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Home My WebLink AboutCUP 260D; PALOMAR TRANSFER STATION; UPDATE SEISMIC DESIGN PARAMETERS BASED ON 2016 CBC FOR GEOTECHNICAL INVESTIGATION REPORT, IMPROVEMENTS TO THE PALOMAR TRANSFER STATION EXPANSION PROJECT; 2018-09-19Converse Consultants Geotechnical Engineering, Environmental & Groundwater Science, Inspection & Testing Services September 19, 2018 RECORD COPY Mr. Rick Garcia Project Manager Land Development David Evans and Associates, Inc. 25152 Springfield Court, Suite 350 Santa Clarita, California 91355 ViAY I 3 20'9 LAND DEVELOPMENT E"'-JCJ1:'\[ER1r, G ,hf l,O 'Date Subject: UPDATED SEISMIC DESIGN PARAMETERS BASED ON 2016 CBC for "GEOTECHNICAL INVESTIGATION REPORT, IMPROVEMENTS TO THE PALOMAR TRANSFER STATION" by Converse Consultants dated April 5, 2006 Palomar Transfer Station Expansion Project Orion Street and Faraday Avenue Carlsbad, California Converse Project No. 06-32-110-02 Dear Mr. Garcia, In accordance with your request and approval, Converse Consultants (Converse) has prepared this letter to provide seismic design parameters based on 2016 California Building Code (CBC). In our report dated April 5, 2006, Seismic Design Parameters were based on the then applicable 2001 CBC. Seismic parameters based on the 2016 California Building Code are calculated using the United States Geological Survey U.S. Seismic Design Maps website application and the site coordinates (33.133 degrees North Latitude, -117 .270 degrees West Longitude). The seismic design parameters are presented below: Site Class C Mapped Short period (0.2-sec) Spectral Response Acceleration, Ss 1.057 g Mapped 1-second Spectral Response Acceleration, S1 0.409 Site Coefficient (from Table 1613.5.3(1 )), Fa 1.0 Site Coefficient (from Table 1613.5.3(2)), Fv 1.39 MCE 0.2-sec period Spectral Response Acceleration, SMS 1.057 g MCE 1-second period Spectral Response Acceleration, SM1 0.569 g Design Spectral Response Acceleration for short period, Sos 0.705 Design Spectral Response Acceleration for 1-second period, So1 0.379 g 3176 Pullman Street, Suite 108, Costa Mesa, California 92626 Telephone: (714) 444-9660 • Facsimile: (714) 444-9640 ♦ www.converseconsultants.com CUP 260(D) David Evans and Associates, Inc. Updated Seismic Design Parameters Palomar Transfer Station Expansion Project, Carlsbad, California Converse Project No. 06-32-110-02 September 19, 2018 CLOSURE We appreciate the opportunity to be of continued service to David Evans and Associates, Inc. and KPG Inc., PS. If you have any questions or would like to discuss this letter in greater detail, please do not hesitate to contact us at (626) 930-1200. Sincerely, CONVERSE CONSULTANTS c:;;g:; ✓ d1 ~ ~ Siva K. Sivathasan, PhD, PE, GE, DGE, QSD, F. ASCE Senior Vice President / Principal Engineer Dist.: 1/Addressee via email Encl: General Conditions @) Copyright 2018 Converse Consultants 2 Converse Consultants Geotechnical Engineering, Environmental & Groundwater Science, Inspection & Testing Services October 16, 2018 Mr. Rick Browning, AIA, LEED AP Architect/Project Manager KPG Interdisciplinary Design 3131 Elliott Avenue, Suite 400 Seattle, Washington 98121 Subject: UPDATED RETAINING WALL DESIGN PARAMETERS 2016 CALIFORNIA BUILDING CODE (CBC) Palomar Transfer Station Expansion Project Orion Street and Faraday Avenue Carlsbad, California Converse Project No. 06-32-110-02 Dear Mr. Browning, In accordance wi~~ your request and approval, Converse Consultants (Converse) has prepared this letter to provide retaining wall design parameters based on 2016 California Building Code (CBC). Lateral Earth Pressure Although not anticipated, the following provisional design values may be used for any utility vaults and/or walls below grade that are less than 6 feet high. The earth pressure behind any buried wall depends primarily on the allowable wall movement, type of soil behind the wall, backfill slopes, wall inclination, surcharges, and any hydrostatic pressure. The following earth pressures are recommended for vertical walls with no hydrostatic pressure. Level ressure distribution ressure distribution The recommended lateral pressures assume that the walls are fully back-drained to prevent build- up of hydrostatic pressure. Adequate drainage should be provided by means of permeable drainage materials wrapped in filter fabric installed behind the walls. The drainage system should consist of perforated pipe surrounded by a minimum one (1) square foot per lineal feet of free draining, uniformly graded, 3/4-inch washed, crushed aggregate, and wrapped in filterfabric such as Mirafi 140N or equivalent. The filter fabric should overlap approximately 12 inches or more at the joints. The subdrain pipe should consist of perforated, four-inch diameter, rigid Schedule 40 PVC or ABS (SDR-35) pipe, or equivalent, with perforations placed down. Alternatively, a prefabricated drainage composite system such as the Miradrain G100N or equivalent can be used. The subdrain should be connected to solid pipe outlets, with a maximum outlet spacing of 3176 Pullman Street, Suite 108, Costa Mesa, California 92626 Telephone: (714) 444-9660 • Facsimile: (714) 444-9640 • www.converseconsultants.com Updated Retaining Wall Design Parameters 2016 California Building Code (CBC) Palomar Transfer Station Expansion Project Carlsbad, California Converse Project No. 06-32-110-02 October 16, 2018 100 feet. Waterproofing membranes should be added to the subterranean wall levels for moisture sensitive areas to mitigate moisture migration through the walls. In addition, walls with inclined backfill should be designed for an additional equivalent fluid pressure of one (1) pound per cubic foot for every two (2) degrees of slope inclination. Walls subjected to surcharge loads located within a distance equal to the height of the wall should be designed for an additional uniform lateral pressure equal to one-third or one-half the anticipated surcharge load for unrestrained or restrained walls, respectively. These values are applicable for backfill placed between the wall stem and an imaginary plane rising 45 degrees from below the edge (heel) of the wall footings. Retaining walls taller than 6 feet should be designed to resist additional earth pressure caused by seismic ground shaking based on Section 1615A.1.6 of CBC 2016. A seismic earth pressure of 18H (psf}, based on an inverted triangular distribution, can be used for design of wall. Lateral Capacity Resistance to lateral loads can be provided by friction acting at the base of the foundation and by passive earth pressure. A coefficient of friction of 0.35 may be assumed with normal dead load forces. An allowable passive earth pressure of 300 psf per foot of depth up to a maximum of 2,500 psf may be used for footings poured against properly compacted fill. The values of coefficient of friction and allowable passive earth pressure include a factor of safety of 1.5. Closure We appreciate the opportunity to be of continued service to KPG. If you have any questions or would like to discuss this letter in greater detail, please do not hesitate to contact us at (626) 930- 1200. Sincerely, CONVERSE CONSULTANTS ~ # -= ~rv.~~- Siva K. Sivathasan, PhD, PE, GE, DGE, QSD, F. ASCE Senior Vice President/ Principal Engineer Dist.: 1/Addressee via email Encl: General Conditions {t) Copyright 2018 Converse Consultants -~ .. O,v~ . ....,.=,~ -tt '-~~ ~\\_ l 8 2 CONVERSE CONSULTANTS General Conditions - Right of Entry Client warrants to Converse that It has full legal right to authorize Converse's entry upon the real property where Converse's services are to be performed ('Site' herein) and upon all property, if any, required for ingress and egress to the Site. Client authorizes Converse to enter upon the Site and such adjoining property as is necessary to allow Converse to perform its services. Converse will take reasonable precautions to minimize any damage to the Site; however, Client acknowledges that during the normal course of the performance of Converse's S8!Vices, some damage to the Site may occur. The correction of any damage to the Site (surface or subterranean) shall be the obligation of the Client Information Supplied by Client Client warrants the aCOJracy of any information supplied by It to Converse, acknowledges that Converse will not verify the aCOJracy of such information, and agrees that Converse is entitled to rely upon any such information. Client shall immediately notify Converse in writing of any data, information or knowledge in the possession of or known to Client relating to conditions existing at the Site and shall provide Converse with the location, size and depth of any and all underground tanks, piping or structures existing upon the Site. Client shall defend, indemnify and save harmless Converse, its officers, agents and emplo~s from and against any and all claims, costs, suits and damages, induding attorneys' fees, ansing out of errors, omissions and inaCOJracies in doruments and information provided to Converse by Client. Ownership of Data and Documents; Samples All reports, boring logs, field data, field notes, laboratory test data, calrulations, estimates and other doruments prepared by Converse shall remain the sole property of Converse. Client shall have the right to the use of all data, recommendations, proposals, reports, design criteria and similar information provided to It by Converse ('information' herein); provided, however, that the information shall not be used or relied upon by any party other than Client, save and except as may be required by the design and licensing requirements of the project for which the information is provided; further, such use shall be limited to the particular site and project for which the information is provided. To the extent Client utilizes Converse's information by providing or making the same available to any third party (a) Client agrees to give written notice to any such third party that It may not utilize or rely on any aspect of Converse's information and (b) Client agrees to defend, indemnify and hold Converse harmless against any and all claims, demands, costs, losses, damages and expenses, induding attorneys fees, that may be asserted against or sought from Converse by any such third party. Client's right to the use of the information is expressly conditioned upon Client's prompt payment to Converse of all sums due under the ClienVConverse agreement In the event of Client's nonpayment or partial payment of said amounts, Client agrees that It shall not use any of the information for any purpose whatsoever and shall return the same to Converse within 2 business days upon demand. Converse will retain all samples of soil, rock or other materials obtained in the course of performing its services for a period of thirty (30) days. Thereafter, further storage or transfer of samples to Client may be made at Client's expense upon written request from Client to Converse received by Converse prior to the expiration of the J<Hjay period. Converse shall retain permanent records relating to the Converse services for a period of five (5) years followin9 submittal of Converse's report, dUri!J which period the records will be made available to Client upon reasonable notice given by Client and upon payment to Converse of an amount sufficient to reimburse Converse for its necessary and reasonable expenses in making said records available. Standard of Care and Profeaslonal Responsibility Client acknowledges that the services to be performed by Converse inwlve the use of tests, calQJlations, analyses and procedures which are in a constant state of development, improvement and refinement and that, as such, improvements, changes in methods, and modifications of procedures have been made in the past, are now being made, and are expected to continue to be made in the future. Further, Client recognizes that, while necessary for investigations, commonly used exploration methods, such as drilling borings or excavating trenches, involve an inherent risk. For example, exploration on a site containing contaminated materials may result in inducing cross- contamination, the prevention of which may not be complete using presently recognized sealing methods. Client ~nizes that the state of practice, induding but not limited to the practice relating to contamination or hazardous waste conditions, is changing and evolving and that standards existing at the present time may subsequently change as knowledge increases and the state of the practice continues to improve. Client recognizes that projects containing contaminated materials may not perform as anticipated by Client, even though Converse's services are performed in acoordance with the level of care and skill required of il Further, certain governmental regulations relating to hazardous waste sites may purport to require achievement of results which cannot be Converle Contu-GC00-1 acoomplished in an absolute sense. It is recognized that a satisfactorily designed, constructed and maintained monitoring system may assist in the earty detection of environmental changes allowing for early correction of problems. Unless It is specifically induded in the scope of services to be performed by Converse, Client understands that Converse shall not perform such monitoring. The S8!Vices to be provided by Converse pursuant to the agreement to which these General Conditions are a part shall be provided in acoordance with generally accepted professional engineering, environmental, and geologic practice in the area where these S8!Vices are to be rendered and at the time that S8!Vices are rendered. Client acknowledges that the present standard in the engineering and environmental professions does not indude, and Converse does not extend to Client, a guarantee of perfection of the wor1< contemplated hereby; further, that even In the exercise of normal and reasonable care, errors or omissions may from time to time occur. Except as expressly set forth in these General Conditions, no other warranty, express or implied, is extended by Converse. Converse shall have no duty to supervise, coordinate or otherwise be involved in the performance of S8!Vices or wor1< by any third-party consultant, contractor or subcontractor. Where Converse's services involve field observation of grading, filling and compaction (or any of them), It is agreed: a. That Converse shall in no way be responsible for the manner in which such work is performed by any third party. b. That in the event Converse is to provide periodic observation, Client acknowledges that Converse cannot be responsible for any wor1< performed at a time or times when Converse was not performing its observation services. Converse will not provide an opinion concerning the performance of any third party, save and except to the extent that said work was in fact observed and tested by Converse during the course of construction. c. That where Converse's services indude continuous observation, Client agrees not to allow grading, filling or compaction to be performed at any time or times when Converse is not physically present upon the Site and shall restrict the amount and extent of such grading, filling and compaction to that which can be property observed by Converse personnel present on the Site. d. That in the event Converse is to conduct test borings for Clien~ Client acknowledges that the aCOJracy of said test borings relates only to the specific location in which the boring itself was performed and that the nature of many sites is such that differing subsurface soil characteristics can be experienced within a small distance. As such, Client acknowledges that greater aCOJracy is obtained when the number of test borings is increased. Technical Limitations Client acknowledges and agrees that (1) It is unreasonable to expect Converse to be able to completely evaluate subsurface conditions, even after the most comprehensive exploratory program; (2) site conditions change frequently due to the passage of time, human activities, and dimatic conditions and uncertainties are therefore inherent in the nature of Converse's services and impossible to avoid; (3) the identification of geotechnical and environmental conditions and the prediction of future or concealed conditions is an inexact scientific endeavor; (4) the state of the art of geotechnical and environmental practice is such that Converse cannot guarantee that its recommendations will prove adequate on this project and the Client assumes the risk of any such failure, except as otherwise provided in these General Conditions and that (5) these General Conditions contains specific LIMITATIONS OF LIABILl1Y. Indemnity of Client and Limitation of Llabllity Converse shall indemnify Client, its officers, directors, agents or employees from any daim, demand or liability arising from personal Injury or property loss or damage caused by the sole negligence or willful misconduct of Converse. Anything to the contrary in the agreement to which these General Conditions are attached or in these General Conditions notwithstanding, Converse's liability shall be limited to the lesser of the fees charged to Cl lent by Converse for the services performed for Client, or the sum of fifty thousand dollars. Client may, at its option, increase the maximum amount for which Converse shall be liable by payment of an additional fee. For the maximum liability sum of one hundred thousand dollars, the additional amount to be paid shall be four percent of the total Converse fee charged hereunder; for the maximum liability sum of one million dollars, the additional amount to be paid shall be five percent of the total Converse fees charged hereunder Client acknowledges and agrees that its recovery, if any, shall be satisfied, in the first instance, from the proceeds of Converse's insurance, and to the extent of any deficiency in the available insurance proceeds, then and only then, by Converse. Client acknowledges that Converse has agreed to charge Client a reduced fee for S8!Vices in exchange for the above !imitation of liability and that said reduction in fees is consideration for said !imitation. Client shall defend and save harmless Converse, its