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Home My WebLink About1993-070 Proposal - Marquess1120 EAST JACKSON STREET P.O. BOX 490 M EDFORD OREGON 97501 TELEPHON E: (503) 772-7115 FAX: (503) 779-4079 August 9, 1993 Steven P. Hall Public Works Director City of Ashland 20 East Main Street Ashland, Oregon 97520 RE: GEOTECHNICAL INVESTIGATION PROPOSED ADNINISTRATIVE BUILDING CITY OF ASHLAND ASHLAND, OREGON NAI JOB NO. 7-10.4 Dear Mr. Hall: Introduction As requested, we have performed a geotechnical nvestigation for the proposed Administrative Building for the City of Ashland. The approximate location of the building site is shown on Drawing 1, Site Plan. The purpose of our investigation was to evaluate the prevailing soil and foundation conditions in the building area and develop findings and recommendations for the earthwork and foundation engineering aspects of the project. As shown on the preliminary drawings by Gary N. Afseth, Architect, the new building will be located behind the existing Police Department and Justice Center Building on East Main Street. The structure will be one story and roughly rectangular in shape with plan dimensions of about 81x136 feet. The building will utilize wood framing and slab-on-grade floors. Maximum column loads are expected to be 46 kips. The finished floor will be established at elevation 1894.45 feet. Scope As presented in our proposal letter dated July 2, 1993, the scope of services for this investigation was to include: 1. Review of available published and unpublished geologic and geotechnical information for this area. 2. Subsurface exploration consisting of three exploratory borings under the observation of our engineer. 3. Laboratory testing of samples obtained from the borings. Mr. Steven P. Hall August 9, 1993 Page 2 Geotechnical engineering analyses using the field and laboratory data and preparation of a geotechnical investigation report. The report presents findings and recommendations for the following: a) Site geology. b) Site preparation and grading for the building. c) Building foundation type, minimum dimensions, and allowable bearing values. d) Estimated foundation settlements. e) Treatment of expansive soils, as appropriate. f) Support of interior and exterior slabs-on-grade. Backfilling and compaction of utility trenches. h) Surface and subsurface drainage. i) Any other unusual design or construction conditions encountered in the investigation. This report has been prepared for the specific use of the City of Ashland and their consultants in accordance with generally accepted soil and foundation engineering principles and practices. No other warranty, either expressed or implied, is made. In the event that any substantial changes in the nature, design, or location of the building is planned, the conclusions and recommendations of this report shall not be considered valid unless such changes are reviewed and the conclusions of this report modified or verified in writing. It should also be recognized that changes in the site conditions may occur with the passage of time due to environmental processes or man-made changes. Furthermore, building code or state of the practice changes may require modifications in the recommendations presented herein. Accordingly, the recommendations of this report should not be relied on beyond a period of three years without being reviewed by a civil engineer that is knowledgeable and experienced in soils engineering. Method of Investiqation The site reconnaissance and subsurface exploration were performed by our geotechnical engineer on July 21, 1993. Three exploratory borings were drilled to a maximum depth of 25 feet using a truck-mounted continuous hollow stem auger drill rig (Mobile B-80) at the locations shown on Drawing 1. A key describing the soil classification system and soil consistency terms used in this report is presented on Drawing 3 and the soil sampling procedures are described on Drawing 4. Logs of the borings are presented on Drawings 6 through 9. Mr. Steven P. Hall August 9, 1993 Page 3 The borings were located in the field by pacing and interpolation of the features shown on the drawings provided us. These locations ~hould be considered accurate only to the degree implied by the method used. Samples of the soil materials from the borings were returned to our laboratory for classification and testing. The results of moisture content, dry density, percent finer than No. 200 sieve, free swell, and plasticity index tests are shown on the boring logs. Drawing ]0 presents additional information on the plasticity tests. The laboratory test procedures followed during this investigation are summarized on Drawing 5. A bibliography of references consulted during this investigation is included at the end of the text. Site Conditions A. Surface The building site is a grass covered landscaped