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Home My WebLink About; N End Highland Drive Storm Drain Reconstruction; N End Highland Drive Storm Drain Reconstruction; 2003-06-17p» M Preliminary Geotechnical Investigation Storm Drain Reconstruction North End of Highland Drive Carlsbad June 17, 2003 Prepared For: CITY OF CARLSBAD Mr. William E. Plummer Deputy City Engineer 1635 Faraday Avenue Carlsbad, California 92008 Prepared By: VINJE & MIDDLETON ENGINEERING, INC. 2450 Vineyard Avenue, Suite 102 Escondido, California 92029 Job #03-262-P VINJE & MIDDLETON ENQINEERINQ, INC, ^M ••"• — —L - ---- -• - - ••-• Job #03-262-P June 17, 2003 City of Carlsbad Mr. William E. Plummer Deputy City Engineer 1635 Faraday Avenue Carlsbad, California 92008 2450 Vineyard Avenue Escondido, California 92029-1229 Phone (760) 743-1214 Fax (760) 739-0343 PRELIMINARY GEOTECHNICAL INVESTIGATION, STORM DRAIN RECONSTRUCTION, NORTH END OF HIGHLAND DRIVE, CARLSBAD Pursuant to your request, Vinje & Middleton Engineering, Inc., has completed the Preliminary Geotechnical Investigation Report for the storm drain reconstruction at the above-referenced site. The following report summarizes the results of our field investigation, laboratory analyses and conclusions, and provides recommendations for the planned reconstruction as understood. In our opinion, the reconstruction of the existing failure features are feasible from a geotechnical engineering standpoint provided the recommendations presented in this report are incorporated into the final development plans and implemented during the reconstruction phase of the project. Thank you for choosing Vinje & Middleton Engineering, Inc. If you have any questions concerning this report, please do not hesitate to call us. Reference to our Job #03-262-P will help to expedite our response to your inquiries. We appreciate this opportunity to be of service to you. VINJE & MIDDLETON ENGINEERING, INC. Dennis Middleton CEG #980 DM/jt (P to TABLE OF CONTENTS PAGE NO. I. INTRODUCTION 1 II. SITE DESCRIPTION 1 III. SITE INVESTIGATION 1 IV. EXISTING FAILURE FEATURES AND PROPOSED RECONSTRUCTION 2 V. GEOTECHNICAL CONDITIONS 2 A. Earth Materials 2 B. Groundwater 3 C. Slope Stability 3 D. Laboratory Testing / Results 3 VI. CONCLUSIONS 5 VII. RECOMMENDATIONS 6 A. Slope Repairs and Reconstruction 6 B. Storm Drain Replacement 8 C. Soil Design Parameters 10 D. Years to Perforation of Steel Culverts 11 E. Plan Review 11 F. Preconstruction Conference 11 VIII. LIMITATIONS 12 TABLE NO. Soil Type 1 Maximum Dry Density and Optimum Moisture Content 2 Moisture-Density Tests (Undisturbed Chunk Samples) 3 Direct Shear Test 4 Ph and Resistivity Test 5 Years to Perforation of Steel Culverts 6 Hi p TABLE OF CONTENTS (continued) PLATE NO. Site Map 1 Geologic Cross-Section 2 Test Trench Logs (with key) 3-4 PRELIMINARY GEOTECHNICAL INVESTIGATION STORM DRAIN RECONSTRUCTION NORTH END OF HIGHLAND DRIVE CARLSBAD I. INTRODUCTION The property investigated in this work includes a graded hillside and natural canyon terrain below the northern terminus of Highland Drive, in the City of Carlsbad. The property accommodates a 24-inch diameter storm drain pipe which transmits storm waters from developed areas along Highland Drive down into canyon terrain and the Buena Vista Lagoon to the north. The existing pipe has failed resulting in high levels of erosion and sediment transport downstream, as well as uncontrolled run-off within the lower canyon terrain. We understand that plans for pipe reconstruction are currently underway. Consequently, the purpose of this work was to determine geotechnical conditions along the storm drain alignment within the failed segment and their impacts upon the planned reconstruction. Geologic mapping, test hole digging and soil sampling / testing were among the activities conducted in connection with the study which have resulted in reconstruction recommendations presented herein. II. SITE DESCRIPTION The project site includes upper graded areas at the north end of Highland Drive. The end of the road is marked by a large inlet which transmits run-off into a 2-foot diameter corrugated storm drain pipe buried within a descending fill slope. The slope terminates nearly 50 feet below in the lower canyon. A previous failure within the pipe has resulted in high levels of erosion with the lower slope. Impacted areas are presently marked by a large vertical scarp, soil debris and broken segments of the pipe throughout. Surrounding hillside areas are characterized by steep, natural slopes which also evidence recent erosion. Details of site surface conditions are shown on a Site Plan enclosed with this report as Plate 1. Subsurface conditions along the alignment are shown