officers, directors, agents and employees from all liability, daims and demands, induding expenses of suit and reasonable attorneys' fees arising from personal injuries, induding disease and death, property loss or damage, injury to others ~nduding personnel of Client, Converse or subcontractors perfonning work hereunder), and air or ground pollution or environmental impainnent arising out of or in any manner connected with or related to the pelformance of Converse's services, except where there is a judicial detennination that such injury, loss or damage shall have been caused by the sole negligence or willful misconduct of Converse. Client acknowiedges that Converse has charged Client a reduced fee for services to be perfonned by It in exchange for this hold hannless and that the reduction in fees is consideration for said hold hannless provision. Converse will not be liable for consequential damages of any kind, nature or description. Hazardous Waste, Pollution and Health Hazard Projects ("Hazardous Projects" Herein) Prior to the commencement of services by Converse on any hazardous project, Client agrees to advise Converse in writing of any known hazardous waste or materials existing on or near the Site or if any of said services are to be perfonned in an area where dust, fumes, gas, noise, vibrations or other particulate or nonparticulate matter is in the atmosphere where it raises a potential or possible health hazard or nuisance to anyone working within the area. Anything in these General Conditions notwithstanding, Client shall indemnify and hold Converse, its officers, directors, agents, servants and employees, hannless from any daim, demand or action brought by any party whomsoever, induding employees of Converse which daim, demand or action is based upon injury or damage caused or alleged to have been caused by hazardous wastes or hazardous materials whether or not such waste or materials were known to exist prior to the commencement of services. Client agrees to be responsible for the removal and disposal of any hazardous waste uncovered as a result of the site investigation, induding drill cuttings, unless specifically in duded within the scope of work It is a9reed that the discovery of unanticipated hazardous materials constitutes a changed condition mandating an immediate renegotiation of the scope of services or tennination of services. Converse will at all times endeavor to perfonn in a faithful and trustworthy manner. Client understands that Client or Converse may be required by local and/or state and/or federal statute to report the discovery of hazardous materials to a government agency. Client also understands that Converse may be required by local and/or state and/or federal statute to report the discovery of hazardous materials to a government agency, and that Converse, when practical, will do so only after notifying Client. In the event Converse discovers hazardous material that we believe poses an immediate threat to public health and safety, Converse will use its best judgment to notify appropriate emergency personnel for immediate containment. Client agrees to take no action of any kind against Converse when Converse makes a good-faith effort to fulfill its obligations. Client's Responsibilities Client shall immediately provide Converse with full infonnation in writin~ as to Client's requirements for the services to be provided by Converse and shall designate in writing within five (5) days of the effective date of the agreement to which these General Conditions are a part, a representative to act on Clienfs behalf in conjunction with the services to be provided hereunder. Client shall prompUy review all documents, reports, data and recommendations submitted by Converse and shall communicate with Converse concerning such reviews for the purpose of avoiding delay in the perfonnance of the services to be rendered by Converse. Client shall notify any third party who may perfonn on the Site of the standard of care being undertaken by Converse pursuant hereto and of the limitations of liability contained herein. Client shall require as a condition lo the perfonnance of any such third party a like indemnity and limitation of liability on their part against Converse. Confidentiality Converse shall hold all infonnation provided to it by Client and the results of the work perfonned by it confidential and shall not disdose the same to any third party except where required by Governmental regulatory agencies or as otherwise required by law. Disputes Converse shall have the right to bring a legal action in a state or federal court against Client for any sums due or alleged to be due to it or for services rendered. Except for this right, Converse and Client agree that as an express condition to the right of either party to bring a legal action against the other, they shall first submit any dispute to mediation by a neutral person acceptable to both parties. Each party shall bear its own attorneys' fees, costs and other expenses, except that each party shalf be responsible and pay for one-half of the costs and expenses of the mediator. In the event that legal action is required, the prevailinQ party shall be entitled to recover all of its costs incurred in connection therewith induding, w1thou{ limitation, staff time, court costs, attorneys' fees, consultant and expert witness fees and any other related expenses. In this regard, in order to make the prevailing party whole, the parties acknowledge and agree that the prevailing party shall be entitled to recover all of its costs incurred in connection with the legal action and shall not be limited to ·reasonable attorneys fees' as defined in any statute or rule of court. The obligations, responsibilities, warranties and liabilities of the parties shall be solely those expressly set forth herein. Remedies and limitations of liability shall apply regardless of whether an action is brought in contract, or is based on either party's negligence, or another theory of law. All of the rights, remedies, obligations, tenns, conditions and limitations of liability stated herein shall extend collectively to and be binding upon the parties' partners joint ventures, licensors, successors, assigns, insurers, and affiliates. Client and Converse agree that any legal action with respect lo the services to be perfonned under these General Conditions shall be brought against the parties, and not against individual officers, ConYerle Coosulan1s GC99-1 employees or funner employees of the parties. All legal actions by either party against the other for breach of these General Conditions or for the failure to perfonn in accordance with the applicable standard of care, however framed, that are essentially based upon such breach or failure shall be barred two (2) years from the time daimant knew or should have known of its right to make a daim, but, in any event, not later than four (4) years from substantial completion of Converse's services. Jobsite Safety Converse shall be responsible for its activity and that of its employees on the Site. This shall not be construed to relieve the Clien~ its general contractor or any subcontractor of their obligation to maintain a safe jobsite. Neither the professional activities nor the presence of Converse or its employees and subcontractors shall be understood to control the operations of others, nor shall it be construed to be an acceptance of the responsibility for jobsite safety. Converse will not direct, sueervise or lay out the work of the Client, contractor, or any subcontractors. Converses services will not indude a review or evaluation of the adequacy of the contracto(s safety measures on or near the Site. Schedules Unless otherwise specified in the agreemen~ Converse shall be obligated to perfonn within a reasonable period of time. Converse shall not be responsible for delays in the completion of its services created by reason of any unforeseeable cause or causes beyond the control and/or without the fault or negligence of Converse, induding but not restricted lo acts of God or the public enemy, acts of the Government of the United States or of the several states, or any foreign country, or any of them acting in their sovereign capacity, acts of other contractors with COent, fire, floods, epidemics, riots, quarantine restrictions, strikes, civil insurrections, freight embargoes, and unusually severe weather. Should completion of any portion of the services to be rendered by Converse be delayed beyond the estimated date of completion for any reason which is beyond the control of or without default or negligence of Converse, then and in that event Client and Converse shall mutually agree on the tenns and conditions upon which the services may be continued or tenninated. Invoices Converse shall submit monthly progress invoices to Client, and a final bill shall be submitted upon completion of the services. Within thirty (30) days after receirl of an invoice, Client shall pay the full amount of the invoice. If Cfient objects to al or any portion of any invoice, 11 shall so notify Converse of the same within fifteen (15) da~ from the date of receipt of said invoice and shall pay that portion of the invoice not in dispute, and the parties shall immediately make every effort to settle the disputed portion of the invoice. If Client fails to make payment within thirty l30) days after receipt of an invoice, then Client shall pay an additional monthly seMce charge of one and one-half percent (1½ %) on all such amounts outstanding. The additional charge shall not apply to any disputed portion of any invoice resolved in favor of Client. In the event Client fails to pay any undisputed amount to Converse when due, Converse may immediately cease work until said payment together with a service charge at the rate of 1 ½ % per month, as specified above, from the due date has been received. Further, Converse may, at its sole option and discretion, refuse to perfonn any further work irrespective of payment from Client. In the event that all or any portion of the 1 ½ % service charge provided for herein is deemed to be an interest charge, then and in that event sai<finterest charge shall be limited to the maximum amount legally allowed by law. Client acknowledges Converse's fee schedules are revised annually and agrees that the ~e schedule in effect at the time the services are perfonned shall apply to such seMces. Insurance Converse represents that ii now carries, and will continue to carry during the tenn of the contract to which these General Conditions are a part, Workers Compensation insurance and that, if re9uested, Converse shall provide to Client certificates as evidence of the aforementioned insurance. Assignments Client shall not assign this contract or any portion thereof to any other person or entity without the express written consent of Converse. Nothing contained in this contract or any part thereof shall be construed to create a righf in any third party whomsoever, and nothing herein shall inure to the benefit of any third party. Severabllity If any provision of these General Conditions is finally detennined to be contrary to, prohibited by, or invalid under applicable laws or regulations, such provision will be renegotiated so as to 9ive effect to the intent of the parties to the maximum possible extent Such detennmation and renegotiation shall not affect of invalidate the remaining provisions or these General Conditions. Governing Law These General Conditions shall be governed by and construed under the laws of the State of California. ---... ·--.. ~ - " -.. -· • - • - • -. ' - .. - - - - • - ► ) GEOTECHNICAL INVESTIGATION REPORT Improvements to Palomar T-ransfer Station Orlon Street and Faraday Avenue Carlsbad, Callfornla Prepared For: Riha Construction 8173 Commercial Street Carlsbad, CA 91942 Converse Project No. 06-32-110-01 April 5, 2006 ..: @ Converse Consultants Over 50 Years of Dedication in Geotechnlcal Engineering and Environmental .Sciences April 5, 2006 Mr. Kenneth Riha Riha Construction Co. 8173 Commercial Street La Mesa, CA 91942 • Subject: GEOTECHNICAL INVESTIGATION REPORT Improvements to the Palomar Transfer Station Orion-Street and Faraday Avenue Carlsbad, California Converse Project No. 06-32-110-01 Dear Mr. Riha: . Converse Consultants (Converse) has prepared this report presenting the results of our geotechnical investigation for the proposed improvements to the Palomar Transfer .:station in the City of Carlsbad, California. This report was prepared in accordance with our proposal dated February 17, 2006 and Professional Services Consultant Agreement dated_March 7, 2006. We appreciate the opportunity to be of continued service to Riha Construction Co. If you have any questions, please do not hesitate to contact us at (714) 444-9660. CONVERSE CONSULTANTS ~------,. William H. Chu, G. E. Senior Vice President/Principal Engineer Dist.: 5/Addressee KNMJHC/dlr 185 East Paularlno Avenue, Suite B, Costa Mesa, Callfomla 92626 .... - ... - - • ... -.. ... - - - - - • - - - - - -.... -\ ·- ' I. i- • I I . ! .... I· ! I . L.-- ... ' . - -- • - • - - 1.-.. • - EXECUTIVE SUMMARY Geotachnlcal lnveatlgatlon·Report Improvements to Palomar Tr■nlfer Station Cerisbad, Callfomla Apn15,.2006 Page II The following is a summary of our geotechnical investigation, conclusions and recommendations, as presented In the body of this report. Please refer to the appropriate sections of the report for complete conclusions and recommendations. In the event of a conflict between this summary and the report, or an omission in the summary, the report shall prevail. • The proposed improvement to the existing Palomar Transfer Station is located at 5960 El Camino Real, Carlsbad, California. • The project consists of an addition to the existing ISuilding, new Truck Scale and scale building, parking areas and driveways. All the improvements will likely to be constructed at or near grade . • The site grading and design recommendations provided in this report are based on our understanding of the project, experience with similar projects in the area, and the results of our investigation and laboratory testing. • The field investigation consisted of a field exploration performed on March 9, 2006 including drilling nine (9) exploratory borings (BH-1 through BH-9) within the project site. · • Based on the current exploration borings BH-1 through BH-9, the site for the proposed improvement consists of five (5) to seven (7) feet of fill. The fills soils encountered in the boring are believed to have been derived from the original grading of the site. Underneath the fill, sedimentary bedrock was encountered in our borings. • Groundwater was not encountered in the borings (BH-1 through BH-9) drilled to a depth ranging from 6.5 to 24.5 feet below ground surface (bgs ). Based on the available well data, the recorded highest groundwater table is reported to be 10 feet below ground surface. • There are no known active faulfs projecting toward or extending across the proposed project site. The site is not situated within any currently designated Alquist-Priolo Earthquake Fault Zone of California. The site is, however, located in a seismically active zone. Ground shaking from earthquakes associated with nearby and distant faults may occur during the lifetime of the project. The nearest Type B fault to the site Is the Rose Canyon Fault located about 7.0 miles (11.2 km) from the site. Due to relatively close proximity of the project site to this fault and other adjacent faults there is a high probability of strong shaking at the site during a strong seismic event. However, the potential for ground surface rupture is considered remote. Efl Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc J ) ...,, Geotechnlcal lnvesllgatlon Report lmprovem-,tsto PalomarTranalerSlllllon Carfebad. Cdbmfa April 5, 2006 Page-ID • In accordance with Table 16-J of the California Building Code (CBC, 2001), the geologic subgrade classification wlll be Sc. The site seismic design coefficients in accordance with Tables 16-Q through 16-T are: Na=1.0 Nv=1.0 Ca=0.44 Cv=0.56 • The potentlal of seismic hazards due to the secondary effects of earthquakes including surface fault rupture, seismically induced differential settlement. lateral spreading, and earthquake induced flooding is considered to be low but based on the topography of the site, the potential of seismic Induced landslide is considered to be moderate to low. Based on the site location and elevation, tsunamis and seiches pose a very low hazard to the project site. • Site soils are not susceptible to liquefaction under earthquake ground shaking. • Laboratory tests conducted on representative soil samples indicated the expansion potential of the site soils is low (El=40). • Based on the corrosivity test results, the site soils are considered to be negligible to concrete. Therefore, Type I or II Portland cement is recommended. Electrical resistivity test results indicate that the site soils are severally corrosive to ferrous metals. - - • .. ... ... ... ... .. ... • Earth materials at the site should be excavatable with conventional heavy-duty earth • ., moving equipment. ' • Based on the materials encountered in the exploratory borings, temporary excavations for a short period of time, may be supported using shoring or constructed vertical up to an excavation depth of four (4) feet, at 1 :1 horizontal: vertical (H:V) slope for excavations from four (4) feet to ten (10) feet. • All trench backfill should be compacted to a mImmum relative compaction of 90 percent as per ASTM Standard p1557 test method. • •· The new Truck Scale may be supported on mat foundation founded all on firm and unyielding bedrock or at least two (2) feet of properly compacted fill below the bottom • Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc ... ... .. ... .. ..... ... - ... .. -.... -... -... -. ' - • - - - 1, - • . ' - • - -... Geotechnlcal Investigation Report lmprovwnentll to Palomar Transfer Station Cerlsbad, C8ftfanla April 5, 2006 Page Iv of foundations. The compacted fill should extend at least five (5) feet laterally orto the maximum extent possible . ,. Shallow footings . such as conventional isolated spread footings for the proposed ~~~~=~;n~f~ogn sPJrJJi~i~!