area which slopes approximately three percent to the north. The surface grades vary from elevation 1895.0 to ]891.8 feet. There are underground storm drain and sewer pipes in the western and southern portions of the site. The building site is generally bounded to the west, north, and east by asphalt paved parking areas and on the south by landscaping. We understand that the site was previously used as a lumber mill. B. Subsurface The geologic map (Beaulieu and Hughes, 1977) reviewed indicates that the site is underlain by Quaternary age alluvial fan deposits consisting of unconsolidated mixtures of gravel, sand, silt, and clay. The exploratory borings encountered six to seven feet of fill at the site. The fill generally consisted of loose to medium dense silty sand and clayey sand with occasional boulders. In Boring 2, however, loose to very loose silty sand and debris, including brick, concrete, charred wood, wire, glass, and rags, were encountered to five feet. The fill materials were underlain to the depths explored in the borings by medium dense to dense silty sand and very stiff sandy clay. The borings and probes by Ferrero Geologic (]993) at the site encountered roughly similar silty sand fill materials with randomly occurring debris and organics. The subsurface information from this study is summarized on Drawing 1]. The fill materials and underlying natural silty sands have a low plasticity based on their classification and Atterberg Limits tests (plasticity index of ]0 percent for the clayey sand fill in Boring 1 at six feet). The results of our Atterberg Limits testing are shown on the boring logs and on Drawing 10. Mr. Steven P. Hall August 9, 1993 Page 4 The attached boring logs and related information depict subsurface conditions only at the specific locations shown on Drawing I and on the particular date designated on the logs. Soil conditions at other locations may differ from conditions occurring at these locations. Also, the passage of time may result in a change of conditions at these boring locations due to environmental changes. C. Groundwater Free groundwater and wet soils were encountered during drilling at depths of 4.5, 6.5, and 5.5 feet, respectively, in Borings 1, 2, and 3. Free flowing groundwater was encountered at depths of 10.5 to 13.5 feet in the borings. The upper groundwater levels in the borings appear to be due to perched groundwater. Borings 2 and 3 were left open for two days to allow time for the water levels in the holes to stabilize prior to backfilling. The measured water levels were 7.5 and 4.5 feet in Borings 2 and 3, respectively. Boring 1 was backfilled upon completion of drilling. Fluctuations in the groundwater level may occur, however, because of variations in rainfall, temperature, runoff, irrigation, and other factors not evident at the time our observations were made and reported herein. Conclusions and Recommendations From a soil and foundation engineering standpoint, we conclude that the site can be developed as proposed provided the recommendations of this report are incorporated into the design and construction of the project. The existing fill soils are locally weak and compressible and contain random deposits of organic materials and building debris. In their present condition, the fill soils are considered unsuitable for foundation support. In order to provide adequate support for the building, we recommend that all of the fill materials be removed from the site and replaced with approved engineered fill materials as discussed below under "Earthwork". The building can then be supported on conventional spread footing foundations which bear in the engineered fill materials. Construction dewatering of the excavated hole is expected to be required during construction. We recommend that a gravel trench drain be installed around the perimeter of the bottom of the over-excavation. The drain should be installed in conjunction with the excavation operations. The recommended perforated pipe subdrain that will be installed as part of the drain will also mitigate the high groundwater conditions beneath the building. The recommendations presented in the remainder of the report are contingent on our review of the earthwork and foundation plans for the project and our observation of the earthwork and foundation installation phases of construction. Mr. Steven P. Hall August 9, 1993 Page 5 A. Earthwork 1. Clearing and Site Preparation The area to be graded should be cleared of utilities, landscaping, and any other obstructions encountered during grading. Holes resulting from the removal of underground obstructions that are deeper than the proposed excavations should be backfilled with suitable material and compacted to the requirements for engineered fill. Earth material that is mixed with construction debris should not be used for engineered fill. The backfilling operations should be performed under the observation of the soil engineer. 