on a Geologic Cross- Section, enclosed with this report as Plate 2. Both graphics have been modified by approximate physical measurements taken at the site in order to depict recent slope erosion. III. SITE INVESTIGATION Geotechnical conditions along the failed alignment areas were determined from geologic mapping of existing exposures and from the excavation of 3 test trenches dug with a VINJE & MIDDLETON ENGINEERING, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICAL INVESTIGATIONS QRADINQ SUPERVISION PERC TEST/Nq ENVIRONMENTAL .NVESTIQATION PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 2 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003 limited access tractor-mounted backhoe. The trenches were logged by our project geologist who also retained representative soil samples for laboratory testing. Trench locations and mapped data are shown on Plates 1 and 2. Logs of the trenches are enclosed with this report as Plates 3 and 4. Laboratory testing and results are summarized in a following section. IV. EXISTING FAILURE FEATURES AND PROPOSED RECONSTRUCTION The existing storm drain has become disjointed and came apart as a result of bedding soil erosion and subsequent failure of the supporting slope terrain. High flow rates and velocities, as well as steep invert gradients causing piping (mining) of bedding materials are suspected causes of the noted failure. Subsequent to the storm drain failure, accelerated erosion and sediment transport have occurred resulting the existing vertical scraps. High levels of additional erosion and failures within the impacted canyon terrain should be anticipated in the event the planned reconstructions and repairs are not carried prior to the next rainy season. Details of the planned reconstruction work are presently unknown. We understand that a new storm drain pipe is proposed along a similar alignment approximately as shown on Plate 1. Design profile and new inverts are also not known, however, preliminary plans include the use of a 36-inch diameter pipe designed for 66 cfs flow rate with velocities on the order of 41 fps. Non-segmented pipe will likely be utilized particularly in steep sloping portions of the alignment. The pipe will outlet upon a designed structure located at an unknown point within the lower canyon. V. GEOTECHNICAL CONDITIONS The project site consists of graded hillside, and narrow canyon terrain which accommodate a damaged storm drain pipe. The following geotechnical conditions are apparent at the property: A. Earth Materials Upper hillside terrain at the project site is underlain by fill soils originally placed in order to expand building areas at the end of Highland Drive. The fill extended into the lower canyon with a slope gradient of 2:1 (horizontal to vertical). Based upon noted field exposures, the fill consists of locally derived sandy soils. Grading records for the fill are not available for review. VINJE & MIDDLETON ENQINEERIN(J, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICAL1NVESTIQATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTIGATION PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 3 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003 Formational rock units occur at the site beneath the fill and in surface exposures throughout the lower site canyon areas. The rocks consist of light colored sandstone units which occur in a weakly cemented and friable condition. Well- developed examples of site formational rocks were noted in near-vertical exposures developed from pipe erosion as shown on Plate 2. Lower canyon areas of the project site are underlain by debris and alluvial soil resulting from the recent erosion. Alluvial soils at the site consist of sandy deposits in a loose condition. The approximate distribution of project earth materials is shown on the enclosed Plates 1 and 2. Details of the noted deposits are given on the enclosed logs, Plates 3 and 4. B. Groundwater Major groundwater conditions were not encountered at the time of our test trench excavations to the depths explored; however, slight seepage was encountered along the base of the sandstone / claystone units in the test trench location T-3. Groundwater at the site is not expected to impact the project. C. Slope Stability Site topographic conditions are depicted on the enclosed Plates 1 and 2. Over- steepened conditions have resulted in lower site terrain where the recent pipe failure has occurred. Rotational-type slope failures within the lower near-vertical slopes can be expected, thus resulting in a progression of failures within remaining upper sections of the slope and supporting storm drain pipe. D. Laboratory Testing / Results Earth deposits encountered in our test trenches