~D!~~~~~!~~mr~r~;~~:gs~a~f ~~e s::::1f~: drilled cast-in-place piles are used to support the building, then the upper five (5) feet of soils should not be considered for the vertical and the lateral capacities . • Spread footings for the Transfer Station addition, founded on bedrock or properly- compacted fill may be designed based on an allowable net bearing capacity of 4,000 pounds per square foot (psf). Alternatively, the drill pile's with allowable skin friction of 300 psf driving from the bedrock may be used for the design. • All undocumented fill soils at the new Scale Building and the new Truck Scale area should be removed and replaced as compacted fill. Subgrade soil surfaces that will receive compacted fill shall be scarified to a depth of at least 12 inches and the scarified on site soils shall be moisture-conditioned to 120 percent of optimum moisture content and compacted to a minimum relative compaction of 90 percent. The fill materials placed on scarified and compacted soils should be compacted to 90 percent relative compaction. , • Footings founded on compacted fill, and placed at a depth 24 inches below lowest adjacent grade with at least 18 inches wide, may be designed based on an allowable net bearing capacity of 2,500 psf. The allowable bearing capacity may be increased by 500 psf for each foot of additional embedment depth and 250 psf for each foot of additional width, but should not exceed 4,000 psf. • Resistance to lateral loads and lateral bearing capacity may be provided by the passive earth pressures and frictional resistance at the base of the footing. A coefficient of friction of 0.35 between concrete and soil may be used with the dead load forces. An allowable passive earth pressure of 300 psf per foot of footing depth may be used for compacted soil. The passive resistance should be limited to a maximum of 2,500 psf. Based on our investigation, we believe that the project site is suitable for the proposed development, provided the findings and conclusions presented in this geotechnical investigation report are considered in the planning, design and construction of the project. ~ Converse Consultants CCOC\M:IJOBFILE\2006\32\06-110\06-32110-01 _glr.doc Geolechnlcal lnvestlgaUon Report Improvements to Palomar Transfer Station Carlsbad, California AprilS,2006 Page v · PROFESSIONAL CERTIFICATION This report has been prepared by the staff of Converse Consultants under the professional supervision of the following professionals whose seals and signatures appear hereon. The findings, recommendations, specifications and professional opinions contained in this report were prepared in accordance with the generally accepted professional engineering and engineering geologic principle and practice in this area of Southern California. We make no other warranty, either expressed or implied. Krishnamenon Nadaraja, P.E. Project Engineer • • Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32116-01_gir.doc • Ma Schluter, C.E.G. S ior Engineering Geologist - - - • - - -• • - -.... - ◄ .. - ' . .. • - - .. .i - - - -I • -.. ' - • - • - • .. -,' \. - -.. ' . - - • - • - - • • - • ·1.0 2.0 3.0 TABLE OF CONTENTS Geotechnlcal Investigation Report Improvements to Palomar Tranal'ar Station Carlsbad, Calfomlll Ap,15,2006 Page vi INTRODUCTION ...............................................................................................•... 1 PROJECT DESCRIPTION ..................................................................................... 1 SITE DESCRIPTION .............................................................................................. 1 4.0 SCOPE OF WORK ............................................................................................... 1 5.0 FIELD EXPLORATION AND LABORATORY TESTING ..................................... 2 5.1 FIELD ExPLORATION ............................................... : ............................................. 2 5.2 LABORATORY TESTING ......................................................................................... 2 6.0 SITE CONDITIONS ................................................................................................ 3 6.1 GEOLOGIC SETTING ............................................................................................. 3 6.2 SUBSURFACE CONDITIONS ................................................................................... 4 6.3 EXCAVATABILITY .................................................................................................. 5 6.4 SUMMARY OF LABORATORY TESTING RESULTS ...................................................... 5 6.5 SOIL CORROSIVITY EVALUATION ........................................................................... 6 7 .0 FAUL TING AND SEISMICITY ............................................................................................. 7 7.1 FAULTING ............................................................................................................ ? 7 .2 SEISMIC COEFFICIENTS ........................................................................................ 7 7.3 SECONDARY EFFECTS OF SEISMIC ACTIVITY .......................................................... 8 8.0 EARTHWORK/SITE GRADING RECOMMENDATIONS ..................................... 9 8.1 GENERAL ............................................................................................................ 9 8.2 SUBGRADE PREPARATION .................................................................................... 9 8.3 OVER-EXCAVATION/REMOVAL FOR ADDITION TO EXISTING TRANSFER STATION BUILDING AND NEW SCALE BUILDING ................................................................... 10 8.4 OVER-EXCAVATION/REMOVAL FOR NEW TRUCK SCALE ......................................... 10 8.5 OVER-EXCAVATION/REMOVAL FOR CONCRETE FLAT WORK AND PAVING AREAS ..... 11 8.6 EXPANSIVE SOIL MITIGATION .............................................................................. 11 8. 7 STRUCTURAL BACKFILL ............ • .......................................................................... 11 8. 7.1 COMPACTION ..................................................................................................... 12 8. 7 .2 SHRINKAGE ....................................................................................................... 12 8.8 SITE DRAINAGE .................................................................................................. 13 8.9 PAVING ............................................................................................................. 13 8.10 UTILITIES ........................................................................................................... 14 9.0 DESIGN AND CONSTRUCTION RECOMMENDATIONS .......... ~ ...................... 14 9. 1 GENERAL EVALUATION ....................................................................................... 14 9.2 SPREAD FOOTING DESIGN PARAMETERS ............................................................. 15 ~ Converse Consultants CCOC\M:\J0BFILE\2006\32\06-110\06-32110-01_glr.doc 1. Geotechnlcal IIIYN1lgallon Report lffll)l'OV9IMIII to Palcm■r'Trannr Stallcn C■rllbad, Cdbnla Aj:lrtl5,2006 Page vii 9.3 'DRILLED 'CAST IN PLACE PILES ............................................. ••••••••••••••••••••••••••••••• 16 .9.4 MAT FOUNDATION ••·••••••••••••·•·••••·• ...................................................................... 17 9·.5 RESISTANCE TO LATERAL LOADS ......................................................................... 17 9.4 SLABS-ON-GRADE •••••.•.••••••••••••••••.•.•.•••••.••••••••••.•••..•••••••••.••.•••••••••••••••••••••••••••••• 17 9.5 TEMPORARY SLOPED ExCAVATIONS .................................................................... 19 10.0 GEOTECHNICAL SERVICES DURING CONSTRUCTION ............................... 20 11.0 CLOSURE .......................................................................................................... 20 12.0 REFERENCES .................................................................................................... 22 FIGURES Following Page No. Figure No. 1, Site and Boring Location Plan ................................................................. 1 APPENDICES . Appendix A ......................................................................................... Field Exploration Appendix B .............................................................. : ............ Laboratory Testing Program Appendix C ............................................................................... Earthwork Specifications • ~onvarse Consultanta CCOC\M:\JOBFILE\2006132\06-110\06-32110-01_gir.doc - - • - - - I - - -... - ... ... ... ... - • - • -• - - - - -... --,_ - • - - • - ... ·-i t• ... • - • -.. .- - • - -.. .. , - • 1.0 INTRODUCTION Geotechnlcal lnverigatfon Report lmixo-nems to Palomar Transfer Station car1sbad, C111Kom1a April 5, 2006 Page 1 This report presents the results of our geotechnical investigation performed for the improvement to the existing Palomar Transfer Station in the City of Carlsbad, California. The approximate location of the site is shown in the vicinity map on Figure No. 1, Site and Boring Location Plan. The purposes of this investigation were to determine the nature and engineering properties of the subsurface soils and to provide recommendations for site earthworls and design and construction of foundations for proposed improvements . 2.0 PROJECT DESCRIPTION Based on the information provided to our office, it is our understanding that the proposed project includes construction of an addition to the existing Transfer Station Building, new Truck Scale and Scale Building, parking areas and driveways. All the improvements will likely to be constructed at or near grade . The site grading and design recommendations provided In this report are based on our understanding of the project, experience with similar projects in the area, and the results of our investigation and laboratory testing. 3.0 SITE DESCRIPTION The existing Palomar Transfer Station is a Waste Management Facility, located at 5960 El Camino Real in the City of Carlsbad, California. It is noted that the location of the proposed addition is currently vacant. The new Truck Scale and new Scale Building are currently used by the old truck scale and the existing scale building. The proposed truck parking area is currently used as container storage area. The ground surface elevation varies from 325' MSL (Mean Sea Level) at the north and north westerly side, 31 O' MSL at existing Truck Scale area and the Transfer Station Building and about 300' MSL at truck loading area. 4.0 SCOPE OF WORK The scope of this investigation includes the following tasks: (1) review the project information and available data for the proposed structures, (2) obtain information on the subsurface conditions within the project area, (3) evaluate the data, and (4) provide conclusions and recommendations for the foundation design and construction of the proposed improvements considering current building codes, from a geotechnical standpoint To accomplish these objectives, we: Eii): Converse Consultants CCOC\M:WOBFILE\2006\32\06-110\06-32110-01_glr.doc ) Geotechnlcal lnvesllgatlon'· Raport Improvements to Palomar Trander Station Carlsbad, Callfomla April 5, 2006 Page.2 1. Collected and reviewed the available project data, and previous reports in the site vicinity. 2. Performed a site reconnaissance ofthe existing conditions. 3. Prepared an exploration program for the project. 4. Engaged a contractor to perform test borings, and logged the borings. 5. Performed laboratory tests to aid in dassiflcation of the materials sampled and to obtain data on their engineering properties. 6. Correlated, Interpreted, analyzed, and evaluated the data obtained. 7. Prepared this report to present our conclusions and recommendations. 5.0 FIELD EXPLORATION AND LABORATORY TESTING 5.1 Field Exploration The field exploration, consisting of drilling nine (9) soil borings, was performed on March 9 2006. An engineer visually logged the subsurface conditions encountered in the exploratory borings at the time of drilling and collected soil samples. A more detailed description of the field exploration procedures and the Logs of Borings are presented in Appendix A, Field Exploration. The approximate locations of the borings are shown In Figure No. 1, Site and Boring Location Plan. A total of nine (9) borings (BH-1 through BH-9) were drilled for the project The depths of the borings ranged from 6.5 to 24.5 feet below existing ground surface (bgs). The exploratory borings were advanced using an 8-inch diameter hollow-stem auger drill rig. The drilling was terminated when the refusal of drilling encountered due to bedrock formation. Relatively undisturbed ring and disturbed bulk samples of the subsurface materials were obtained from the borings at selected Intervals for the purpose of laboratory testing. 5.2 Laboratory Testing • Representative samples of the site soils were tested in the laboratory to aid in the soils classification and to evaluate the relevant engineering properties of the site soils. These tests included: •· In-situ moisture content and dry density (ASTM Standard D2216) .. Grain size analysis (ASTM Standard D422) ... Percent passing sieve No. 200 (ASTM Standard D1140) •· Maximum dry density and optimum moisture content (ASTM Standard· D1557) ~ Converse Consultants CCOC\M:WOBFILE\2006\32\06-110\06-32110-01__glr.doc -• -• - - • - ... 11 ... - ... ... - ... • - • - . . - • • - .. .... - - • - • - - • - ... - - .. • -.. - • Ir, -.. ·• Collapse (ASTM Standard D5333) • Direct shear (ASTM Standard 03080) • Expansion index (ASTM Standard D4829) • Atterberg Limits (ASTM D4318) • R-Value (ASTM D2844) Geotechnlcal Investigation Report Improvements ID Palomar Transfer Station Carillbad, Callfcmla April 5, 2006 Page3 • Soil corrosivity (California test 643 and ASTM D512, D156 and G57) For a description of the laboratory test methods and test results, see Appendix B, Laboratory Testing Program. For in-situ moisture and dry density data, see the Logs of Borings in Appendix A, Field Exploration. • 6.0 SITE CONDITIONS A general description of the subsurface conditions and various materials encountered during our field exploration at the site are presented in this section. 6.1 Geologic Setting Geo/ogle Setting The project site lies along the central coastal margin of the Peninsular Ranges Geomorphic Province of California. Some interpretations of the western boundary for the Peninsular Ranges extend westward beyond the present-day coastline Into the offshore continental shelf. The Peninsular Ranges province is characterized by northwest trending valleys and mountain ranges, which have formed in response to the regional tectonic forces along the boundary between the Pacific and North American tectonic plates. The geologic structure is dominated by northwest trending right-lateral faults, most notable, the San Andreas Fault, San Jacinto Fault, Elsinore Fault and Newport-Inglewood Fault. This Province extends southward from the Transverse Ranges at the north end of the Los Angeles basin to the southern tip of the Baja California peninsula . The coastal margin of the Peninsurar Ranges has undergone coastal erosion during the past 1 million years (Holocene and Pleistocene Epochs). Marine erosion and wave action has cut terraces into the coastal margin. The width of the terraces was a function of the lengths of stable geologic time periods. These periods of stability. were also influenced by sea level fluctuations during glacial advances and retreats and vertical tectonic movement. Generally, the longer the stable time interval the wider the resulting terrace. Once the terrace platforms were elevated by emergent tectonic uplift or glacial sea level changes beyond the reach of the sea, continental erosion and mass wasting. processes took over and gradually altered them . @;'. Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc ( - Geotechnlcal Investigation Report lmprovanents to Palomar Transfw Sta11on - C■rlabad, CaltfDml■ April 5, 2006 • Page-4 During the final Pleistocene glacial stage (about 14 to 16 thousand years ago), the sea level was lowered about.200-300 feet. This forced streams crossing the terraces to cut deep gullies and canyons into the terrace platforms and readjust to the new base sea levels. The amount of down cutting and width of the channel or valley was dependent on the size of the stream tributary or river. As the continental ice sheets melted and the postglacial sea levels rose, the lower ends of the channels and. valleys were flooded by the rising ocean and filled with sediments from stream deposition and shoreline processes. The channels mouths were gradually filled with continental alluvial deposits to form the present day features. The plant site is located on the coastal plain north of.Palomar Airport Road and east of El Camino Real. The underlying sediments consist mostly of fine grained fill soils placed during previous site grading and natural soils. Natural bedrock materials composed of elastic sedimentary rock formations of marine and nonmarine origin were encountered beneath the fills. These bedrock units consist of gravel, cobble and boulder size conglomerates with thin lenses of sandstone, siltstone and claystone. These bedrock units are reported to comprise the Lusardi Formation on of the Upper Cretaceous Rosario Group. The project site is not located within a currently designated Alquist-Priolo Earthquake Fault Zone of California. No faults with evidence of surface rupture are known to project through or towards the plant site. The site is located along the coastal margin between the active Elsinore Fault and the offshore Newport-Inglewood Fault. 