2. Over-excavation and Recompaction of Existinq Fill All existing fill materials beneath the proposed building should be removed over their full depth. The fill materials were encountered to depths of 7.0, 7.5, and 6.0 feet, respectively, in Borings 1, 2, and 3. The lateral limits of the proposed over-excavation and new fill placement should extend at least five feet beyond the layout of the building foundations. A schematic of the recommended over-excavation and a detail of the subdrain are shown on Drawing 2, Cross-Section A-A~. The existing fill materials can be selectively stockpiled off-site for re-use as engineered fill. Limited observations and tests were performed on the existing fill soils at the site. These findings indicate that the brown silty sands and clayey sands (see Borings 1 and 3) appeared to be free of organics and construction debris and can probably be re-used as engineered fill. The gray, dark brown, and black soils, however, contain significant undesirable materials (see Boring 2) and should not be re-used as fill. In general, the fill soils may be re-used provided that deleterious materials, such as construction debris and organics, are not present. If the existing fill soils are re-used as fill, the soils will require considerable drying and processing (particularly the lower portion of the existing fill) in order to achieve satisfactory compaction. The exposed bottom of the over-excavation should be protected from softening due to excessive traffic and moisture. Therefore, we recommend that the subdrain discussed above be installed during the excavation process. In addition, we believe a large backhoe or excavator should be used to dig the hole and trench drain since it could move at surface grades and cause less disturbance to the bottom of the hole than a bulldozer. Mr. Steven P. Hall August 9, 1993 Page 6 Loosened soil at the bottom of the over-excavation should be compacted with light equipment. After these soils are compacted, the over-excavation can then be brought up in lifts with approved fill materials that are compacted to the requirements for engineered fill. The lower three feet of the fill in the over-excavation should consist of approved compacted shale fill. Shale fill (or equivalent) should meet the requirements of Item A-5 below. All other imported fill materials should meet the requirements for engineered fill. 3. Dewatering During Construction Groundwater was encountered at depths of 4.5 to 6.5 feet. It is expected that the dewatering can be accomplished by using a trench drain with crushed gravel around the west, south, and east sides of the excavation as shown on Drawing 1. A sump pump may also be required in the northern portion of the excavation. 4. Temporary Cutslopes The excavations of the fill will be at least 5.0 to 7.5 feet deep. We anticipate that temporary cutslopes will be stable at inclinations of one horizontal to one vertical (1:1) or flatter. The slopes will have to be laid back further if the slopes are weakened by substantial groundwater seepage. The actual temporary slope inclination used during construction should be selected by the contractor since the stability of the cutslopes will depend on many factors, some of which they can control. 5. Fill Placement and Compaction All approved on-site soils with an organic content of less than three percent by volume and free of construction debris are suitable for use as fill. The gray, dark brown, and black existing fill soils are not suitable for re-use as structural fill. Fill material should not contain rocks or lumps larger than six inches in greatest dimension with no more than 15 percent larger than 2.5 inches. Imported fill materials should be predominantly granular with a plasticity index of 12 or less. All fill placed at the site should be compacted by mechanical means only to at least 90 percent relative compaction, as determined by ASTM Test Designation D1557. Fill should be placed in lifts not exceeding eight inches in uncompacted thickness. Compaction should be performed using heavy compaction equipment such as a sheepsfoot or self-propelled vibratory compactor. Mr. Steven P. Hall August 9, 1993 Page 7 Three-inch minus crusher-run shale used to fill the over-excavation. below: rock (or approved equivalent) may be The shale should meet the requirements TABLE I - Recommended Material Specifications for Shale Fill Sieve Size Percent Passing 3" 100 2-1/2" 30 - 100 #4 20 - 50 #200 10 - 30 Sand Equivalent = 25 Min. Plasticity Index = 12 Max. L.A. Rattler Resistance : 45 Max. Compaction of the shale should be performed with a heavy self-propelled vibratory roller. Each thin lift should be compacted with at least four passes of a vibratory roller capable of producing at least 18,000 pounds dynamic force. The compaction should be evaluated by proof rolling with a lO-yard loaded lO-wheel gravel dump truck. 