were closely examined and sampled for laboratory testing. Based upon our test data and field exposures, site soils have been grouped into the following soil types: TABLE 1 Soil Type 1 2 3 Description tan to brown silty fine to medium sand (fill/alluvium) tan to gray fine grain sand (sandstone) gray fine sandy clay (claystone) VINJE tf MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 « Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICALINVESTIQATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTIQATION PRELIMINARY GEOTECHNICAL INVESTIGATION NORTH END OF HIGHLAND DRIVE, ESCONDIDO PAGE 4 JUNE 17, 2003 The following tests were conducted in support of this investigation: 1. Maximum Dry Density and Optimum Moisture Content: The maximum dry density and optimum moisture content of representative on-site soil samples were determined in accordance with ASTM D-1557. The test results are presented in Table 2. TABLE 2 Location T-1 @ 2' T-3@1' Soil Type 2 1 Maximum Dry Density (Ym-pcf) 100.4 103.9 Optimum Moisture Content (o)opt-%) 15.5 14.0 2. Moisture-Density Tests (Undisturbed Chunk Samples): In-place dry density and moisture contents of representative soil deposits beneath the site were determined from relatively undisturbed chunk samples using the water displacement method. The test results are presented in Table 3. TABLE 3 Sample Location T-1 @ 21 T-2 @ 6' T-3 @ 4' Soil Type 2 2 2 Field Moisture Content (w-%) 21.7 23.1 27.2 Field Dry Density (Yd-pcf) 93.0 91.0 93.8 Maximum Dry Density (Ym-pcf) 100.4 100.4 100.4 Ratio of In -Place Dry Density to Max. Dry Density* (Yd/Ymx100) 92.6 90.6 93.4 *Designated as relative compaction for structural fills. Required relative compaction for structural fill is 90% or greater. 3. Direct Shear Test: Two direct shear tests were performed on representative samples of Soil Types 1 and 2. The prepared specimens were soaked overnight, loaded with normal loads of 1, 2, and 4 kips per square foot respectively, and sheared to failure in an undrained condition. The test results are presented in Table 4. VINJE & MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escundido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICAL INVESTIGATIONS QRAD1NQ SUPERVISION I'ERC TESTING ENVIRONMENTAL INVESTIGATION PRELIMINARY GEOTECHNICAL INVESTIGATION NORTH END OF HIGHLAND DRIVE, ESCONDIDO PAGE 5 JUNE 17, 2003 TABLE 4 Sample Location T-1 @ 2' T-3@1' Soil Type 2 1 Sample Condition remolded to 100% of field Yd & co% remolded to 90% of Yd @ % coopt Wet Density (Yw-pcf) 118.3 124.3 Angle of Int. Fric. (cD-Deg.) 35 31 Apparent Cohesion (c-psf) 65 20 4. Ph and Resistivity Test: Ph and resistivity of representative samples of Soil Type 1 collected at selected locations was determined using "Method for Estimating the Service Life of Steel Culverts," in accordance with the California Test 643. The test result is presented in Table 5. TABLE 5 Sample Location T-s@r SoilType 1 Minimum Resistivity (OHM-CM) 3360 Ph 7.19 VI. CONCLUSIONS Based upon the foregoing investigation, failure in the storm drain pipe within the lower reaches of the slope has resulted in severe erosion and the destruction of lower pipe segments. Added slope failure and a continued destruction of remaining segments of the pipe should be expected, particularly during the forthcoming winter months. The storm drain pipe may be reconstructed substantially as proposed. The new pipe should be selected based on the design invert gradients, flow rate and velocity, and placed within a regarded fill section which extends to the canyon bottom. This will require the importation of soil or regrading of surrounding terrain in order to generate needed fill soils. Reconstruction of the lower slopes will also buttress existing near vertical exposures and impacted surrounding unstable terrain disallowing failure progression towards the upper unaffected slopes. Alluvial and debris soils which mark the lower canyon are relatively thin deposits which should also be regraded in connection with the proposed reconstruction. VINJE (S1 MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Auenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICAL INVESTIQATIONS QRADINQ SUPERVISION I'ERC TESTING ENVIRONMENTAL INVESTIGATION PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 6 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003 VII. RECOMMENDATIONS »- A significant failure impacts lower graded fill soils and surrounding natural canyon which supported the storm drain. Existing eroded features resulted from a high flow rate, high p~ velocity uncontrolled and concentrated storm water run-off subsequent to the storm pipe *•• failure. Reconstruction of the eroded slope and ground surfaces to