6.2 Subsurface Conditions 6.2.1 Subsurface Profile Based on the current exploration borings BH-1 through BH-9, the site for the proposed improvement consists of five (5) to seven (7) feet of fill. The· fill sells encountered in our exploratory borings consist of silty sand, clayey sand, and clay. The fill is likely to have been derived from the original grading of the site. The documentation (The report by Vinje and Middleton Engineering, Inc. entitled "Limited Soi/ and Foundation Study, Proposed Recycling and Building Expansions, ADJ Sorting Facility, 5960 El Camino Real, Carlsbad, Californian, dated 'March 23, 1995) provided to our office for review at the time this report was prepared Is not adequate to determine that the fill soils were placed as engineered fill. Underneath the fill, bedrock consists of sedimentary rock formations consist of sandstone and claystone broken in to silty sand, silt, clayey sand, clay with sand and clay with elastic rock materials (gravels, cobbles and boulders) encountered to the maximum explored depth of 24.5 feet. @,-Converse Consultants CCOC\M:IJOBFILE\2006\32\06-110\06-32110-01 _glr.doc -• - ... - - - • - - -... -... "" .. - 11 - • - - • - -... L - - • - • 6.2.2 Groundwater Geolllchnlcal lnves11gatlon Report lmpl'OVlll1lenls to Palomar Transfer Station Carlsbad, Cellfomla April 5,.2006 Page5 Groundwater was not encountered in the exploratory borings drilled to the maximum depth of 24.5 feet below ground surface. Based on the available well data, the recorded highest groundwater table Is reported to be 1 O feet below ground surface. It should be noted that the site is on elevated terrace and the groundwater may be higher than the reported depth below surface. 6.2.3 Subsurface Variations • -Based on results of the subsurface exploration and our experience, some variations in the continuity and nature of subsurface conditions within the proje~ site should be anticipated. Because of the uncertainties involved in the nature and depositional characteristics of the ... earth material at the site, care should be exercised in interpolating or extrapolating subsurface conditions between or beyond the boring locations. .. 6.3 Excavatab/1/ty ... , ... - - • - • - - • - • · The fill and native materials encountered in the exploration are generally dense to very dense. It is our opinion that the earth materials at the site can be excavated by conventional heavy-duty earth moving and trenching equipments. 6.4 Summary of Laboratory Testing Results Laboratory testing was performed to determine the physical characteristics and engineering properties of the subsurface soils. Discussion on the various test results is presented below: • In-situ Moisture and Dry Density -Results of in-situ moisture and dry density tests are presented on the Logs of Borings in Appendix A, Field Exploration. In-situ dry density and moisture content of the site soil ranged from 92 to 118 pounds per cubic feet (pcf) and 6.5 to 25.0 percent, respectively . • • Maximum Dry Density and Optimum Moisture Content -Typical moisture-density relationships of the representative near surface soil is presented in Drawing No. B-3, Moisture-Density Relationship Results, In Appendix B, Laboratory Testing Program . The laboratory maximum dry density and optimum moisture content of the sample tested was 129.0 pounds per cubic feet (pcf) at 9.5 percent moisture content. • Direct Shear -Results of direct shear test are presented In Drawings No. 8-5 and B-6, Direct Shear Test Results, in Appendix B, Laboratory Testing Program. The results indicate that the site soils have moderate shear strength. ~, Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr.doc ( ... ' . Geotechnk:111 Investigation· Report lmprovanenbl to F'alomarTranafw Station - Carlsbad, Callbmla Ap,15,2006 Page,e ·• Expansion Index -Representative samples from the upper five (5) feet of the site sells were tested to evaluate Expansion Index (El) In accordance with the California Building Code (CBC, 2001) Standard. Test results are Included In Appendix B, Laboratory Testing Program. The value of the measured El was found to be 40. This value of El Indicates that the site soils have low expansion potential. • Consolidation -Results of Consolidation test is presented In Drawings No. B-4, Consolidation Test Results, In Appendix B, Laboratory Testing Program. The results indicate that the site clayey soils have slightly to moderately compressible. • R -Value -Results of R -Value test is presenteQ in Table No. B-4, R -Value Test Results, in Appendix B, Laboratory Testing Program. The results indicate that the subsurface sandy soils have low soil resistance to penetration. 6.5 Soil Corroslvlty Evaluation Laboratory tests were performed by EGL, Inc. at Santa Fe Spring, California on selected soil sample from Boring BH-7 at depths between 0;0 to 5.0 feet to make a preliminary assessment of the soil corrosion potential. The test results (sulfate and chlorides content, resistivity and pH) are summarized In Appendix 8, Laboratory Testing Program. Test results on the selected sample indicated sulfate concentration of 0.011 percentage by weight. Soils with sulfate concentration less than 0.1 percentage by weight are generally reported to have a negligible corrosive effect on foundation concrete. Type I or Type II Portland cement may be used for concrete in contact with these soils. This should be confirmed by additional testing during or upon completion of site grading. Laboratory tests (soluble chlorides, pH and resistivity) indicated that the site soils are severely corrosive to metallic installations. Consideration may be given to retaining a corrosion engineer to more thoroughly evaluate the corrosion potential of any proposed subsurface piping or other metallic installation. Some general, conventional corrosion mitigation measures include the following: • All steel reinforcement should have at least three (3) inches of concrete cover where cast against soil, unformed. •· As a minimum, below-grade ferrous metal should be given a high-quality protective coating, such as 18-mll plastic tape, extruded polyethylene, coal-tar enamel or Portland cement mortar. Below-grade metals should be electrically insulated (isolated) from above-grade metals by means of dielectric fittings in ferrous utllities and/or exposed metal structures breaking grade. @;Converse Consultants, CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr.doc - - • - - • - • - - • - ◄ - ... ... ·• ... • - - - • - -.... - - • - - • ...... .... ... -( .. - .... , • - • - • - 7.0 FAULTING AND SEISMICITY 7. 1 Faulting Geotechnlcal Investigation Report Improvements to Palomar Transf8r Sllltlon carilbad, catltbml■ Aprl 5,2006 Page7 There are no known active faults projecting toward or extending across the project site. The site is not situated within a currently designated Alquist-Priolo Earthquake Fault Zone of California . The site is situated within the seismically active region of southern California. Although there are no documented active faults projecting towards or transecting the site, there are a number of nearby faults, which could produce significant ground shaking at the site during a major earthquake. The project site Is located within close proximity of several active faults. The closest active type B fault to the site Is the Rose Canyon Fault, which is mapped approximately 7.0 miles (11.2 km) southwest of the site . Earthquake intensities will vary throughout southern California, depending upon the magnitude of the earthquake, the distance of the site from the causative fault, and the type of materials underlying the site. The site will probably be subjected to at least one moderate to severe earthquake during its design life that will cause strong ground shaking. Based on our analysis the site could be subjected to a peak ground acceleration of about 0.30g (Alluvium/Bedrock Condition) with a 1 0 percent probabillty of exceedance In 50 years. A magnitude of 6.9 was noted as the predominant earthquake that contributes most to the hazard at 1 0 percent probability of exceedance in 50 years on the alluvial site condition. 7.2 Seismic Coefficients The site is located within Seismic Zone 4 in accordance with the California Building Code (2001 CBC). Based on the results of our borings, laboratory testing, and in accordance with CBC, the site should be considered as having a Sc profile. The following seismic coefficients are c~nsidered appropriate for analysis: Seismic Zone Factor, Z ........................................ 0.40 Nearest Fault.. ............................. Rose Canyon Fault Distance to the Fault.. .................................. 11.2 km Soil Profile Type ................................................... Sc Seismic Source Type......... ..................................... B Seismic Coefficient, N8 .......................................... 1.0 Seismic Coefficient, Nv .....................................•.... 1 .1 Seismic Coefficient, c •........................................ 0.44 Seismic Coefficient, Cv ...................................... 0.56 ~ Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110'-()1 .,Jllr;doc ( ( \ ) 7.3 Secondary Effects of Seismic Activity Geotechnlcal Investigation Report lmprovsnents 1D Palomar Transfer Station Carlabad,Cafflcmta Aprfl 5, 2006 Pages In addition to ground shaking, effects of seismic activity on a project site may Include surface fault rupture, soil liquefaction, and seismically induced differential settlement of structures; ground lurching, landsliding, lateral spreading, earthquake-induced flooding, seiches, and tsunamis. Results of a site-specific evaluation of each of the above possible secondary effects are explained below: Surface Fault Rupture: The project site is not located within a currently designated Alquist-Priolo Earthquake Fault Zone of California .• Based on our review of existing geologic information, no known major surface fault crosses through or extends towards the site. The potential for surface rupture resulting from the movement of a previously unrecognized fault is not known with certainty but is considered low. Landslides: Seismically induced landslides and other slope failures are common occurrences in areas of significant ground slopes during or soon after earthquakes. Based on the topography of the project site, the potential for seismically induced landslides to affect the site is considered moderate to low. Lateral Spreading: Seismically induced lateral spreading involves primarily lateral movement of earth materials due to ground shaking. It differs from the slope failure in that complete ground failure involving large movement does not occur due to the relatively smaller gradient of the initial ground surface. Lateral spreading is demonstrated by near-vertical cracks with predominantly horizontal movement of the soil mass involved. Based on the topography at the project site and in the immediate vicinity of the site along with the subsurface conditions encountered in the Investigation, the potential for lateral spreading at the subject site is considered low. Earthquake-Induced Flooding: Flooding may be caused by failure of dams or other water retaining structures due to earthquake. Based on our review, no significant dams or other enclosed bodies of water are present in the vicinity of the site. The potential of earthquake-induced flooding is considered low. Tsunamis: Tsunamis are seismic 'Sea waves generated by fault displacement or major ground movement. Based on the location and elevation of the site, tsunamis pose a very low hazard to the site. Selches: Seiches are large waves generated in enclosed bodies of water in response to ground shaking. Review of the area adjacent to the site indicates that there are no significant up-gradient lakes or reservoirs with the potential of flooding the site. Soil Liquefaction and Seismic Induced Settlement: Liquefaction is defined as the phenomenon in which a cohesion less soil mass within about upper 50 feet of the ground surface, suffers a substantial reduction In its shear strength, due the development of {!) Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr.doc - • - - - - - - ... ... '"' ... - - • ... - • - .... • - -.... - • - • - ... , Geotechnlcal Investigation Report lmprovernenta ID Palomar Transfer Station Caliabad, CallfDmla April 5, 2006 Page9 excess pore pressures. During earthquakes, excess pore pressures in saturated soil deposits may develop as a result of induced cyclic shear stresses, resulting in liquefaction . Soils that are most susceptible to liquefaction are clean, loose,· saturated, and unifonnly graded, fine-grained sands that lie below the groundwater table within a depth usually considered to be about 50 feet deep. The groundwater was not encountered in our exploration, and based on the available well data in the vicinity of the project, the recorded depth to the high groundwater is about 8.5 feet below ground surface. Based on the results of the subsurface conditions encount~red in the investigation, the soils beneath the recorded highest groundwater table in the vicinity generally consisted of bedrock and the potential for the seismic induced settlement is very low. 8.0 EARTHWORK/SITE GRADING RECOMMENDATIONS 8.1 General ... This section contains our general recommendations regarding earthwork and site grading for the proposed development. These recommendations are based on our experience with similar projects in the area and the results of our field exploration, laboratory testing, -and data evaluation as presented in the preceding sections. • Prior to the start of grading, utilities should be located in the field and either re-routed or protected. All debris, concrete foundations, surface vegetation, deleterious material, and surficiai soils containing roots and perishable materials should Initially be stripped and removed from the site. Any unsuitable materials uncovered by the stripping operation should be excavated to expose undisturbed bedrock . : The excavations should not cause loss of bearing and/or lateral supports of the existing · -structures or utilities. .. • - • - - • 8.2 Subgrade Preparation The final bottom surfaces of all e:iscavations should be observed and approved by the project geotechnical consultant prior to placing any fill and/or structures. Any over- excavations for the building should be observed by a Converse representative. Based on observations, removal of localized areas deeper than those documented may be required during grading. Therefore, some variations in the depth and lateral extent of over- excavation recommended in this report may be anticipated . Subgrade soil surfaces that will receive compacted fill shall be scarified to a depth of at least 12 inches and the scarified on site soils shall be moisture-conditioned to 120 percent of optimum moisture content and compacted to a minimum relative compaction of 90 ~ Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr.doc I Geotechnlcal lnveallga11on Report lmprovmnents to Palomar Tr■nsf9t Station C■rlabad, Calfomla April 5, 2006 Page 10 percent. The fill materials placed on scarified and compacted soils should be compacted to 90 percent relative compaction. 8.3 Over-excavation/Removal for Addition to Existing Transfer Station Bui/ding and New Scale Building Based on our field investigation, the upper five (5) feet of the site soils encountered In our exploratory boring are undocumented fill soils in the vicinity of the building addition and the new scale building are not suitable to support the structure. Based on laboratory test results and exploration, the upper site soils have low expansion potential (El=40). l . . The top two (2) feet of on-site soils are not suitable to support the slab-on-grade for these proposed buildings. These materials should be removed and replaced with compacted fill. The clayey fill soils should be brought to at least 120 percent of the optimum moisture and compacted to at least 90 percent relative compaction as per ASTM Standard D1557 test method. The depth of anticipated over-excavation Is about 2 feet. Relative compaction is defined as the ratio of the In-place soil dry density to the laboratory maximum dry density as determined by the ASTM Standard D1557 test method. Conventional isolated spread footings for the addition to existing Transfer Building foundered all in compacted fill or bedrock may be used to support the building. The entire undocumented fill soils shall be removed and replaced as compacted fill, if the footings to be supported on properly compacted fill. The footings for the addition to the existing building shall be setback from the descending slope to a distance equal to one third of the height of the slope. · Conventional footings for the new Scale Building foundered all in compacted fill may be used to support the building and all the undocumented fill soils shall be removed and replaced as compacted fill. The anticipated depth of removal Is about five (5) feet and the removal should extend at least five (5) feet laterally or to the extend possible. The subgrade soils need to be scarified at least 12 inches and recompacted according to the Section 8.2, Subgrade Preparation. 8.4 Over-excavation/Removal for New Truck Scale Based on our exploration, and the information given to our office, the site for the proposed new Truck Scale consists of minimum five (5) feet of fin. Over excavations need to be observed to verify the excavation bottomed to competent bedrock. / ~ Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _gir.doc - - - - • - • -., - - .. .... - - -.. - - • - - • - ( .. ... --... - • - .. ... - -- ... -- Geotechnlcal Investigation Report Improvements to Palanar Tranlfar. Sla11on Csrlsbad, callfomla Aprfl5, 2006 Page 11 The proposed Truck Scale may be supported on mat foundation founded on bedrock or at least two (2) feet of compacted fill. The subgrade soils need to be scarified at least 12 Inches and recompacted according to the Sect/on 8.2, Subgrade Preparation. 