11.8-1): PGAM = FPGAPGA = 1.048 x 0.452 = 0.474 g Table 11.8-1: Site Coefficient FPGA Site Mapped MCE Geometric Mean Peak Ground Acceleration, PGA Class PGA s PGA = PGA = PGA = PGA ~ 0.10 0.20 0.30 0.40 0.50 A 0.8 0.8 0.8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 C 1.2 1.2 1.1 1.0 1.0 D 1.6 1.4 1.2 1.1 1.0 E 2.5 1. 7 1.2 0.9 0.9 F See Section 11.4. 7 of ASCE 7 Note: Use straight-line interpolation for intermediate values of PGA For Site Class = D and PGA = 0.452 g, F•oA = 1.048 Section 21.2.1.1 -Method 1 (from Chapter 21 -Site-Specific Ground Motion Procedures for Seismic Design) From Figure 22-17151 CRs = 0.946 From Figure 22-18 161 CR, = 0. 997 https://earthquake.usgs.gov/cn2/designmaps/us/report.php?template=minimal&latitude=33.... 9/5/2017 Design Maps Detailed Report Section 11.6 -Seismic Design Category Table 11.6-1 Seismic Design Category Based on Short Period Response Acceleration Parameter RISK CATEGORY VALUE OF Sos I or II III IV Sos< 0.167g A A A 0.167g S Sos< 0.33g B B C 0.33g S Sos < O.SOg C C D O.SOg S Sos D D D For Risk Category = I and Sos = 0. 795 g, Seismic Design Category = D Table 11 6-2 Seismic Design Category Based on 1-5 Period Response Acceleration Parameter RISK CATEGORY VALUE OF So, I or II III IV So,< 0.067g A A A 0.067g S So, < 0.133g B B C 0.133g s 501. < 0.20g C C D 0.20g S So1 D D D For Risk Category = I and S01 = 0.457 g, Seismic Design Category = D Note: When S1 is greater than or equal t o 0. 75g, the Seismic Design Category is E for bu ildings in Risk Categories I, II, and III, and F for those in Risk Category IV, irrespective of the above. Seismic Design Category = "the more severe design category in accordance with Table 11.6-1 or 11.6-2" = D Note : See Section 11.6 for alternative approaches to calculating Seismic Design Category. References 1. Figure 22-1 : Page 6 of 6 https://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010_ASCE-7 _Figure_22-1. pdf 2. Figure 22-2: https ;//earthquake. usgs.gov /hazards/desig nmaps/downloads/pdfs/201 O_ASCE-7 _Figure_22-2. pdf 3. Figure 22-12: https ://earthquake. usgs.gov /hazards/designmaps/downloads/pdfs/201 O_ASCE-7 _Figu re_22-12. pdf 4. Figure 22-7: https ://earthquake. usgs.gov /haza rds/desig nmaps/ downloads/pdfs/201 O_ASCE-7 _Figure_22-7. pdf 5. Figure 22-17: https ://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010_ASCE-7 _Figure_22-17 .pdf 6 . Figure 22-18 : https ://earthquake. usgs.gov /hazards/desig nma ps/downloads/pdfs/201 O_ASCE-7 _Figure_22-18. pdf https://earthquake.usgs.gov/cn2/designmaps/us/report.php?template=minimal&latitude=33.... 9/5/2017