pre-failure configurations in conjunction with the storm drain replacement is recommended in the "" following sections. Actual finish grades will also control storm drain pipe invert elevations *• and should be designed by the project civil engineer, and reflected on the grading and ^ improvement plans. *• The following preliminary recommendations are based on the site geotechnical conditions ^ and scheme of the project repairs and reconstruction work as understood. Civil drawings which accurately depict existing site topography, proposed final grades and limits of m reconstruction work as well as the new storm drain inverts, profile and associated underground structures should be provided to us for review. More specific recommendations, if necessary, will be given at that time in a formal Geotechnical Plan m Review Report. A. Slope Repairs and Reconstruction ^ J^ |* pi Repairs to the lower failed portions of the existing slopes and surrounding canyon to terrain should be undertaken prior to the planned storm drain replacement. Repair of failed areas may be completed using conventional removal and recompaction m and grading methods which will require imported soils. *•* General: The following procedures should be implemented in the repair of the m affected slope areas in order to construct a safe and stable slope terrain and m preclude progression failure of the upper slopes. Minor groundwater seeps encountered during our field work is not expected to significantly impact repair p grading operations as recommended herein. However, grading repairs and m storm drain installations completed during the summer months, prior to the forthcoming rainy seasons, should be considered. m M The enclosed Site Plan and Cross-Section provided herein are not surveyed maps or civil drawings, and have been prepared based on visual observations ^ and approximate physical measurements for the purpose of geotechnical «• presentations only. These maps and cross-sections may be used for informal approximate estimates of earthworks and repair grading involved. Detailed civil *" drawings and surveyed maps prepared by the project civil engineer shall be *•' considered for accurate repair cost and quantity estimations. VINJE & MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • fax (760) 739-0343 gEOTECHNICAL INVESTIQATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTIQATION ta PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 7 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003 pn * Clearing and Grubbing: Remove surface vegetation, trees and other i* unsuitable / deleterious materials and debris from all areas of slope repairs plus to a minimum of 10 feet where possible, and as approved in the field by the project geotechnical engineer or his designated representative. m m * Establish a Keyway: Construct a lower keyway at the base of the slope failure within the unaffected lower formational rock units as approved by the project "* geotechnical engineer. The keyway should maintain a minimum depth of 3 feet IM into the competent formational rock with a minimum width of 12 feet. The bottom oi the keyway should be heeled back a minimum of 2% into the natural p" hillside and inspected and approved by the project geotechnical engineer. HH * Remove Failed and Loose Soil Debris: Loose surface soils and failure scrapp / debris within the affected areas plus 5 feet beyond the failure features (as "• directed in the field by the project geotechnical engineer), should be removed. The removal operations should effectively remove all loose bottom deposits and T unstable side slopes within the failure affected areas, and expose level11 benches (or steps in the steeper side slope areas) within the unaffected competent formational rocks. The level benches (steps) should be constructed C in a manner that there is a minimum of 5 feet of compacted fill from the outside edge (front) of the bench to the finish slope face and keyed into the unaffected m competent formational rocks. Removed soils are suitable for reuse in recompacted fill. p, Imported soils will be required to complete slope repair grading works. Import soils should be sandy deposits (expansion index less than 51) free of organic materials, larger than 6-inch rock sizes and trash debris, and approved by the p project geotechnical engineer prior to delivery to the site. ttg| * Recompact Fill Soils: Reconstruct the slope by placing fills in thin, horizontal p lifts upon lower keyway and level benches that expose firm approved ground ^ to achieve original 2:1 (horizontal to vertical) gradients. Steeper than 2:1 gradient fill slopes (114:1 or flatter), may also be considered; however, p additional engineering analyses and