8.5 Over-excavation/Removal for Concrete Flat Work and Paving Areas As a minimum, 18 inches of compacted fill should be provided for any concrete flatwork, curbs and gutters and asphalt concrete paving areas. Such over-excavation should extend at least two (2) feet beyond the edges of concrete flatwork or to the extent possible. • 8.6 Expansive So// Mitigation The site soils have low expansion potential. There are several mitigation measures that can be utilized to improve expansive soils at the site. Some mitigation measures include: • Remove and replace with two (2) feet of non-expansive soils • Thicker concrete slabs with moisture barrier and grade beams • Post-tensioned slabs with moisture barrier It is very important to keep the site soils moisture content around or under the edge of foundation, concrete slab, and asphalt concrete pavement at approximately the same moisture content before, during and after construction. This will reduce greatly the expansion potential of the site soils. The site soils have low expansion potential. Slabs, foundations and pavement placed directly on expansive subgrade soil will likely crack over time. The impact of the expansive soil can be reduced by (a) removing about two (2) feet of the under1ying soils below slabs and footings throughout the site, except landscape areas, and replacing with imported sandy material (Expansion Index less than 20), (b) deepen and reinforce footing and place thicker concrete slab with grade beam and moisture barrier, (c) use post-tensioned slab, and ( d) lime treat the upper Ml? (2) feet of the subgrade soils. -8. 7 Structural Backfill .• - - ,. .- All structural fill should be placed on competent, scarified and compacted materials as determined by a geotechnicai consultant representative, and in accordance with the specifications presented in this section. Rocks larger than three (3) inches in the largest dimension should not be placed as fill. Rocks larger than one (1) inch should not be placed within the upper 12 inches of subgrade soils. ~Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01JJir,doc Geotachnlcal Investigation Report Improvements ID PlllomarTranafer S111tlcn Cansbad,Cllllbnlll April 5,.2006 Page 12 Excavated site soils, free of deleterious materials and cobbles/boulders larger than six (6) inches In the largest dimension should be suitable for placement as compacted fill. Any import fill should be tested and approved by Converse prior to delivery to the site. The import fill should be free of organic matter and other deleterious material, non-expansive, with an expansion index less than 20. 8. 7. 1 Compaction This section contains our recommendations for compaction of fill placed in accordance with the specifications provided in Appendix C, Earthwork Specifications and in Section 8.2, Subgrade Preparation. • • All clayey fill, if not noted otherwise, should be compacted to a relative compaction of at least 90 percent as per ASTM Standard D1557 test method at moisture content at least 120 percent of optimum. Relative compaction is defined as the ratio of the in-place soil dry density to the h;tboratory maximum dry density as determined by the ASTM Standard D1557 test method. • All sandy fill, if not noted otherwise, should be compacted to a relative compaction of at least 90 percent and moisture content about 2 percent within the optimum moisture. • All bases and subbase, if any, for pavement structures should be compacted to relative compaction of at least 95 percent as per ASTM Standard D1557 test method. The project geotechnical consultant will observe the placement of compacted fill and conduct in-place field density tests on the compacted fill to check for adequate moisture content and relative compaction as required by the project specifications. Where less than the required relative compaction is Indicated, additional compactive efforts shall be applied and the soil moisture-conditioned as necessary, until the required relative compaction Is attained. The contractor shall provide level testing pads upon which the soils engineer may conduct field density tests. The contractor shall provide safe and timely access for the geotechnical testing personnel throughout the grading operation to allow continuous monitoring and testing, • 8. 7.2 Shrinkage The shrinkage would depend on, among other factors, the depth of cut and/or fill, and the grading method and equipment utilized. The average shrinkage factor for the near surface on site soils may be estimated to range from ten (10) to twenty (20) percent. Although these values are only approximate, they represent our best estimates of the factors to be used to calculate lost volume that may occur during grading. If more accurate shrinkage and subsidence factors. are needed, it is recommended that field- testing using the actual equipment and grading techniques be conducted. ~ Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr;doc -.. - • - • ... • - - - -• - • .... .. -• .. ... .. ... - • - • - - - ... , ...... , \ Geotechnlc;al lnves11gatlon Raport lmprovementll to Palomar Transfer Station Carlsbad, Callfornla April 5, 2006 Page 1~ .... 8.8 Site Drainage - .... - .... - ... - - - • - - ... , • • - • Adequate positive drainage should be provided away from building pad areas to prevent ponding and to reduce percolation of water into the foundation soils. Building pads should have a drainage gradient of at least two (2) percent towards drainage devices. Planters and landscaped areas adjacent to the building pad perimeter should be designed and irrigated to minimize water infiltration into the subgrade soils . Adequate drainage should also be provided for any cut/fill slopes, landscaped and paved areas. A desirable drainage gradient is one (1) percent for paved areas and two (2) percent in landscaped areas. Surface drainage should be directed to suitable non-erosive devices. Slope drainage should be constructed in accordance with Appendix Chapter 33 of the California Building Code (2001 ) . 8.9 Paving All areas to be paved should be graded in accordance with the general recommendations for site grading presented under the Section 8.0, Earthwork/Site Grading Recommendation. If the proposed pavement subgrade areas have become disturbed or desiccated after the site grading and prior to placing the base course, the subgrade may have to be re-scarified to a depth of at least 12 Inches, be moisture conditioned as required to obtain optimum moisture conditions, and be recompacted to at least 90 percent of the maximum dry density. This decision will be made at the time of construction by our field representative. One R-value test was performed on a bulk sample of the on-site surface soils from boring BH-9. The results of this test are presented in Appendix B, · Summary of Laboratory Test Results, and indicate an R-value of 11. Based on this R-value and the selected traffic index values indicated below, the following minimum flexible pavement sections were computed for budget purposes. Our computations were based on the Ca/trans Highway Design Manual, fourth edition: PAVEMENT COMPONENT THICKNESS {Inches) ' Tl• 5.5 Tl ■.6:'!i . 11:-a 7,;5· Tl•8:5 Asphalt Concrete (AC) 3.0 4.0 Aggregate Base (AB) 11.0 12.5 Total Pavement Thickness 14.0 16.5 ~··converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr:doc . 4.5 5.0 15.0 18.0 19.5 23.0 Tl •11;5 6.0 20.0 26.0 I i. ( ' . ! - ' ... Geoteohnlcal IIMISllgallon Report lrnprovemen1s ID PalcmarTranafw.Stalon - cartabad,Cdfomla April 5. 2006 • Page 14 The actual R-value will depend on the compacted fill at the subgrade level. We recommend that R-value tests be performed during grading to confirm design pavement section indicated above. Additional pavement sections can be presented upon request for imported fill subbase or for different traffic index values. Selection of the traffic Indices should be made by your civil engineer based on his knowledge of traffic flow and loading. The base course should be crushed aggregate base or processed natural material conforming to Section 200-2.2 or 200-2.4, Standard Specifications for Pub/le Works Construction (Green Book 2003). The aggregate base and asphalt concrete should be compacted to at least 95 percent of the maximum dry density In accordance . with ASTM D1557-00. 8. 10 Utilities The on-site soils are suitable for backfill of utility trenches from one foot above the top of the pipe to the finished grade, provided the material is free of organic matter and deleterious substances. It is anticipated that the compacted fill will provide a firm foundation for site utilities. Any soft and/or unstable material encountered at the pipe invert should be removed and replaced with an adequate bedding material. The on-site soils are not considered suitable for bedding or shading of utilities. Therefore, we recommend that non-expansive granular soils with a Sand Equivalent (SE) greater than 30 as determined by ASTM Test Method D2419 be imported for that purpose. Trench backfill soils should be compacted to at least 90 percent of the maximum dry density as determined by ASTM Test Method D1557. 9.0 DESIGN AND CONSTRUCTION RECOMMENDATIONS 9.1 General Evaluation Based on our field exploration, laboratory testing and analyses of subsurface conditions at the site, remedial grading is required to prepare the site for support of the various structures. Shallow footings such as conventional isolated spread footings for the proposed Transfer Station addition and Truck Scale Building founded on bedrock or compacted fills shall be setback from the descending slope to a distance equal to one third of the height of the slope. If the drilled cast-in-place piles are used to support the building, then the upper five (5) feet of soils should not be considered for the vertical and the lateral capacities. The new Truck Scale may be supported on mat foundation founded all on undisturbed bedrock or at least two (2) feet of properly compacted fill below the bottom of foundations. The compacted fill should extend at least five (5) feet laterally or to the maximum extent possible; @: Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc ... ... ... • ... - - - ... - ◄ - - - • - - • ... • - • - .... Geotechnlcal Investigation· Report lmpnwements ID Palomar Transfer Sidon Carisblld, calltlmla April 5, 2006 Page 15 The various design recommendations provided in this section are based on the assumption that in preparing the site, the above earthwork and grading ... recommendations will be implemented. ... 9.2 Spread Footing Design Parameters Spread footings for the Transfer Station addition, founded on bedrock or properly compacted fill may be designed based on an allowable net bearing capacity of 4,000 -pounds per square foot (psf) . • - - - - - • ... • .. - -.. - - •· -.. ) All undocumented fill soils at the new Scale Building and the new Truck Scale area should be removed and replaced as compacted fill. Subgrade soil surfaces that will receive compacted fill shall be scarified to a depth of at least 12 inches and the scarified on site sons shall be moisture-conditioned to 120 percent of optimum moisture content and compacted to a minimum relative compaction of 90 percent. The fill materials placed on scarified and compacted soils should be compacted to 90 percent relative compaction. Footings founded on compacted fill, and placed at a depth 24 inches below lowest adjacent grade with at least 18 inches wide, may be designed based on an allowable net bearing capacity of 2,500 psf. The allowable bearing capacity may be increased by 500 psf for each foot of additional embedment depth and 250 psf for each foot of additional width, but should not exceed 4,000 psf. The footing reinforcement should be based on structural design. The allowable net bearing capacity is defined as the maximum allowable net bearing pressure on the ground. It is obtained by dividing the net ultimate bearing capacity by a safety factor. The ultimate bearing capacity is the bearing stress at which ground fails by shear or experiences a limiting amount of settlement at the foundation. The net ultimate bearing capacity Is obtained by subtracting the total overburden pressure on a horizontal plane at the foundation level from the ultimate bearing capacity. The net allowable bearing values indicated above are for the dead loads and frequently applied live loads and are obtained by applying a factor of safety of 3.0 to the net ultimate bearing capacity. If norJllal code requirements are applied for design, the above vertical bearing value may be increased by 33 percent for short duration loadings, which will include loadings induced by wind or seismic forces. The maximum anticipated settlement of a square footing founded on compacted fill is estimated to be less than ½-inch for a five (5) foot square footing and the differential settlements are expected to be on the order of ¼-inch between adjacent footings . ~· Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _gir,doc ( 9.3 Dr/1/ed Cast in Place Plies Geotechnlcal Investigation Report lmpro-,,ents to Palomar Transfer Slllllon Cartsbad,Callbnia April 5, 2006 Page 16 Drilled cast in place plles are another alternative foundation system and the piles deriving their capacities primarily from the bedrock about five (5) feet below the existing grade. We recommend that the grade beam, footings, and slab be supported on the piles if piling is the selected alternate. The allowable design allowable skin friction of 300 psf driving from the bedrock may be used for the design. The capacity was computed by using a safety factor of two (2) for skin friction. The settlement of a single pile is expected to be about one-fourth (¼) inch. The vertical capacities above may be increased by 33 percent to resist transient downward vertical loads, such as wind forces or seismic shaking. Pile uplift design capacities may be taken as 50 percent of the vertical downward pile design values shown. The drill cast in place pile should have a minimum diameter of 14 inches and the spacing between piles should not be less than three (3) times the pile diameter. Allowable axial loads of pile groups with center-to-center pile spacing of less than three (3) pile diameters should be determined by incorporating an efficiency reduction factor to the allowable axial loads for single piles. Based on the subsurface conditions, the piers can be drilled without casing. However, if caving or an unstable hole is encountered, a temporary casing may be required. Drilled pile excavations should be filled with concrete on the same day they are drilled. The drilling for piles should not be performed adjacent to recently excavated or recently poured piles until the concrete in the completed piles has been allowed to set for several hours. In addition, the piles should also be poured in a manner that will not result in concrete flowing into adjacent open pile excavations. Piles in groups should be drilled and poured in an alternating sequence to minimize the potential for fresh concrete flowing into adjacent open pile excavations. The placement of reinforcement and concreting operations should conform to ACI and other applicable code requirements. Concrete placement should be continuous from the bottom to the top of the drilled pile. Concrete placement should continue after the borehole is filled until good quality ·concrete is evident at the top of the shaft. Concrete should be placed through a tremie or pump system and the discharge end of the tremie/orifice should be immersed at least 5 feet in concrete at all times after the start of the concrete flow. In addition, the level of concrete in the tremie should be maintained above the level of slurry in the borehole at all times to prevent slurry intrusion into the shaft concrete. We recommend that the installation of the drilled piles be performed with the observation of Converse Consultants. ~ Converse Consultants CCOC\M:IJOBFILE\2006\32\06-110\06-32110-01_glr.doc .. ... - .. - - -... .. ·◄ .. .. .. ... .. 11 .. .... .. 