6. Surface Drainaqe Positive surface gradients of at least one percent on paved surfaces and two percent on unpaved surfaces should be provided adjacent to the building to direct surface water toward suitable collection facilities. Water from roof gutters and downspouts should be tied into closed pipes that drain into suitable discharge facilities. Water on paved surfaces next to the building should be directed to drain inlets that also drain to approved facilities. Surface water drainage systems should be maintained separately from underground subdrainage systems. 7. Trench Backfill Utility trenches should be backfilled with engineered fill placed in lifts not exceeding eight inches in uncompacted thickness, except thicker lifts may be used with the approval of the soil engineer provided satisfactory compaction is achieved. If on-site soil is used, the material should be compacted to at least 85 percent relative compaction by mechanical means only. Imported clean sand can also be used for backfilling trenches provided it is compacted to at least 90 percent relative compaction. In building, slab, and pavement areas, the upper three feet of trench backfill should be compacted to at least 90 percent relative compaction for on-site soils, and 95 percent where imported clean sand backfill is used. Mr. Steven P. Hall August 9, 1993 Page 8 8. Construction Observation Grading and earthwork should be monitored and tested by our representative for conformance with the project plans/specifications and our recommendations. This work includes site preparation, selection of satisfactory fill materials, and placement and compaction of the fill. Sufficient notification prior to commencement of earthwork is essential to make certain that the work will be properly observed. B. Foundations The building can be supported on conventional continuous and isolated spread footings bearing in the engineered fill materials that will underlie the structure. Footings should be founded at least 18 inches below lowest adjacent finished grade. Continuous footings should have a minimum width of 15 inches and isolated footings should be at least 24 inches square. Footings located adjacent to utility trenches should have their bearing surfaces below an imaginary 1.5:1 (horizontal to vertical) plane projected upward from the edge of the bottom of the trench. At the above depths, footings may be designed for an allowable bearing pressure of 2000 psf due to dead loads with a one-third increase for dead plus live loads and a 50 percent increase for total design loads including wind and seismic. All continuous footings should be provided with at least two number four reinforcement bars, top and bottom, to provide structural continuity and to permit spanning of local irregularities. Soil conditions in the footing bottoms should be inspected by our representative prior to placing reinforcing steel or concrete. Lateral loads may be resisted by friction between the foundation bottoms and the supporting subgrade. A friction coefficient of 0.30 is considered applicable. As an alternative, an equivalent fluid pressure of 300 pcf can be taken against the side of footings poured neat. Settlements under the anticipated loads are expected to be within tolerable limits for the proposed construction. C. Retaining Walls Any retaining walls at the site should be designed to resist lateral earth pressures from the backfill and any surcharge loads. Unrestrained walls should be designed to resist an active equivalent fluid pressure of 45 pounds per cubic foot for level backfill conditions. Restrained walls should be designed to resist an equivalent fluid pressure of 45 pcf plus an additional uniform lateral pressure of 8H pounds per square foot where H = height of backfill above the top of the wall footing in feet. Mr. Steven P. Hall August 9, 1993 Page 9 Lateral surcharge loads may also develop on the walls from live areal loads on the wall backfill. Where these loads are anticipated, the walls should be designed for an additional uniform pressure equivalent to one-third or one-half the anticipated areal surcharge load depending on whether the wall is unrestrained or restrained, respectively. The preceding pressures assume that sufficient drainage is provided behind the walls to prevent the build-up of hydrostatic pressures from surface or subsurface water infiltration. Adequate drainage may be provided by means of a backdrainage system consisting of a four-inch diameter, rigid perforated pipe placed at the base of the wall with the perforations down, and a 12-inch wide, 3/4 inch drain rock section carried to within one foot of the top of the wall. The upper one foot should be backfilled with compacted impermeable soil or surfaced