construction specifications, including H placement of slope reinforcement Geogrid, will be required and should be given in the subsequent Geotechnical Plan Review Report as appropriate. p m Site fill soils should be moisture conditioned to near optimum levels, thoroughly processed into a uniform mixture, and mechanically compacted in thin uniform »• horizontal lifts with heavy construction equipments to a minimum of 90% of the VINJE <S? MIDDLETON ENGINEERING, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 gEOTECHNICAL INVESTIGATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTIGATION PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 8 NORTH END OF HIGHLAND DRIVE, ESCONDIDO _ JUNE 17, 2003 laboratory maximum density value in accordance with ASTM D-1557. The fill should be compacted to a minimum of 90% out to the slope face. Back rolling at a minimum of 3-foot vertical increments and track walking the completed slope, or over-building the slope and cutting back to design configurations is recommended. Field density tests should be performed to confirm adequate compaction levels within the slope face. Improve Site Surface Drainage: Surface drainage improvements should be completed at the site as specified on the project grading and improvement plans, prepared by the project civil engineer. Overflow of the upper surface run-off from the top of the slope should not be allowed. Slope drainage should sheet-flow over the slope face rather than occur in a concentrated flow. Surface drainage facilities should also be considered. Concentrated run-off should not be allowed to occur any place over the slope face areas. m * Engineering Inspection and Testing: The future performance of the H reconstructed slope depends on correctly implementing the above recommended procedures. All grading operations should be continuously H inspected and tested by representatives of this office. A final compaction and j| slope repair certification report which details grading procedures should then be prepared at the completion of the work by the project geotechnical p consultant. * Plant the Slope Face soon after Reconstruction: The completed slope face m should be provided with a suitable plant cover. Natural brush is best but difficult ^ to quickly establish. Initially, only broad-leafed, deep rooted vegetation which requires a minimum of irrigation should be used. Over watering of site p vegetation should be avoided. Only the amount of water to sustain vegetation m life should be provided. p B. Storm Drain Replacement j^y We understand that a new 36-inch HOPE storm drain pipe replacement is being p considered. The following recommendations are appropriate: m * Storm drain should be installed in stable compacted fills or natural ground as P specified herein. All trench excavations should be inspected, tested as ki necessary and approved by the project geotechnical engineer. IP IM ftH pt VINJE # MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 IB QEOTECHNICALINVEST1QATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTigATION - PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 9 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003PP» • * Bottom of trench and pipe bedding / backfill materials on steeper slope "" conditions are subject to creep when they become excessively saturated. «• Erosion and subsequent failures are also common occurrences where significant flow within the gravel / crushed rock materials, typically used for pipe m bedding and backfill within the pipe zone, impacts the bottom of the trench and *• causes trench erosion and subsequent loss of prior support. A well-constructed and backfilled trench is critical in the future performance of the proposed storm "" drain constructed on site slopes. * Storm drains installed on steeper than 4:1 gradient slopes may be encased with "* concrete slurry within the pipe zone. The concrete slurry may be used for *" encasing the entire pipe length to a minimum of 1-foot above the top of pipe m (within the pipe zone). A minimum two-sack concrete slurry should be used. In this case, provide minimum 4-inch concrete blocks or saddles, securely 111 placed at close intervals to support the storm drain pipe during pipe m encasement with concrete slurry. m In the case of 2YzA or steeper invert gradients, provide a minimum of 8 inches _ wide by 12 inches deep concrete anchors dug into the well-compacted fills, or •L formational units to assure trench, pipe bedding and backfill stability. The CIP (Cast In Place) concrete anchors should be constructed perpendicular to the p, pipe profile, strategically placed at less than 50 feet intervals maximum. The ^ concrete anchors should be provided with a shear key (2-inch