11 - .. • - • - - • - - . . .. .... • - - • ·- • -- --- 9.4 Mat Foundation Geotechnlcal Investigation-Report Improvements le Palomar Transfer.Station Carlsbad,Calllcmla Aprfl 5, 2006 Page 17 A mat foundation may be used to support the proposed new Truck Scale. An allowable net bearing capacity of 3,000 pounds per square foot (psf) may be used to support the Truck Scale on competent bedrock or at least two feet of compacted fill. A total settlement within ½-inch with a differential settlement of ¼-iinch is anticipated for a mat foundation placed on competent bedrock or on two feet of properly compacted fill. A modulus of subgrade reaction of 175 pounds per square inch per inch can be used for design of the mat foundation for the tank and booster pump station. This value is based on a unit square foot area and must be adjusted to mats of various widths . • The following equation may be used to calculate k for use in mat foundation design: k= 175[(8+1 )/28) 2 k= Modulus of subgrade reaction, pounds per square inch per inch B= Mat foundation width, feet 9.5 Resistance to Lateral Loads Resistance to lateral loads can be assumed to be provided by friction acting at the base of foundations and by passive earth pressure. A coefficient of friction of 0.35 between concrete and soil may be used with the dead load forces. An allowable passive earth pressure of 300 psf per foot of depth may be used for the sides of footings poured against recompacted soils. A factor of safety of 1.5 was applied in calculating passive earth pressure. The maximum value of the passive earth pressure should be limited to 2,500 psf. Vertical and lateral bearing values indicated above are for the total dead loads and frequently applied live loads. If normal code requirements are applied for design, the above vertical bearing and lateral resistance values may be increased by 33 percent for short duration loading, which will include the effect of wind or seismic forces. Due to the low overburden stress of the soil at shallow depth, the upper one foot of passive resistance should be neglected unless the soil Is confined by pavement or slab . • --9.4 Slabs-on-Grade • ---... -- .. - • Structural design elements such as thickness, reinforcement, joint spacing, etc., for the slab-on-grade should be selected based on the analysis performed by the project structural engineer considering anticipated loading conditions and the modulus of subgrade reaction of the supporting materials. The site soils will be substantially mixed during site grading and the Expansion Index (El) values of the final subgrade soils are likely to be different. At the completion of ~' Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc Geotechnk:al Investigation Report lmprovanents 10 Palomar Transfer Sidon Carilbad, Callbnla April 5, 2006 Page 18 grading, the expansion index of the subgrade soils should be determined and recommendations should be re-evaluated. For upper the two (2} feet of subqrade soils replaced with compacted Imported soils: Slab-on-grade should have a minimum thickness of four (4) inches for support of nominal ground-floor live loads. Minimum reinforcement for slab-on-grade will be No. 4 reinforcing bars, spaced at 16 inches on-center each way. The thickness and reinforcement of more heavily loaded slabs will be dependent upon the anticipated loads and shall be designed by a structural engineer. A static modulus of subgrade reaction equal to 200 pounds per square inch (psi) may be used in structural design of concrete slab-on-grade. • For upper the two (2) feet of subqrade sells, replaced with compacted on-site soils: Slab-on-grade should have a minimum thickness of six (6) inches for support of nominal ground-floor live loads. Minimum reinforcement for slab-on-grade will be No. 4 reinforcing bars, spaced at 16 inches on-center each way. The thickness and reinforcement of more heavily loaded slabs will be dependent upon the anticipated loads and shall be designed by a structural engineer. A static modulus of subgrade reaction equal to 150 psi may be used in structural design of concrete slab-on-grade. Our recommended parameters for the design of post-tension slab-on-grade are based on the CBC, 2001 Edition, Section 1816, listed below: • Edge Moisture Variation Distance (Em, Center Lift): 6 feet • Edge Moisture Variation Distance (Em, Edge Lift): 3 feet • Estimated Differential Swell (Ym, Center Lift}: 0.9 to 1.3 Inches • Estimated Differential Swell (Ym, Edge Lift): 0.18 to 0.32 inches Actual design method for post-tensioned slab-on-grade should be selected by the project structural engineer. All slab-on-grade should be underlain by a ten-mil Vlsqueen (or equivalent) moisture barrier. The moisture barrier should be covered by approximately two (2) inches of sand to minimize punctures and to aid in concrete curing. Subgrade soils must be firm and nonyielding prior to placement of concrete. In hot weather, the contractor should take appropriate curing precautions after placement of concrete to minimize cracking of the slabs. The potential for slab cracking may be lessened by the addition of fibre mesh to the concrete and/or control of water/cement ratio. ~,: Converse Consultants CCDC\M:\JOBFILE\2006\32\06-110\06-32.110-01_gir.doc -..., - - • - - • - .. - - -• ... -.. -.. .. ... • -.. - - - - • ... ... - .. ... ·- ·• - • - Geotechnk:al lnvesllg■tion Report Improvements to Palomar Transfer Slallan · Cal1sbad, Calbnla April 5, 2006 Page 19 Joints for concrete slabs-on-grade must be carefully designed. Joint spacing is dependent upon slab thickness and concrete properties and should be selected by the structural engineer . Concrete should be cured by protecting it against loss of moisture and rapid temperature change for at least seven days after placement. Moist curing, waterproof paper, white polyethylene sheeting, white liquid membrane compound, or a combination thereof, may be used after finishing operations have been completed. The edges of concrete slabs exposed after removal of forms should be immediately protected to provide continuous curing. • After the subgrade soils have been compacted to at least 90 percent of compaction and moisture-conditioned to at least 120 percent above optimum moisture, at least 24 inches of the subgrade soil below the bottom of the footings shall be presoaked to 20 percent above optimum moisture content prior to concrete pour. For example, the optimum moisture content of the subgrade soil is 8.0 percent, presoaking to 20 percent above optimum moisture content will bring the· moisture content to 9.6 percent (20 percent increase). This moisture content should be maintained at the time of concrete pour. The above recommendations are based on the results of tests performed on representative site soils. If soils other than those presently encountered within the project site are placed as structural fill within the building pads, the modulus of subgrade reaction should be reevaluated. The final slab design should be based on this value of the modulus of subgrade reaction. 9.5 Temporary Sloped Excavations The following recommendations are provided for use by the engineer during the design of the project to detennine shoring requirements and estimate construction costs. Based on the materials encountered in the exploratory borings temporary excavations may be supported by shoring or constructed according to the slope ratios presented In the table below. Temporary cuts encountering loose fill or loose dry sand, excavated near existing structures may require shoring or have to be constructed at a flatter gradient than presented in the following table. • Maximum Depth of Excavation (feet) Maxlmum·Slopa.Ratlo' (horlzontaJ:.vertlcall. 0-4 Vertical 4-10 1:1' 'Slope ratio assumed to be uniform from top to toe of slope. For steeper temporary construction slopes or deeper excavations, shoring should be provided by the contractor as necessary, to protect the workers in the excavation . ~t Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc ( I \ Geotechnlcal Investigation-Report lmprovanenta to Palomar Transfer Station Carlebad, Calfomla April 5, 2006 Page 20 Surfaces exposed In slope excavations should be kept moist but not saturated to retard raveling and sloughing during construction. Adequate provisions should be made to protect the slopes from erosion during periods of rainfall. Surcharge loads, including construction materials, should not be placed within five (5) feet of the unsupported slope edge. Stockpiled soils with a height larger than six (6) feet will require greater distance from trench edges. If the excavation occurs near existing structures, special construction considerations would be required during excavation to protect these existing structures during construction. The proposed excavation should not cause loss of bearing and/or lateral supports of the existing structures. · Due to close proximity of the existing building, the sloped over-excavation for the transfer station addition building may not be feasible. The excavation may consist of vertical cut exceeding five (5) feet or more should be adequately supported by temporary shoring to protect existing adjacent structures. Recommendations of shoring will be provided upon requested. All applicable requirements of the California Construction and General Industry Safety Orders, the Occupational Safety and Health Act of 1987 and current amendments, and the Construction Safety Act should be met. The soils exposed in cuts should be observed during excavation by a competent person employed by the contractor. If potentially unstable soil conditions are encountered, modifications of slope ratios for temporary cuts may be required. 10.0 GEOTECHNICAL SERVICES DURING CONSTRUCTION This report has been prepared to aid in the -evaluation of the site, to prepare site grading recommendations, and to assist the structural engineer with the design of the proposed structures. ~c,#' ( Recommendations presented herein are based upon the assumptions that earthwork monitoring will be provided by a Converse consultant. All excavation bottoms should be observed by a geotechnlcal representative prior to fill placement. Structural fill and backfill § should be placed and compacted during continuous observation and testing. It is I recommended footing excavations should be observed by a geotechnical consultant ~( representative prior to placement of steel and concrete, so that footings are founded on ,,:!sfactory materials and excavations are free of loose and disturbed materials. 11.0 CLOSURE The findings and recommendations of this report were prepared in accordance with generally accepted professional engineering and engineering geologic principles and 'iJ: Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc .. ,.., - - - - - - - • - - -·• .. ·• .. - .. ,, - - • - ,.., -· -.. .. • - • - .• • - - --- • ... .. Geotechnlcal Investigation Report lmpnM1111en1Bto Palanar Transfer Station Cat1lbad. callfomla April 5, 2006 Page.21 practice within our profession at this time in Southern Callfornia. Our conclusions and recommendations are based on the results of the field and laboratory investigations, combined with an Interpolation of subsurface conditions between and beyond exploration locations. As the project evolves, a continued consultation and construction monitoring by a qualified geotechnical consultant should be considered an extension of geotechnical investigation services performed to date. The geotechnical consultant may review plans and specifications to verify that the recommendations presented: herein have been appropriately Interpreted, and that the design assumptions used In this report are valid . Where significant design changes occur, Converse may be required to augment or modify the recommendations presented herein if the subsurface conditions during over- excavation differ in some locations from those encountered in the explorations and this office should notify immediately. This report was prepared for Riha Construction Co. for the subject project described herein. We are not responsible for technical interpretations made by others of our exploratory information. Specific questions or interpretations concerning our findings and conclusions may require a written clarification to avoid future misunderstandings . • ~' Convel88 Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr;doc ( 12.0 :REFERENCES Geotechnlcal lnvestlga1lcn R■port lmprowm■nls ti P■lomarT,.,_. Slllllon C■rl9blld, Clllfoma Aprl5,2006 Page22 BLAKE, T. (2000), UBCSEJS and FRISKSP, Version 1.03, Computer Programs for the Determination of UBC Seismic Design Parameters from Digitized California Faults, California. CALIFORNIA BUILDING CODE (CBC), 2001. LAMBE, T. W., and WHITMAN, R. V., 1979, Soil Mechanics, John Wiley & Sons. NAVFAC (1986), D~sign Manual 7.02: Foundation and Earth Structures. FOUNDATION ENGINEERING HANDBOOK, Has F. Winterkom and Hsai-Fang. GEOTECHNICAL ENGINEER'S PORTABEL HANDBOOK, Robert w. Day. SOUTHERN CALIFORNIA EARTHQUAKE CENTER, Recommended Procedures for Implementation of DMG Special Publication 117 Guidelines fbr Analyzing and Mitigating Liquefaction Hazards in California, March 1999. STANDARD SPECIFICATIONS FOR PUBLIC WORKS CONSTRUCTION (Green Book 2003), Building News, Inc., Los Angeles, California. VINJE & MIDDLETON ENGINEERING, INC., March 23, 1995, Limited Soil and Foundation Study, Proposed Recycling and Building Expansions, ADJ Sorting Facility, 5960 El Camino Real, Cartsbad; California, JOB# 95-144E. • €1, Converse Consultants CCOC\M:WOBFILE\2006\32\06-110\06-32110-01 _glr.doc -.... - - -• ... • - - • - - • ... ... • - - - - .. .. , ( ) I • \ I:: . .. :. . . ' . . .. . . . F I G u R E .......... \._ J f i r, I ' I ! I j ! . ,--i, I i ' , --lj/ JI ~ ......_.., f --~ ..... • . iJ Offllitfa ,": ., Ii ,--· I. ~ ·1 : \ ~- ' " =-~ ",. ~ ' _.., ' ,, ~-~ , .... ~~\ t l.Wllil BH-2 INDICATT:S NUMBER ANO 6l APPROXIMATE LOCATION OF BORING a ... Plan Provided by. Rlha Con11nlctlon Co. Sl'Fe AllD'BORlflG COCA TION. Pl.AN, IMPROVEMENTSTO'ni!:PALOMAR"TRANSF£11"5TATION. Clty,otCMf.-a;.Qlllbmta, ~10'4~ -,r;;:;n;-8-:.illl.:--Co---------Cosa;uj-, ___ tan_ts _____________ ;.__ t - -•·. - - -.. - I• ! j ...... • - 1• / . J - ; . I i ; - .. - ·• - - • ...... ... ..• , -... • • A p p ·E N D I X A \- • APPENDIX A FIELD EXPLORATION • - . ' .... - • • .., .. -.. - • - -• - - - .. .. .. -... - • - - • ... • - • - ... ·- - - • - - -... APPENDIX A FIELD EXPLORATION Geotechnlcal Investigation Report Improvements to Palomar Transfer Station Carlsbad, Callfomla April 5, 2006 PageA-1 Our field investigation Included a site reconnaissance and subsurface exploration program consisting of drilling exploratory borings. During the site reconnaissance, the surface conditions were noted and the locations of the borings were determined. The borings were located using existing topography, structures and boundary features as a guide . A total of nine (9) borings (BH-1 through BH-9) were drilled on the site on March 9, 2006 to depths ranging from 6.5 to 24.5 feet below ground surface. The drilling was terminated when the refusal of drilling encountered due to the bedrock formation. Relatively undisturbed ring and disturbed bulk samples of the subsurface materials were obtained from the borings at selected intervals for the purpose of laboratory testing. Approximate borings locations are shown in Figure No. 1, Site and Boring Location Plan. The borings were advanced using an 8-inch diameter hollow-stem auger drill rig. Soils were continuously logged and classified in the field by visual examination in accordance with the Unified Soil Classification System. The field descriptions have been modified where appropriate to reflect laboratory test results. Relatively undisturbed ring and bulk samples of the subsurface soils were obtained at frequent intervals in the borings. The relatively undisturbed samples were obtained using a California Modified Sampler (2.4 inches inside diameter and 3.0 inches outside diameter) lined with thin sample rings. Resistance blow counts were obtained with the sampler by dropping a 140-pound automatic hammer through a 30-inch free fall. The blows per foot recorded on the boring logs represent the accumulated number of blows required for the last 12 inches or shorter distance as indicated when refusal was encountered. The soil was retained in brass rings (2.4 inches in diameter and one inch in height). The central portion of the sample was retained and carefully sealed in waterproof plastic containers for shipment to the laboratory. Bulk soil samples collected from the borings were sealed in plastic bags and brought to the laboratory. Standard Penetration Tests (SPTs) were performed at selected depths in the borings using a standard (1.4-inch inside diameter and 2.0-inch outside diameter) split-barrel sampler. The mechanically driven hammer for the SPT sampler was 140 pounds, falling 30 inches for each blow. Resistance blow counts were obtained with the sampler by dropping a 140-pound automatic hammer through a 30-inch free fall. The blows per foot recorded on the boring logs represent the accumulated number of blows required· for the last 12 inches or shorter distance as indicated when refusal was encountered. The standard penetration tests were performed in accordance with the ASTM Standard 01586 test method. ~-Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc I. ( Geotechrical lnvntlgation'Repcrt lmp10V811111111s to PalomarTralwfer Station Cartsbad,.Calfomla April 6, 2006 PageA-2 · A key to soil symbols and terminology used in ·the Boring is included as DrawiRg No. A- - ' .. - - 1, Unified Soll Classification and Key to Boring. For Logs of Borings see Drawings No. - A-2 through A-10, Logs of Borings. ti)\ ConveraeCol'lsullants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_gfr.doc • - • - - .... .... ... ... ., ... - - - ..... -.. -.. , -... , - -.... - - ·• -.. - .... - " ' . ·- ., - •· k8J -D ~ SOlL 1CLA·SSJfl:CATl'ON CHA:RT. MAJOR:.DIVISlONS COARSE GRAINED SOILS MORETHAN-0 MATIRIAL 18 LAA<ilER TliAN NO, 200 SIEVE SIZE FINE GRAINED SOILS MOQT)WI 501' Of IAATERIAl.11 ~'!HANNO. 2DO IIIYE IIZI GRAVEL AND GRAVELLY SOILS MORI! THAN'°" 01' ccwonMACTION IIETAINED ON NO, 4 111111! SAND AND SANDY SOILS MOftl! THAN 50" Of' ccwon AW:110N PAIIINCI ON NO, .C - SILTS AND CLAYS SILTS AND CLAYS CLEAN GRAVELS IIJffl,I Ofl NO FIND) GRAVELS WITH FINES ~LIAMOUMT o,--, CLEAN SANDS (Uffl.a OJI NO !=!NU) SANDS WITH FINES LIQUID LIMIT LESS THAN SO LIQUID LIMIT GREATER lHAN SO HIGHLY ORGANIC SOILS SYMBOLS GRAPH LETTER . .. . . . • • 0 o O I ... ... ... ...... ... I:_ •• • . •.•.• : •• I· :,• .·.·.·.·>:: f--- GW GP GM GC SW SP SM SC ML CL ~--: OL f-- MH CH OH PT TYPICAL DESCRIPTIONS WEU4MDa) Cl"AYEl.&, CIMVEL-UNJ l&lCTUIIII, um.I OR NO FINEI ,P'00fll..Y4ftADElCMA\IILI, CIRAVIL•&NilDMDmJIIIIII, um.& Ofl NO NIEi BLTYBMVEl.a, CIIIIAYIL-SAND • SILT MDmJltEli Cl.A VEY OftAVELI. lllltAVEL. IIAND•ClAYMIXTURU WELJ.4MDED UHDI, OMY&U.Y MNOa, LITTLE ORNOFfNE■ ftOOftl..Y.alU.DIED aN«>a, UA\IEU.Y UNO. UTilE OIi NOANEI SILlY&AN:>a, MND•ILT -· ct.AYl't' IANDa, MN0 • CLAY MIXT\JIW N0RGANIC ■LTI AND VERY FM IANDI, "0CM FL0Wt. Ill.TY Oft CLAYft' FINE SANDIOfl~:--VILTa INORGNC ct.AYI 01' LOW TO MIDIUlol NMTICITY, ClftAVE.L y a.A YI. PHD"( ~~~ IILTY CI.AYI. UW. OllCIANC &TSMD OftGANIC 111.TYCLAYI DFLOW •LAITICITY N>IICIMIC A.Ta, MCACEOUI Oft DIATDIMCl'DW FINI MND Ofl 81l.TY IOI.I 1NCM1tUHK: a.A.YI 0, HIGH •LAITICITY 0RCMHIC CLA'f'li 0, MIDIUII TO I-IIIH ~rrv. OfltGANIC IL'TI 191AT, HUMUS.~ IOU WITH HICIH OtltllANIC CDNTIN1'1 NOTE: DUAL SYMBOLS ARE USED TO INDICATE BORDERLINE SOIL CLASSIFICATIONS SAMPLE]YPE STANOMP PftNCJJIAD9N llST lpllt bani 1ampierln aCDDrdance'IAh AITM D-1-...... ..., T"1 Molhod PBIYE MMN 2."'2" LO. •lmpl•, drfven -1-40 lb wolght, :SO In. drap QfflYI! &WPU!. No_recov-,y BYLJCSAMPbli • BORING LOG SYMBOLS LABORATORY TESTINO ABBREVIATIONS llllil'.U llWliil:I (Ruulls shown In ApplMlx !) Pockat ,..natn:nn.ter Oln,Ol- Cl-Shoor (llinglo point) CU.SSJflC&TlQN u-ComplUllon Trlaldal ~Ion Pluticity pl -·-OIU'ISlaAnalytil m• Pusfng No. 2DD 8'eve ... Con-Sond-.. ~Tol1 ~ GflAYNQWAJEB WMIU! PIU.LJtA ExpDlian Index. ., R-(ll)V.. Compadfon CUrve ,... Chemk:al Anlllylfs _,..,., h -~ ~ Ci89\JNRWAil8 Amft PBIWNO p •• ... UC tx VI • a,j .. .. ►---------------------------------------------------UNIFIED SOIL CLASSIFICATION AND KEY TO BORING LOG SYMBOLS - Dates .Drilled: 3/9/2006 -----------Logged·by: _____ C_K_L _____ Checked.By: __ ._KN __ _ Equipment: 8" HOLLOW STEM AUGER · ·. Ground Surface Elevation (ft)·'--. __ N_/A __ _ Driving Weight:and.Drop: 140 lbs/ 30 in Depth to Water (ft): NOT ENCOUNTERED -.-----,----,------------------------,-----,-----,----,.