with impermeable paving materials. The drain rock should be backed with filter fabric, such as Mirafi 140. Water collected from behind the walls should drain to approved discharge facilities. Details regarding locations and heights of retaining walls were unavailable at the time of this report. D. Slabs-on-Grade Slab-on-grade construction will be used for the building floors. Just prior to final preparation for the slabs, the slab subgrade surface should be proof rolled to provide firm, smooth support. The slab should be underlain by four inches of 3/4 inch free draining crushed rock or gravel and an impervious membrane such as 6 mil visqueen that is placed over the gravel in order to provide a capillary moisture break. The membrane should be covered with two inches of sand to protect it during construction. The sand should be lightly moistened just prior to placing the concrete. Exterior walkway slabs should be supported on a minimum of four inches of compacted imported non-expansive fill consisting of granular soil with a plasticity index of twelve or less and no more than ten percent finer than #200 sieve. Reinforcement of slabs should be provided in accordance with the anticipated use and loading, but as a minimum, slabs should be reinforced with 6x6 W2.9xW2.9 welded-wire mesh or number three bars at 16 inches on center, both ways. Plan Review and Construction Observation We should review the foundation and grading plans and specifications for the project. We should also be retained to provide monitoring and testing services during the grading and foundation installation phases of the project. This will provide the opportunity for correlation of the subsurface conditions found in our investigation with those actually encountered in the field, and thus permit any necessary modifications in our recommendations resulting from changes in anticipated conditions. Mr. Steven P. Hall August 9, 1993 Page lO If you have any questions regarding this report, please call. Sincerely, MARQUESS & ASSOCIATES, INC. Rick Swanson, P. E. Geotechnical Engineer (California) Randy C~eveland, P. E. RS, RCC/pc ~ ,E.,'(PIRES: 12/31/93 Copies: Addressee (5) Attachments: Bibliography Site Plan, Drawing 1 Cross-Section A-A*, Drawing 2 Key to Boring Logs, Drawing 3 Summary of Field Sampling Procedures, Drawing 4 Laboratory Testing Procedures, Drawing 5 Logs of Exploratory Borings 1-3, Drawings 6-9 Plasticity Chart, Drawing lO Summary of Borehole and Testhole Data by Others, Drawing 11 RS-14 Biblioqra~h¥ Beaulieu, John D., and Paul W. Jackson County, Oregon, Industries, Bulletin 94. Hughes, 1977, Land Use Geology of Central State of Oregon Dept. of Geology and Mineral Ferrero Geologic, 1993, Geologic Investigation of Foundation Site, New City of Ashland Administrative Building, Ashland City Building Complex, Mountain and East Main Streets. ELEVATION IN FEET ? ~ ~ m m~ //~ !~ / m Z 0 00~, oO ~Z )> GROUP PRIMARY DIVISIONS SYMBOL SECONDARY DIVISIONS GRAVELS Cl.[AN C~W Well graded gravels, grovel-sand mixtures, little or ..I OR AV~LS no fines. U~, < MORE I~'IAN HALF (LESS 'n-lAN Poorly graded gravels, or gravel-sand mixtures, little 0~3 ~ ~ OF COARSE 5X FINES) GP or no fines. Silty grovels, gravel-send-slit mixtures, · 6 FRACTION IS ORA~I"[- (~M non-plastic fines. No. 4 SIEVE FINES (~C clayey gravels, gravel-sand-clay mixtures, -- ~lastic fines. ~ ~;~ SANDS CLEAN SW , well graded sands, gravelly sands, little or no fines. ~ SANDS ~ MORE I~tAR HALF (Ir'SS ~IAR PooHy graded sands or gravelly sands, little or ~ ~ OF COARSi; 5~, FINES) SP no fines. ~ ~ . FRAC~ON IS SANDS SM Silty sands, sand-silt mlxtrues, non-plastic fines 0 No. 4 SIE~/[ FINES SC Clayey sands, sand-clay mixtures, plastic fines. cn I~ SILTS AND CLAYS ME Inorganic silts and very fine sands, rock flour, silty or ..I clayey fine sands or clayey silts with sli,qht plasticity. h ~ UQUID UMIT IS CL inorganic clays of iow to medium plasticity, gravelly ~ 3: O~ LESS THAN ~ clays, sandy clays, silty cloys, lean clays. OL Organic silts and organic silty clays of Iow plasticity. ~ -- Inorganic silts, m~caceous or diatomaceous fine .~ SILTS AND CLAYS MH sandy or silty soilsr elastic silts. ~ I~ U(~JID U~,T IS CH Inorganic clays of high plasticity, fat clays. z GREA'IER 1HAN · · OH OrganiCor~anic silts.Clays of medium to high plasticity, HIGHLY ORGANIC SOILS Pt Peat and other highly organic sells. UNIFIED SOIL CLASSIFICATION SYSTEM (ASTM D-2487~ U.S. STANDARD SERIES SIEVE CLEAR SQUARE SIEVE OPENINGS 200 40 10 4 3/4" 3' 12" SAND GRAVEL SILTS AND CLAYS ;OBBLE$ BOULDERS SANDS & GRAVELS BLOWS/FOOT1' SILTS & CLAYS !STRENGTH=l: BLOWS/FOOT1' VERY LOOSE 0 - 4 'v~Y SOFT 0 - 1/4 0 - 2 LOOSE 4- 10 ~ SOFT 1/4- 1/2 2 - 4 RRM I/2 - 1 4 - 8 MEDIUM DENSE 10 - .30 STIFF 1 - 2 8 - 16 DENSE 50 - 50 VERY STIFF 2 - 4 16 - 32 I i VERYDEN~ OVER 50 HARD OVER4 I 0~R32I RELATIVE DENSITY CONSISTENCY ~Number of blows of 140 pound hammer failing 30 inches to drive a 2 inch O.D. (1-3/8 inch I.D.) split spoon (ASTM D-1586). =~=Unconfined compressive strength in tons/sq, ft. as determined by laDoratory testing or approximated by the standard penetration test [ASTM D-1586), pocket penetrometer, torvone, or visual observation. KEY TO BORING LOGS MARQUESS & ASSOCIATES, INC. ADMINISTRA1WE BUILDING CONSULTING ENGINEERS 1120 East Jackson Street (50,3) 772-7115 ASHLAND, OREGON MEDFORD, OREGON 97504 PROJECT NO. DA'IE ORA~JNG NO. 7-10.4 AUGUST. 