X 4-inch wood board blocked out in concrete) for the subsequent slurry backfill to lock into the m anchors. m * Storm drains or portions thereof installed at flatter that 4:1 invert gradients may m be provided with %-inch to 1-inch crushed rocks wrapped in filter fabric (Mirafi ^ 140 N), or %-inch crushed rock for pipe bedding and as backfill within the pipe zone. m m * Site or import soils (expansion index less than 51) may be used to backfill trenches above the pipe zone. Trench backfill soils (above the pipe zone) P should be moisture conditioned to near optimum levels, placed in thin lifts and in mechanically compacted to at least 90% of the corresponding maximum dry density. Field in-place density tests should be performed by the project P geotechnical consultant to ensure adequate compaction levels within the trench In backfill materials. Trench backfill compaction test results should be summarized in a final report. V/NJE # MIDDLETON ENGINEERING, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICAL INVESTIGATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTigATION p m PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 10 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003 Storm drains should also be constructed and installed in conformance with the project civil drawings. * Temporary trench sidewall excavations less than 5 feet high maximum and exposing well-compacted fills or competent formational units may be constructed at near vertical gradients. Recommendations with deeper trench excavations and sidewall stability will be given in the Geotechnical Plan Review Report based on the design invert elevations. C. Soil Design Parameters The following soil design parameters are based on the tested representative samples of on-site earth deposits. All parameters should be re-evaluated when the characteristics of the final as-graded soils have been specifically determined. Added or modified soil design parameters will be provided in the Geotechnical Plan Review Report based on actual project design scheme, if necessary: - Design wet density of soil = 124.3 pcf. m - Design angle of internal friction of soil = 31 degrees. - Design active soil pressure for retaining structures = 40 pcf (EFP), level backfill, m cantilever, unrestrained walls. p, - Design at-rest soil pressure for retaining structures = 60 pcf (EFP), non- ^ yielding, restrained walls. - Design passive soil pressure for retaining structures = 388 pcf (EFP), level m surface at the toe. 10 - Design coefficient of friction for concrete on soils = 0.38. - Net allowable foundation pressure for certified bearing soils (minimum 12 p inches wide by 12 inches deep footings) = 1500 psf. fl - Allowable lateral bearing pressure (all structures except retaining walls) for certified on-site soils = 150 psf/ft. p HI Notes: P - Use a minimum safety factor of 1.5 for wall over-turning and sliding stability. Mi However, because large movements must take place before maximum passive resistance can be developed, a safety factor of 2 may be used for sliding "" stability where sensitive structures and improvements are planned near or on IM top of retaining walls. m VINJE # MIDDLETON ENQINEERINQ, INC. 2450 Vtneyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 ||| gEOTECHNICAL INVESTIGATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL 1NVESTIQATION PRELIMINARY GEOTECHNICAL INVESTIGATION NORTH END OF HIGHLAND DRIVE, ESCONDIDO PAGE 11 JUNE 17, 2003 p m wW - When combining passive pressure and frictional resistance the passive component should be reduced by one-third. - The net allowable foundation pressure provided herein was determined for footings having a minimum width and depth of 12 inches. This value may be increased by 20% for each additional foot of depth and 20% for each additional foot of width to a maximum of 3500 psf if needed. The allowable foundation pressures provided herein also apply to dead plus live loads and may be increased by one-third for wind and seismic loading. - The lateral bearing earth pressures may be increased by the amount of the designated value for each additional foot of depth to a maximum of 1500 pounds per square foot. D. Years to Perforation of Steel Culverts The following are appropriate based on the Ph-Resistivity test result: TABLE 6 , Sample Location ' T-3@r " .'•' . • v -• '• _• -,' .'. 'Gage- . • ' . .-•- ': - Years to Perforation of Steel Culverts 18 28 w '>',?-<« 1$ : 36 '.I*:" 44 -',-12' ; 61 10 78 •: .'a-:. 