--,----,• :5 C. ~ 0 t f!! Cl (!) .3 SUMMARY OF SUBSURFACE CONDITIONS This log Is part of the report prepared by Converse for this project and should be read together with the report. This summary applies only at the location of the boring and at the time of drilling. Subsurface conditions may differ at other locations and may change at this location with the passage of time. The data presented is a SAMPLES w ~ ;?:: -I a::: ::, 0 III ...... I-~ ~ 0 a --0 w en LL a::: I-I--:::> z en ~ w I-:::> I-en 0 5 ~ 'fi' Ill -I ~ Ill :I!: o.e: -... -slmpllficatlon of actual conditions encountered. ----------------------+--+--i---+--+--+----1 .... 5 10 4" ASPHALT CONCRETE OVER 8" AGGREGATE BASE FILL; SIL TY SAND (SM): fine-to coarse-grained, olive gray . BEDROCK FORMATION: SANDSTONE: broken into silty sand, fine-to coarse-grained, cemented clasts, olive gray. -rocks and cobbles • End of boring at 10.5 feet due to refusal of bedrock. Groundwater not encountered at the time of drilling. Boring backfilled with bentonite chips and soil cuttings. Project Name l··~- ~Converse Consultants, Improvements to Palomar Transf9I' Station Carlabad, Callfomla For: Riha Conatructkm Co. 50-4" 11.5 110 50-6" 14.5 50-4" 10.5 (50-2") Project No. 08-32110-01 99 ds, wa 106 Drawing No. A-2 .. -... -.... - • - ·• - -• - - ' . - -... - - --- - • - •· -., - - - ' .. - -· . (, -.. -... , -. ' -•-- I - • _:_ .. Log ,of ,BH-2 Dates· Drilled: -----------3/9/2006 .Logged by: _____ C_K-"--L _____ Checked·sy: __ K_N __ .Equipment: 8" HOLLOW STEM AUGER Driving Weightand Drop: 140 lbs/ 30 in L Ground Surface Elevation (ft)~: __ N_/A __ _ Depth to Water (ft): 'NOT ENCOUNTERED = --:5 C. cu C 5 10 15 20 .2 .c C. £!! Cl (!) .9 ...... . '' ..... ... . . . . . . . . SUMMARY OF SUBSURFACE CONDITIONS This log is part of the report prepared by Converseforthis project and should be read together with the report. This summary applies only at the location of the boring and at the time of drilling • Subsurface conditions may differ at other locations and may change at this location with the passage of time. The data presented is a slmpllfication of actual conditions encountered. .E!bb;, SIL TY SAND (SM): fine-to coarse-grained, some fine gravel, brown. BEDROCK FORMATION: SANDSTONE: broken into silty sand, fine-to coarse-grained, some broken cobbles, cemented, elastic sedimentary rocks and cobbles, reddish brown. -gray, rocks and cobbles -rocks and cobbles -some fine gravel, olive gray -rocks and cobbles End of boring at 24.5 feet due to refusal of bedrock. Groundwater not encountered at the time of drilling. Boring backfilled with soil cuttings. SAMPLES I-;e-~ 0 0 --0 w u. a:: !:: ~ :::> z w :::,:: I-:::> > en ~ ..J 0 5 ~'a' ::> ..J C C0 C0 ~ Cl S, 50-6" 9.5 118 50-6" 16 109.5 50-4" 10 dist (50-4") (50-2") (96-11") (50-6") en I-en w I-re :5 max.ma : ~Converse· Consultants, Project Name Improvements to Palomar·Tr■n■far Station Carlsbad, Callfoml■ For: Riha Con■tructlon Co. Project No. 06-32110-01 Drawing No. A-3 --------------------------------------------- I .Log of:BH-3 Dates .Drilled: ------------3/9/2006 Logged by: _____ C_K_L _____ Checked By: __ ·_KN __ _ ( Equipment 8" HOLLOW·STEM AUGER Driving Weight.and Drop: ·140 lbs/ 30 in Depth to Water (ft): NOT ENCOUNTERED Ground Surface Elevation (ft)'-: __ NI_A __ _ SUMMARY OF SUBSURFACE CONDITIONS SAMPLES I-0 This log Is part of the report prepared by Converse for this project 0 and should be read together with the report. This summary applies i iE' .__ t.> only at the location of the boring and at the time of drilling. :5 :E Subsurface conditions may differ at other locations and may change w ~ C. > C. e! g, at this location with the passage of time. The data presented is a 2 ...J g Q) ::::> Cl (!) ...J simplification of actual conditions encountered. 0 al ID :-/. \{: :.{:. Ell,.b. SIL TY SAND (SM): fine-to coarse-grained, some fine gravel, brown. 50-4" • 5 BEDROCK FORMATION; 50-S" SANDSTONE: broken into silty sand, some fine gravel, cemented, elastic sedimentary rocks and cobbles, (50-S") brown.· 10 -gray 50-4" ........ . . . . . . . . . . . . . . . . ....... ' . . . . . . . . ' ... . . . . . . . . ~ 0 ...... w er: ~ U) 0 :!: 12.5 8 10 ( ........ ........ L . . . . . . .. ........ 15 . ·7·7·~- X X X X X X X )( X )( X X )( )( )( )( X X x X X X X X )( )( X X X X )( )( X X X )( X )( X X X X X X 20 X )( X X X X X X )( )( )( )( X X X X X X X X ---------------------------------CLA YSTONE: broken into clay, cemented, gray brown. End of boring at 22.0 feet due to refusal of bedrock. Groundwater not encountered at the time of drifflng. Boring backfilled with soil cuttings. (-~ . ~jConverse Consultants Project Name Improvements to Palomar Tr■n■far Station C■rl■bad, C■llfomla For: Riha Con■tructlon Co, 50-6" 25 50-6" 18.5 Project No. 08-32110-01' - ~ U) -t: I-U) z ~ ::::> >-c-ID ... er: u :'.5 o-8: •• ... 108 • ... 115.5 ·• ... rf -107 ·• ... .... 92 ... - ◄ 103 - -. ... ... .... 11111 .... 11111 ··• Drawing No. ... A-4 .... ... -... Dates Drilled:. ___ ..=3/:..:9::.:/2:;.:0-=06~----Logged by: ____ _..;:Ccc.K_;:L:.._ ____ Checked'By: _ __:_:Kc.:.N __ -,. Equipment 8" HOLLOW-STEM AUGER .Driving Weight:and Drop: ·140 lbs/ 30 in . Ground Surface Elevation (ft)'-: __ -_Nc.../A-'----Depth to Water (ft): NOT ENCOUNTERED - - - SUMMARY OF SUBSURFACE CONDITIONS SAMPLES I-* ~ This Jog Is part of the report prepared by Converse for this project 0 ...... 0 w ~ = and should be read together with the report This summary applies b!: 0:: !:: . (/) () only at the location of the boring and at the time of drilling. ~ ::, z w --~ I-:5 :E Subsurface conditions may differ at other locations and may change :.:: (/) ::, I- C. C. at this location with the passage of time. The data presented Is a ..J 0 5 >-c-ID Cl) ~ 8> it: ::, ..J 0:: 8. :5 C (!) ..J simplification of actual conditions encountered. C CD ID :E c ...... ... - • ·- 4" ASPHALT CONCRETE OVER 8" AGGREGATE . <:( ?/: :./.:. BASE Ii - .Ell:bi. 50-2" 6.5 dist. " <:/ :/.~-/·:: SIL TY SAND (SM): fine-to medium-grained, some fine _).\ /'.;: }: gravel, light brown. • ~ ~ 5 . :,-;. IX ·:::_:::: .-:-:-/ :.~ :::. -rocks (50-6") " ·- ' .. ' I End of bo('ing at 6.5 feet. Groundwater not encountered at the time of drilling. Boring backfilled with soil cuttings. ·- •· -( • I ) - -.. - -- • • -.. - - (: -Converse Consultants Project Name Improvements to Palomar Transfer Station Carlsbad, Callfomla For: Riha Construction Co, Project No. 0IS-32110-01 Drawing No. A-5 --------------------------------------------- ( ,Lo:gofBH-5 Dates Drilled: ------------3/9/2006 Logged by: _____ c_KL ______ Checked By:----KN Equipment: 8" HOLLOW STEM AUGER Ground Surface Elevation (ft)_: __ NJ_A __ _ Driving Weightand:Drop: 140 lbs /30 In Depth to Water (ft): NOT ENCOUNTERED 5 10 .f! .r:. Q. e! Cl (!) .3 )( X X )( X X )( X X X X X )( )( )( )( X X X X X X X )( )( )( )( )( X X X X X X X JC X X X X X X X X X ,c X X .-1'.-1'.-1'. SUMMARY OF SUBSURFACE CONDITIONS This log is part of the report prepared by Converse forthis project and should be read together with the report. This summary applies only at the location of the boring and at the time of drilling. Subsurface conditions may differ at other locations and may change at this location with the passage of time. The data presented Is a simplification of actual conditions encountered. 4" ASPHALT CONCRETE OVER 8" AGGREGATE BASE FILL; CLAYEY SAND (SC): fine-to medium-grained, light brown; • BEDROCK FORMATION: CLAYSTONE: broken into clay with sand, olive. -brown SAMP LES w ~ > a: ...J ::::> C CD I-~ g 0 0 ....... 0 w u. a:: I--:::i z ~ I-:::i en ~'[ 0 5 ...J CD ~ c ....... 72 11.5 116 41 16 109.5 52 21 dist SANDSTONE: broken into silty sand, light brown. 50-6" 20.5 dist. End of boring at 10.5 feet. Groundwater not encountered at the time of drilling. Boring backfilled with soil cuttings. ~ en w I- ID ~ ei ds wa - ··• -• ... .... ... ... ... ... ... -... - ' .. ... ... - , . -... -··• -.. - - - (.. ___ __,_ __ _.,_ _____________________ __,__,..__.....1.... __ -4_-4 __ ,..__ __ _, -· (+)· Project Name Project No. Drawing No. r_:_.. . _,·· Converse· Consultants g:,,..=:=:::.:om-Transf9rSlatlon OG-32110-01 A-6 For: Riha Construction Co. -... -... -.. ' - - •· - -... -.... .... - I ·, • J .. • .... • -.. -.. . - •· - •· Oates.Drilled: ------------3/9/2006 Logged·by:_. ____ C_KL ______ Checked By: __ KN __ Equipment 8" HOLLOW STEM AUGER Driving Welghtand Drop: 140 lbs/ 30 in Ground Surface Elevation (ft)'-: __ N_I_A __ _ Depth to Water (ft): NOT ENCOUNTERED g t QI 0 10 15 20 .2 .c 0. ~ Cl (.!) .:l xXXX X )( X X X X X X )( )( )( )( X X X X )( )( )( )(, X X X -,c,. X X X X X X X X X X X X X )( X )( X X X X X X ..X X X )( )( X )( )( )( )( X X X X X X X X X )( X X X X X X )( X X X )( .x )( )( )( )( )( )( )( )( )( )( X X )( X X )( X X x X X X X X X X )( X X X X X X )( X X X X X )( X X X X X X X X X X SUMMARY OF SUBSURFACE CONDITIONS This log Is part of the report prepared by Converse for this project and should be read together with the report. This summSJY applies only at the location of the boring and at the time of drllllng. Subsurface conditions may differ at other locations and may change at this location with the passage of time. The data presented is a simplification of actual conditions encountered. 4" ASPHALT CONCRETE OVER 8'.' AGGREGATE BASE FILL: SIL TY SAND (SM): fine-to medium-grained, gray . • BEDROCK FORMATION: SANDSTONE: broken into silty sand, fine-to medlun:,~grained, sedimentary, light brown. CLA YSTONE: broken into clay, moderately hard, dark gray. End of boring at 23.0 feet due to refusal. .' Grourtdwliter not encountered at the time of drilling . . Borini;i backfiiled with soil cuttings . SAMP w > a:: 0 LES f-~ g 0 0 ..... 0 w I:!:: a::: !:: ::::i z ~ ::ii::: f-::::i en ..J 0 0 >-c-::::i -I c:: I,.) al Ill :E cs 50-6" 14 115 50-6" 13 113.5 50-6" dist. 75 dist. (50-3") (50-4") en f-en w f- Ill :5 pi (-------'--___.... _____________________ ---1.._.1-__._ __ ----4-_----4-__ ,_ __ ~ """ Ct) Project Name Project No. Drawing No. .. _ ., --,Converse Consultants ~~s:::.r~W::n~omarTranllferSlatlon 06-32110-01 A-7' · For: Rlha Con■tructlon Co. ( ( - Dates Drilled: ------------3/9/2006 Logged by: _____ C_K_L _____ Checked By: _ _,K_N __ - · Equipment B" HOLLOW STEM AUGER Ground Surface Elevation (ft)'-: __ N_/A __ _ Driving Welghtand Drop: 140 lbs/ 30 in Depth·to Water (ft): NOT ENCOUNTERED - ,-----,---,------------------------,----,-----,---,---,-----, ·•• SUMMARY OF SUBSURFACE CONDITIONS --~ SAMPL ES I-~ This log is part of the report prepared by Converse for this project 0 ...... 0 w Cl) and should be read together with the report. This summary applies i c:: I-I-= z . Cl) • S:? only at the location of the boring and at the time of drilling . :::::, w ---~ I-:::::, t .s:: Subsurface conditions may differ at other locations and may change ~ I-C. en >-'fi' e! g> at this location with the passage of time. The data presented Is a ii: ...J 0 5 lXI QI :::::, ...J c:: C. ·:s C C!) ...J simplification of actual conditions encountered. C a:i lXI :E c ...... FILL: ca,er ----------------------t--t,,,,,'9i----t---t----t-----f'"" - - CLAYEY SAND (SC): fine-to medium-grained, some -fine gravel, gray brown. 39 15 113 .. • -5 ---------------------------------CLAY (CL): some fine-grained sand, brown. 64 22.9 95.7 C X X )( X BEDROCK FORMATION: 50-6" 19 101 X )( X X X )( X X )( )( )( )( CLAYSTONE: broken into clay, some fine-grained X )( X X ... X X X X sand, cemented, sedimentary, gray. X X X X 10 X X )( X X X X )( 50-6" 18.5 103 X X X X - )( )( )( )( End of boring at 11.5 feet. -Groundwater not encountered at the time of drilling. Boring backfilled with soil cuttings. -... - - -• • - • - • - • (-_ _,. __ ...._ _ __.J ______________________ ..J...._.J..__.JL_ __ -1---1---.....I...--__J - · · Project Name Project No. Drawing No. ,. . ·.·.·converse Consultants g:=~~.,:lom■rTransferSt■tlon 011-32110-01 A-8' For: Riha Con■trul:tlon Co. • - • -Log ofBH-8 Dates Drilled: ------------3/9/2006 -Logged by: ____ ___;C;..;.K..c:L:;.._ ____ Checked By: _ ___;_,:KN:...;___ .. ·Equipment: 8" HOLLOW STEM AUGER Driving Weight and Drop: 140 lbs/ 30 in (_ ' Ground Surface Elevation (ft)'-: __ -_N_/A __ _ Depth to Water (ft): NOT ENCOUNTERED ,. -,.., - - - • - ... .. , • - • .... •· -. ' -., -.. ' 5 . . . . . . . . SUMMARY OF SUBSURFACE CONDITIONS This log is part of the report prepared by Converse for this project and should be read together with the report. This summary applies only at the location of the boring and at the time of drilling. Subsurface conditions may differ at other locations and may change at this location with the passage of time. The data presented is a simplification of actual conditions encountered. .E!Y... CLAY (CL): trace fine-grained sand, brown .. • BEDROCK FORMATION; SANDSTONE: broken into sil sand red brown . End of boring at 6.5 feet. Groundwater not'encountered at the time of drilling . Boring backfilled with soil cuttings. • SAMPLES I-[ ~ 0 0 w Cf,) LL er: !:: I--::::> z Cf,) ~ UJ UJ ::.::: I-::::> I-> en ii:: ..J 0 5 ri'fi' ID ::::> ..J :5 0 ID ID :i: o..9: 20 20 101.5 50-6" 14 113.5 i_-@~ ___ .._ __ .__~---------P-ro-1e_ci_N_am_e _______ ___.__.1-........ P-ro_j_e_ci_N~o-.--1--□-rawt~.-.-n-g_N_o~ . .,. _ . _';converse Consultants gi:w=,;r:n:m"i:1omarTran•fer Station· 06-32110-01 A-9· For: Rib• Confflllctlon Co, --------------------------------------.....;. _____ _ ( - • Dates Drilled: 3/9/2006 ------------Logged by: _____ C_K_L _____ Checked By: __ ._KN __ - Equipment: a• HOLLOW STEM AUGER Ground Surface Elevation (ft)=-: __ N_/A __ _ .Driving Weightand Drop: 140 lbs/ 30 in Depth to Water (ft): NOT ENCOUNTERED = ...... .r:: .... Q, G) 0 5 10 -~ .r:: Q, e! 8> (!) -I )( X X X )( X X )( X )( X )( X X X X X X X >e )( )( )( )( )( )( )( )( )( )( )( )( X )( X X )( )( )( )( X X X X X X )( X X X >C X X X X X )( )( )( )( )( )( )( )( SUMMARY OF SUBSURFACE CONDITIONS This log Is part of the report prepared by Converse forthis project and should be read together with the report. This summary applies only at the location of the boring and at the time of drilling. Subsurface conditions may differ at other locations and may change at this location with the passage of time. The data presented is a simplification of actual conditions encountered. .E!LLi. CLAVEY SAND (SC): fine-grained, light brown. BEDROCK FORMATION; CLAYSTONE: broken into clay, red brown -gray brown End of boring at 11.5 feet. Groundwater not encountered at the time of drilling. Boring backfilled with soil cuttings. • SAMPL ES I-~ g 0 0 w !:!: ex: !:: ~ ::::::, z w :ii::: I-::::::, > en ~& 2 -I 0 0 ::::::, -I 0 al al :E o ...... 50-4" 16 102.5 50-6" 18 96 50-6" 17.5 99 - ~ -en w I- al -:5 r - - • - - - -.. - • - - - • __ __. __ __,_ ______________________ __J_..J_.....J. ___ -l-_4-_ _J. __ __, - ~Converse Consultants Project.Name Improvements to Palomar Transfer Station Carlsbad, Callfomls For: Riha Construction Co. Project No. 08-32110-01 Drawing No. A-10 -.. - ... ( !. - • - • - • - • ·-... -... ! ... r ... ) - • ► • -.. - • - •· - • - • \.. .. .. -.. • • A p p E N D I . . X • APPENDIX B . LABORATORY TESTING PROGRAM - - • - 11 ... .. - - -.. - - -,. - - • ... ... - - •·11 -.. - - - • • - - • ·- • - • - • - .... ... • - • - • -.. ... - • - • • - • APPENDIXB Geotechnlcal Investigation Report Improvements to Palomar Transfer Statlan CBr1sbad, Callfcmla April 5, 2006 PageB-1 LABORATORY TESTING PROGRAM Tests were conducted in our geotechnical laboratory on representative soil samples for the purpose of classification and evaluation of their relevant physical characteristics and engineering properties. The amount and selection of tests were based on the geotechnical parameters required for the design and construction of the project. Test results are presented herein and on the Logs of Borings in Appendix A, Field Exp/oration. The following is a summary of the variqus laboratory tests conducted for this project. Moisture Content and Dry Density Results of these tests performed on relatively undisturbed ring samples were used to aid in the classification of the soils and to provide qualitative information regarding soil strength and compressibility. For test results, see the Logs of Borings in Appendix A, Field Exploration . Sieve Analysis To aid in classification of the soils, mechanical grain-size analyses were performed on one (1) representative samples. Testing was performed in accordance with the ASTM Standard D422 method. For test results, see Drawing No. B-1, Grain Size Distribution Results . Amounts of Material In Soils Finer Than The No. 200 Sieve Two (2) selected samples were tested in accordance with the ASTM Standard D1140 test method to determine the amounts of materials finer than U.S. Standard Sieve No . 200. This information are summarized in Table No. B-1,· Percent Finer Than #200 Sieve Results. Table No. B-1, Percent Finer thal} #200 Sieve Results Boring No. Depth (ft) SolLClassJflcatlon BH-1 5 SANDSTONE *BH-2 0-5 SIL TY SAND (SM) BH-5 7 CLAYSTONE ~: Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc Percent.·Fln.wThan No. 200,SleMt{o/,.) 17 27 82 Atterberg Limits Geotachnlcal Investigation Report Liberty Baptist Church Nwport Beach, Callfomla April 5, 2006 PageB-2 Atterberg Limit Test was performed on one (1) representative sample to assist in the classification of the soils according to ASTM D4318. The test result is presented In Drawing No. B-2, Atterberg Limits Results. Laboratory Maximum Density Tests One (1) representative bulk sample was tested in the laboratory to determine· the maximum dry density and optimum moisture cont~nt. The test was conducted in general accordance with the ASTM Standard D1557 laboratory procedure. The test results are presented in Drawing No. B-3, Moisture-Density Relationship Results. Expansion Index One (1) representative bulk sample was tested to evaluate the expansion potential of material encountered at the site. The test was conducted in accordance with UBC/CBC Standard. For test results, see table below: Table No. B-2, Summary of Expansion Index Test Results . ... Boring No. mepth SoU·Descrlptfon Expansion 'Expansion (f'O Index. Poteritlat BH-5 1.0'-5.0' CLAYEY SAND (SC) 40 Low Consolldatlon Test Data obtained from this test, performed on one (1) relatively undisturbed soil sample, was used to evaluate the settlement characteristics of the on-site soils under load. Preparation for this test involved trimming the sample, placing it in a one-inch-high brass ring, and loading it into the test apparatus, which contained porous stones to accommodate drainage during testing. The sample was tested at field moisture and submerged conditions. Nonnal axial loads were applied to one end of the sample through the porous stones, and the resulting deflections were recorded at various times. The load was increased after the sample reached a reasonable state of equilibrium. Normal loads were applied at a constant load-increment ratio, successive loads being generally twice the preceding load. For test results, including sample density and moisture content, see Drawing No. B-4, Consolidation Test Results. @, Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr;doc - - -• - ... ... • - - • - • - - - - - - • - • - - - - .. . . ·- --~ ' I,... r. ) ..... .. - • - • - - -. ' -... , • - • Direct Shear Tests Geotechnical investigation• Report Uberty Baptist Church N-i,ort Beach, Callfomla Aprll 5,.2006 PageB-3 Two (2) direct shear tests were performed on undisturbed samples at soaked moisture conditions. Three samples contained in brass sampler ring was placed, one at a time, directly into the test apparatus and subjected to a range of normal loads appropriate for the anticipated conditions. The sample was then sheared at a constant strain rate of 0.01 inch/min. Shear deformation was recorded until a maximum of about 0.30-inch shear displacement was achieved. Ultimate strength was selected from the shear-stress deformation data and plotted to determine the shear strength parameters. For test data, including sample density and moisture content, see prawing Nos. 8-5 and B-6, Direct Shear Test Results and Table No. B-3, Summary of Direct Shear Test Results . Table N B 3 S o . -' ummarr of DI rect Sh ear T R est esuts Peak,.Str.ength Sample Depth Parameters So.lKDes.criptlon ;fi:rictlon · ' -,-,. ·,;· No. {feet) . Coheslom* Angle (psf) (degreesl BH-1 5 SANDSTONE 30 400 BH-5 5 CLAYSTONE 27 800 *Cohesion is not accounted In engineering analysis due to generally granular nature of site soils . R-Valua Test One (1) representative bulk sample of the surface soil was tested for resistance value (R-value} in accordance with State of California Standard Method 301-G. This test is designed to provide a relative measure of the soil strength for use in pavement design. For test results, see Table No. B-4, R-Value Test Results . Table No 8-4 R-Value Test Results . , . ·.· . Boring No. Depth (ft) Soll Classification -R~Vah:1e • uses BH-9 0.0' -5.0' CLAYEY SAND (SM) 11 Soll Corrosivlty One (1) representative soil samples were tested to determine mImmum electrical resistivity, pH, and chemical content, including soluble sulfate and chloride concentrations. The purpose of these tests is to determine-the corrosion potential of ~: Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_gir.doc ( Geolllchnlcal. lnvmttgallon,Report Uberty,Baplat Churc:h N.wport Beach, Callbnla Apr11·5,.2006 PageB-4 site soils when placed In contact with common construction materials. For·test results, see Table No. B-6, Soil CorrosMty Test Results. T able No. B-6,.Soll Corroslvlty Test Results . ·c, . ,, ... ,, .. ' "Jllln~::satumt.d ·t:liffliiilll■ . .;Mlfate ;l!!Gcatfm~h .pf.f ! ~~'! ·•·~ ~%-~!'9ighq " . ' .••" .. BH-7/0.0' -5.0' 7.88 235 0.011 820 • Sample Storage Soil samples presently stored In our laboratory will be discarded 30 days after the date of this report, unless this office receives a specific request to retain the samples for a longer period. • .• C011V81'N ConsuHants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01_glr.doc - - - - • - - • - - - f - - • - • - - - - - • ( - - - - - • -• - .... -.. - - • - - - • APPENDIX C EARTHWORK SPEC[FICATIONS .U.S. SIEVE OPENING IN INCHES U.S. SIEVE NUMBERS ~ 4 3 2 1.5 ~ 3/4 112318 3 ,4 e ,10 1,416 20 30 40 50 80 100140200 100 l I ,. \I I I I I I I 95 ~ ( 90 \ 85 80 75 f\ I\ : 70 ~ "- I-65 " l ""' :i: £! 60 ~ "- ~ 55 \ 0: • !/i! 50 )' ii: . . 1-45 I\ ifi a1 40 \ w D. 35 "-. 30 " ~ 25 20 I 15 I 10 5 0 100 10 0.1 GRAIN SIZE IN MILLIMETERS COBBLES GRAVEL SAND coar.e I fine coar.e I medium I fine Boring No. Depth (ft) Description LL • BH-2 0-5 SIL TY SAND (SM) • Boring No. Depth (ft) D100 D60 D30 D10 %Gravel • BH-2 0-5 25.4 1,296 0.113 28.0 i .• 0----. ' GRAIN SIZE DISTRIBUTION RESULTS ~ Converse Consultants Project Name Improvements to Palomar Transfer Station Carl■bad, Callfoml■ For: Riha Con■tructlon Co. HYDROMETER 0.01 0.001 SILT OR CLAY I PL Pl Cc Cu %Sand %Silt I %Clay 46.0 Project No. 08-32110-01 27.0 Drawing No. B-1 -•·• ... ... ... ·• ... • -·• - • ... • - - .... 11 -• - ... ... ... - - - -... -... , ( -. ' - • - • -.. .. .... ..J J J j j J j ... I -.. ', p L A s T I C I T y I N D E X Symbol • 60 50 40 30 20 10 o 0 CL-ML Boring No. BH-6 Depth (Ft) 10 20 LL (%) 46 V / PL (%) 16 @ @) --V / / V 40 Pl (%) 30 • @ 9 60 LIQUID LIMIT Description CLAYSTONE . / V . ATTERBERG LIMITS RESULTS :(it ·converse Consultants Project Name lmprovamanta to Palomar Tranafer station Cartabld, Callfoml■ For: Riha Construction Co. _, V' / V 80 Project No. 06-32110-01 .. 100 Drawing No. B-2 ( 150 , ' 145 140 135 130 'R. 125 ~ V) 120 z w C ~ C 115 110 ( I 105 I 100 95 90 a 5 10 15 20 25 WATER CONTENT, % • ASTM OPTIMUM SYMBOL SAMPLE NO. DEPTH (ft) DESCRIPTION TESTMETHOD WATER,% • BH-2 0-5 SIL TY SAND (SM) 01557 Method B 9.5 r-. . . MOISTURE-DENSITY RELATIONSHIP RESULTS • @converse Consultants Project Name lmpri>~ to Palomar Tranafar Siatlon c--.i, CallfDmla For: Riha Construction Co. Project No. 06-32110-01 30 MAXIMUM DRY DENSITY, pc:f 129 Drawing No. 8-3' - ... .... ... , ..... ... ... ... ... ... - • - • - ... ... ... ... • - - - - • ... . .. --·------------------------~------------------- • - • • ' i :- j ,_ • .... , 0 2 6 B 10 0.1 SAMPLENO. : DESCRIPTION : MOISTURE CONTENT(%) INITIAL 22.9 FINAL 2L7 NOTE: I J' \ t\ "" • j ---h., -.............. BH-7 • CLAY (CL) ORY DENSITY (pcf) 95.7 111.1 ~ " N " "-• I\ ~ \ ............ I\ r---... i-. \ t--. ,_ 1--,-. ::. 10 STRESS, ksf DEPTH (fl) SPECIFIC GRAVITY : PERCENT SAllJRATION 84 100 CONSOLIDATION TEST. RES UL TS ~ Converse Consultants Project Name Improvements to Palomar Transfer Station Carlsbad, CalHomla For: Riha Conatruc:tlon Co. .... I 5 2.15 VOID RATIO 0.710 0.701 Project No. 06-3211 0-01 100 Drawing No. B◄· I 4,000 3,500 3,000 2,500 2,000 /I V V • / V V 1 1,500 / / 1,000 V v· 500 V 0 0 1,000 2,000 3,000 4,000 NORMAL PRESSURE, psf SAMPLE NO. : BH-1 • DEPTH (fl) : DESCRIPTION : SANDSTONE COHESION (psfj : 400 FRICTION ANGLE (degrees): MOISTURE CONTENT(%) : 15 DRY DENSITY (pd) : NOTE: ULTIMATE STRENGTH DIRECT. SHEAR" TEST RESULTS 8 converse Consultants Project Name lmprovemllllta·to Palomar Tra.,..,. station Carlsbad, Callfomla For: Riha Construction Co. Project No. 06~2110-01 5 30 91 Drawing No. B-5 -... -.... -... ... .. .. .. ... ... - - - • - -• - - --------------------------------------------- - • ( 4,000 .... 3,500 - ' ' ·-3,000 ,_ ! r• § I I~ z w I= r:•i: Cl) I ~ ·-:r Cl) 1· 1_ \.,. 2,500 2,000 1,500 1,000 ./ v· ~ l,.,.-/ . • _,,,..../ ~ V • '__,,,...,/ ~ ~ ·-.. 500 _j J j 0 0 1,000 2,000 3,000 4,000 j ) SAMPLE NO. : DESCRIPTION : COHESION (paf) : MOISTURE CONTENT (%) ., NOTE: ULTIMATE STRENGTH : NORMAL PRESSURE, psf BH•$ , DEPTH (ft) : CLAYSTONI! 80D FRICTION ANGLE (degrees): 11 DRY DENSITY (pcf) : I --DIRECT SHEAR TEST RESULTS =~ Converse Consultants Project Name lmprovemenu to P■l•mar Transfer Station Carlsbad, Cllllfomla For: Riha Construction Co. Project No. 0fi-32110-01 5 X1 110 Drawing No. B-6 I • I - r I • A- P p E N D I X C ... ... ... ... - ... ... ... .... ... ... ... ... - • - • - -• - -... ... ... ... ... ... ... ... - • - • ( ... • - • i i 1- • I !-. ' I 1-, • - • - - - • J.. - APPENDIXC Geotechnlcal lnvestig■llon Raport Improvements to Palomar Transfer Slatlon C■rlsbad,C■llbnl■ Aprll 5;2006 Page D-1 EARTHWORK SPECIFICATIONS C1 .1 Scope of Work The work includes all labor, supplies and construction equipment required to construct the building pads In a good, workmanlike manner, as shown on the drawings and herein specified. The major items of work covered in this section include the following: ·· • • Site Inspection • Authority of Geotechnlcal Engineer • Site Clearing • Excavations • Preparation of Fill Areas • Placement and Compaction of Fills • Observation and Testing C1.2 Site Inspection 1. The Contractor shall carefully examine the site and make all inspections necessary in order to determine the full extent of the work required to make the completed work conform to the drawings and specifications. The Contractor shall satisfy himself as to the nature and location of the work, ground surface and the characteristics of equipment and facilities needed prior to and during prosecution of the work. The Contractor shall satisfy himself as to the character, quality, and quantity of surface and subsurface materials or obstacles to be encountered. Any inaccuracies or discrepancies between the actual field conditions and the drawings, or between the drawings and specifications must be brought to the Owner's attention In order to clarify the exact nature of the work to be performed. 2. This Geotechnica/ Investigation Report by Converse Consultants may be used as a reference to the surface and subsurface conditions on this project. The information presented in this above referenced report is intended for use in design and is subject to confirmation of the conditions encountered during construction. The exploration logs and related Information depict subsurface conditions only at the particular time and location designated on the boring logs. Subsurface conditions at other locations may differ from conditions encountered at the exploration locations. In addition, the passage of time may result in a change in subsurface conditions at the exploration locations. Any review of this information shall not relieve the Contractor from performing such independent @Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _gir.doc Geotechnical Investigation Report lmprovwnentsflo Palonulr Transfer Station Carlsbad,Cdbnla April 5, 2006 PageD-2 investigation and evaluation to satisfy himself as to the nature of the surface and subsurface conditions to be encountered and the procedures to be used in performing his work. C1.3. Authority of the Geotechnlcal Engineer 1. The Geotechnical Engineer will observe the placement of compacted fill and will take sufficient tests to evaluate the uniformity and degree of compaction of filled ground. • 2.As the Owner's representative, the Geotechnlcal Engineer will (a) have the authority to cause the removal and replacement of loose, soft, disturbed and other unsatisfactory soils and uncontrolled fills; (b) have the authority to approve the preparation of native ground to receive fill material; and (c) have the authority to approve or reject soils proposed for use in building areas. 3. The Civil Engineer and/or Owner will decide all questions regarding (a) the interpretation of the drawings and specifications, (b) the acceptable fulfillment of the contract on the part of the contractor and (c) the matters of compensation. ( C1 .4 Site Clearing 1. Clearing and grubbing shall consist of the removal from building areas to be graded: all existing pavement, utilities, and vegetation. 2. Organic and inorganic materials resulting from the clearing and grubbing operations shall be hauled away from the areas to be graded. C1 .5 Excavations Based on observations made during our field explorations, the surflcial soils can be excavated with conventiopal earthwork equipment. C1 .6 Preparation of FIii Areas 1. All organic material, organic soils, incompetent alluvium, undocumented fill soils and debris should be removed from the proposed building areas. 2. After the required removals have been made, the exposed bedrock shall be scarified to provide a zone of structural fill for the support of footings, slabs-on- grade, exterior flatwork. All loose, soft or disturbed earth materials, should be ~ Converse Consullanta CCOC\M:WOBFILE\2006\32\06-110\06-32110-01_glr.doc - - - - - .. .. 11 - ... - ... .. - NIii .. - 11 .. 11 - .. • - - - • -l - - • - - - - (-,.. • - Geotechnlcal Investigation· Report Improvements to Palomar Transfer Station Carllbad,Caltfoml■ Apn15,.2006 Page D-3 removed from the bottom of excavations before placing structural fill. As a minimum, the on site soils in the building area and to five (5) feet beyond the building limits and appendages shall be removed and recompacted to provide at least two (2) feet of properly compacted fill underneath all slabs and footings. 3. The subgrade in all areas to receive fill shall be scarified to a minimum depth of twelve (12) inches, then compacted to a relative compaction of at least 90 percent as per ASTM Standard D1557 test method at moisture content at least 120 percent of optimum and compacted to a relative compaction of at least 90 percent. 4. Compacted fill may be placed on native soils that have been properly scarified and recompacted as discussed above. 5. All areas to receive compacted fill will be observed and approved by the Geotechnical Engineer before the placement of fill. C1.7 Placement and Compaction of Fills 1. Compacted fill placed for the support of footings, slabs-on-grade, exterior concrete flatwork, and driveways will be considered structural fill. Structural fill may consist of approved onsite soils or imported fill that meets the criteria indicated below. 2. Fill consisting of selected on-site earth materials or imported soils approved by the Geotechnical Engineer shall be placed in layers on approved earth materials. Soils used as compacted structural fill shall have the following characteristics: a. b. All fill soil particles shall not exceed three (3) inches in nominal size, and shall be free of organic matter and miscellaneous inorganic debris and inert rubble. In order to limit moisture penetration to foundation earth materials, imported fill materials shall· be similar to on-site earth materials with at least 30 percent passing the No. 200 sieve. As an alternative to 30 percent passlnj the No. 200 sieve, import materials with a remolded permeablllty of 1 x 10 < > cm/sec or less would be acceptable. c. Fill materials shall have an Expansion Index (El) less than 20. All imported fill should be compacted to at least 90 percent of maximum dry density (ASTM Standard D1557 test method) at about two (2) percent above optimum moisture for fine grained soils, and within two (2) percent of optimum for granular soils. ~ Converse Consultants CCOC\M:\JOBFILE\2006\32\06-,110\06-32110-01_glr.doc Geotechnlcaf Investigation Report Improvements to Plllomar Transfar Station cai1abacl, Cdfomla April 5,2008 Page D-4 d. Imported fill materials shall have less than 0.1 percent sulfate salts, if possible. If laboratory test results indicate Import fill materials contain more than 0.1 percent sulfate salts, a concrete mix should be designed to resist the sulfate levels indicated by the laboratory test results. 3. Fill soils shall be evenly spread in maximum eight-inch lifts, watered or dried as necessary, mixed and compacted to at least the density specified below. The fill shall be placed and compacted on a horizontal plane, unless otherwise approved by the Geotechnlcal Engineer. 4. All fill placed at the site shall be compacted to at least 90 percent of the maximum laboratory density as determined by ASTM Standard D1557 test method. Granular soils shall be moisture conditioned to within two (2) percent, and dayey soils to at least 120 percent of optimum moisture content. 5. Representative samples of materials being used as compacted fill will be analyzed in the laboratory by the Geotechnical Engineer to obtain Information on their physical properties. Maximum laboratory density of each soil type used in the compacted fill will be determined by the ASTM D1557 compaction method. 6. Fill materials shall not be placed, spread or compacted during unfavorable weather conditions. When site earthwork Is interrupted by heavy rain, filling operations shall not resume until the Geotechnical Engineer approves the moisture and density conditions of the previously placed fill. 7. It shall be the Earthwork Contractor's obligation to take all measures deemed necessary during earthwork to provide erosion control devices in order to protect slope areas and adjacent properties from storm damage and flood hazard originating on this project. It shall be the contractor's responsiblllty to maintain slopes in their as-graded form until all slopes are in satisfactory compliance with job specifications, all berms have been properly constructed, and all associated drainage devices meet the requirements of the Civil/Geotechnical Engineer. • 8. Fill exceeding five (5) feet in height shall not be placed on native slopes that are steeper than 5:1 (horizontal to vertical). Where native slopes are steeper than 5:1, and the height of fill ls greater than five (5) feet, the fill shall be benched into competent materials. The height and width of the benches shall be at least tow (2) feet. • Converse Consultants CCOC\M:\JOBFILE\2006\32\06-110\06-32110..01 _glr.doc - ' .. -.... - • - .. -... - - .... - - - - • - • - - .. • - · .. , • - - - - • - C1 .8 Observation and Testing Geotechnk:al Investigation Report lmprowments to Palomar Transfer Station Cariabad, Cllllfomla April'5,2006 Page D-5 1. During the progress of earthwork, the Geotechnlcal Engineer will provide observation of the fill placement operations. 2. Field density tests will be made during earthwork to provide an opinion on the degree of compaction being obtained by the contractor. Where compaction of less than specified herein Is Indicated, addltlonal compactlve effort with adjustment of the moisture content shall be made as necessary untll the required degree of compaction is obtained . 3. A sufficient number of field density tests will be performed to provide an opinion to the degree of compaction achieved. In general, density tests will be performed on each one-foot 11ft of fill, but not less than one for each 500 cubic yards of fill placed. (B·: Converse Consultanla CCOC\M:\JOBFILE\2006\32\06-110\06-32110-01 _glr.doc