95 E. Plan Review Final drainage improvements and slope repair plans should incorporate recommendations provided in this report and reviewed and approved by this office. If the final plans vary from conditions used as a basis of our investigation, further subsoil study may be required and should be anticipated. Additional and / or modified recommendations will also be provided at that time, as necessary. F. Preconstruction Conference A preconstruction meeting between representatives of this office, the property owner or planner, the city inspector, the project civil engineer, and grading contractor is recommended in order to discuss repair grading and reconstruction details. VINJE # MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 • Phone (760) 743-1214 • Fax (760) 739-0343 QEOTECHNICAL INVESTIGATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTIGATION PRELIMINARY GEOTECHNICAL INVESTIGATION PAGE 12 NORTH END OF HIGHLAND DRIVE, ESCONDIDO JUNE 17, 2003 VIII. LIMITATIONS P» to The conclusions and recommendations provided herein have been based on all available data obtained from our field observations and laboratory analysis, as well as our p experience with the soils and formational materials located in the general area. The it materials encountered on the project site and utilized in our laboratory testing are believed representative of the total area; however, earth materials may vary in characteristics P between excavations. m Of necessity we must assume a certain degree of continuity between exploratory *" excavations and / or natural exposures. It is necessary, therefore, that all observations, i" conclusions, and recommendations be verified during the grading operation. In the event discrepancies are noted, we should be contacted immediately so that an inspection can *" be made and additional recommendations issued if required. m The recommendations made in this report are applicable to the site at the time this report * was prepared. It is the responsibility of the owner / developer to ensure that these * recommendations are carried out in the field. P It is almost impossible to predict with certainty the future performance of a property. The *" future behavior of the site is also dependent on numerous unpredictable variables, such as earthquakes, rainfall, and on-site drainage patterns.p ta The firm of VINJE & MIDDLETON ENGINEERING, INC., shall not be held responsible for changes to the physical conditions of the property such as addition of fill soils, added cut slopes, or changing drainage patterns which occur without our inspection or control. p This report should be considered valid for a period of one year and is subject to review by y our firm following that time. If significant modifications are made to your tentative development plan, especially with respect to the height and location of cut and fill slopes, p this report must be presented to us for review and possible revision. m Vinje & Middleton Engineering, Inc., warrants that this report has been prepared within the p limits prescribed by our client with the usual thoroughness and competence of the y engineering profession. No other warranty or representation, either expressed or implied, is included or intended. p y Once again, should any questions arise concerning this report, please do not hesitate to contact this office. Reference to our Job #03-262-P will help to expedite our response to m your inquiries. VZNJE & MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escandido, California 92029-1229 .• Phone (760) 743-1214 • fax (760) 739-0343 QEOTECHNICAL INVESTIGATIONS QRADINQ SUPERVISION PERC TESTINq ENVIRONMENTAL INVESTIGATION pb p tt PRELIMINARY GEOTECHNICAL INVESTIGATION NORTH END OF HIGHLAND DRIVE, ESCONDIDO PAGE 13 JUNE 17, 2003 We appreciate this opportunity to be of service to you. VINJE & MIDDLETON ENGINEERING, INC. pi m p m Dennis Middleton CEG #980 CERTIFIED ENGINEERING ehdi S. Shanat E#46174 RG #6953 DM/SMSS/SJM Distribution: Addressee (5) VINJE & MIDDLETON ENQINEERINQ, INC. 2450 Vineyard Avenue, Escondido, California 92029-1229 « Phone (760) 743-1214 • fax (760) 739-0343 QEOTECHN1CAI./NVESTIQATIONS QRADINQ SUPERVISION PERC TESTINQ ENVIRONMENTAL INVESTIGATION ORMAtlONAL ROCK FORMATIONAL ROCK FORMATIONAL ROCK ^NGLE FAMILY ESIDENCE STORM DRAIN PROJECT, NORTH END OF HIGHLAND DRIVE, CARLSBAD Base map is modified to depict recent erosion. Not surveyed. Location of test trench Geologic cross-section line PLATE 1 03-262-P 0 iu I I I I I I I C I I I I I PLATE 2 wo- 50- STORM DRAIN PIPE-,. Original Surface-^/-j/ - 750 -700 T-1 -50 Scale: 1 "=30' D Surface profile determined chiefly from physical measurements taken at the site. Not surveyed. PRIMARY DIVISIONS GROUP SYMBOL SECONDARY DIVISIONS 3 8 CD LUCO5< 0O ooCM LL *- LU 0 Z N U. < CO <K£ 1 CC. LU I OC r^cl O ~ GRAVELS MORE THAN HALF OF COARSE FRACTION IS LARGER THAN NO. 4 SIEVE SANDS MORE THAN HALF OF COARSE FRACTION IS SMALLER THAN NO. 4 SIEVE CLEAN GRAVELS (LESS THAN 5% FINES) GW Well graded gravels, gravel-sand mixtures, little or no fines. GP Poorly graded gravels or gravel-sand mixtures, little or no fines. GRAVEL WITH FINES GM Silty gravels, gravel-sand-silt mixtures, non-plastic fines. GC Clayey gravels, gravel-sand-clay mixtures, plastic fines. CLEAN SANDS (LESS THAN 5% FINES) sw Well graded sands, gravelly sands, little or no fines. SP Poorly graded sands or gravelly sands, little or no fines. SANDS WITH FINES SM Silty sands, sand-silt mixtures, non-plastic fines. sc Clayey sands, sand-clay mixtures, plastic fines. to LU<r Nuj CO SILTS AND CLAYS LIQUID LIMIT IS LESS THAN 50% ML Inorganic silts and very fine sands, rock flour, silty or clayey fine sands or clayey silts with slight plasticity. CL Inorganic clays of low to medium plasticity, gravelly clays, sandy clays, silty clays, lean clays. OL .Organic silts and organic silty clays of low plasticity. < ICC I— 0 LULU rrz O SILTS AND CLAYS LIQUID LIMIT IS GREATER THAN 50% MH Inorganic silts, micaceous or diatomaceous fine sandy or silty soils, elastic silts. CH Inorganic clays of high plasticity, fat clays. OH Organic clays of medium to high plasticity, organic silts. HIGHLY ORGANIC SOILS PT Peat and other highly organic soils. GRAIN SIZES U.S. STANDARD SERIES SIEVE 200 40 10 CLEAR SQUARE SIEVE OPENINGS 3/4" 3" 12" SILTS AND CLAYS SAND FINE MEDIUM COARSE GRAVEL FINE COARSE COBBLES BOULDERS RELATIVE DENSITY CONSISTENCY SANDS, GRAVELS AND NON-PLASTIC SILTS VERY LOOSE LOOSE MEDIUM DENSE DENSE VERY DENSE BLOWS/FOOT 0-4 4- 10 10-30 30 - 50 OVER 50 CLAYS AND PLASTIC SILTS VERY SOFT SOFT- FIRM STIFF VERY STIFF HARD STRENGTH 0 - </4 '/4 - Vl '/> ' 1 1 - 2 2-4 OVER 4 BLOWS/FOOT 0 - 2 2-4 4-8 8 - 16 16-32 OVER 32 1. Blow count, 140 pound hammer falling 30 inches on 2 inch O.D. split spoon sampler (ASTM D-1586) 2. Unconfined compressive strength per SOILTEST pocket penetrometer CL-700 Standard Penetration Test (SPT) (ASTM D-1586) with blow counts per 6 inchesSand Cone Test j§ Bulk Sample | ^6 M Chunk Sample O Driven Rings II 246 = California Sampler with blow counts per 6 inches VINJE & MIDDLETON ENGINEERING, INC. 2450 Vineyard Ave., #102 Escondido, CA 92029-1229 KEY TO EXPLORATORY BORING LOGS Unified Soil Classification System (ASTM D-2487) PROJECT NO. KEY 0* tan f" te to h. f" pi Ml PI Itt fe* f" k. PI to 1H r Date: 5-14-03 DEPTH (ft) •1 - 2 - - 3 - - 4 - - 5 - c— D — - 7 - - 8 - - 9 - SAMPLE \ QH \ Logged by: SJM T-1 DESCRIPTION ALLUVIUM: Silty fine to medium sand. Brown color. Dry. Loose. Some cobbles. ST-1 FORMATIONAL ROCK: Sandstone. Fine grained. Gray color. Slightly micaceous. Massive. Rust colored staining. Weathered friable. Poorly cemented. Color changes to tan at 4'. Unable to obtain chunk samples below 21/z'. ST-2 End Test Trench at 6'. No caving. No groundwater. uses SYMBOL SM SP MOISTURE 21.7 DRY DENSITY (pcf) 93.0 RELATIVE COMPACTION 92.6 Date: 3-11-03 DEPTH (ft) - 1 - - 2 - - 4 - - 5 - - 6 - - 7 - - 8 - - 9 - SAMPLE Q \ Logged by: SJM T-2 DESCRIPTION ALLUVIUM: Silty fine to medium sand. Tan to rust colored. Some cobbles. Moist. Loose. Sidewall caving. ST-1 FORMATIONAL ROCK: Sandstone. Fine grained. Tan color. Slightly micaceous. Weathered friable. Massive. Poorly cemented. ST-2 End Test Trench at 61/2', Sidewall caving in upper 3'. No groundwater. VINJE & MIDDLETON ENGINEERING, INC Escondido, California 92029-1229 Office 760-743-1214 Fax 760-739-0343 T Sand Cone Test • Bulk Sample uses SYMBOL SM \ SP MOISTURE 23.1 "• i — ^^— DRY DENSITY (pcf) 91.0 RELATIVE COMPACTION 90.6 TEST TRENCH LOGS HIGHLAND DRIVE, CARLSBAD PROJECT NO. 03-262-P PLATE 3 Q Nuclear Test O Driven Rings P" te. to P» il m m p» IM f* Li P" III 1* Date: 5-14-03 Logged by: SJM DEPTH (ft) - 1 - 1 - 3 - - 4 - 5 - 7 - - 8 - - 9 - SAMPLE • Q : -^ \ T-3 DESCRIPTION ALLUVIUM: Silty fine sand. Tan color. Some cobbles. Moist. Loose. ST-1 FORMATIONAL ROCK: Sandstone. Fine grained. Gray to tan color. Slightly micaceous. Weathered friable. Poorly cemented. Massive. Moist to very moist. ST-2 Fine sandy claystone. Gray color. Rust colored iron staining. Moist. Very stiff. Weeping at 5'. ST-3 End Test Trench at 6'. No caving. Groundwater seeps at 5'. uses SYMBOL SM SP CL \ 1 MOISTURE (%) 27.2 DRY DENSITY (pcf) 93.8 RELATIVE COMPACTION (%) 93.4 P w P P I •1 1II E m Date: DEPTH (ft) - 1 - - 2 - - 3 - - 4 - - 5 - - 6 - - 7 - - 8 - - 9 - SAMPLE Logged by: DESCRIPTION VINJE & MIDDLETON ENGINEERING, INC 2450 Vineyard Avenue, Suite 102 Escondido, California 92029-1229 Office 760-743-1214 Fax 760-739-0343 ^f~ Groundwater • Bulk Sample uses SYMBOL MOISTURE DRY DENSITY (pcf) RELATIVE COMPACTION TEST TRENCH LOGS HIGHLAND DRIVE, CARLSBAD PROJECT NO. 03-262-P PLATE 4 Q Nuclear Test O Driven Rings F L