1993 SANDS & ORAVELS BLOWS/FOOT1' VERY LOOSE 0 - 4 LOOSE 4 - 10 MEDIUM DENSE 10 - .30 DENSE 50 - 50 VERY DEN~ OVER 50 SILTS & CLAYS STRENGTH=l: BLOWS/q:'OOT1' 'v~RY SOFT O- 1/4 O- 2 SOFT 1/4- 1/2 2 - 4 RRM I/2 - 1 4 - 8 STIFF 1 - 2 8 - 16 VERY STIFF 2 - 4 16 - 32 HARD OVER 4 OVER 32 FIELD SAMPLING PROCEDURES The soils encountered in the borings were continuously logged in the field by our representative and described in accordance with the Unified Soil Classification System (ASTM D-2487). Representative soil samples were obtained from the borings at selected depths appropriate to the soil investigation. All samples were returned to our laboratory for classification and testing. In accordance with ASTM- D1586 procedure, the standard penetration resistance blow counts were obtained by dropping a 140 pound hammer through a 50-inch free fall. The 2-inch O.D. split spoon sampler was driven 18 inches or to practical refusal and the number of blows were recorded for each 6-1rich penetration Interval. The blows per foot recorded on the boring logs represent the accumulated number of blows required to drive the penetration sampler the final 12 inches. In addition, ,3.0 inch O.D. x 2.42 inch I.D. drive samples were obtained using a Modified California Smapler and a 140 pound hammer. Blow counts for the Modified California Sampler are shown converted to standard penetration resistance by multiplying by 0.6. The sample type is shown on the boring logs in accordance with the designation below. 6" x 2.42" liners% Bag Sample---...~ Modified California Sampler Standard Split Spoon Sampler Where obtained, the shear strength of the soil samples using either Torvane (TV) or Pocket Penetrometer (PP) devices is shown on the boring logs in the for right hand column. MARQUESS & ASSOCIATES, INC. CONSULTING ENGINEERS 1120 East Jackson Street (50.3) 772-7115 MEDFORD, OREGON 97504 SUMMARY OF FIELD SAMPLING PROCEDURES ADMINISTRATIVE BUILDING ASHLAND, OREGON PROJECT NO. I OA]E I DRA~INO NO. 7-10.4 AUGUST, 1993 4 LABORATORY TESTING PROCEDURES The laboratory testing program was directed toward a quantitative evaluation of the physical and mechanical properties of the soils underlying the site. The natural water content was determined on 31 samples of the materials recovered from the borings in accordance with the ASTM D2216 Test Procedure. These water contents are recorded on the boring logs at the appropriate sample depths. Dry density determinations were performed on 18 samples to measure the unit weight of the subsurface soils in accordance with the ASTM D2937 Test Procedure. The results of these tests are shown on the boring logs at the appropriate sample depths. An Atterberg Limit determination was performed on a sample of the existing fill soils in accordance with the ASTM D4318 Test Procedure to determine the range of water content over which the materials exhibited plasticity. The Atterberg Limits are used to classify the soil in accordance with the Unified Soil Classification System and to evaluate the soil's expansion potential. The results of these tests are presented on Drawing 10 and on the Log of Boring 1 at the appropriate sample depth. The percent soil fraction passing the #200 sieve was determined on nine samples of the subsurface soils in accordance with the ASTM Dl140 Test Procedure to aid in the classification of the soils. The results of these tests are shown on the boring logs at the appropriate sample depths. Free swell tests were performed on three samples of the soil materials to evaluate the swelling potential of the materials. The tests were performed by pouring ten grams of the dry material into a 100 mL graduated cylinder containing about 40 mL of distilled water. The mixture was stirred repeatedly and allowed to equilibrate for 24 hours, then distilled water was added up to the 100 mL mark. The graduated cylinder was stoppered and left undisturbed to equilibrate. The free-swell volume was then noted. The percent free swell was calculated by dividing the free-swell volume by ten and multiplying by 100 percent. The results of these tests are presented on the boring logs. Drawing No. 5 EQUIPMENT 8' HOLLOW STEM AUGER~ ELEVATION 1892':1:: LOGGED BY RS DEPTH TO GROUNDWA3ER 13.5':~: DEPTH TO BEDROCK NOT ENCOUNTERED DATE DRILLED 7-21-93 DESCRIPTION AND CLASSIFICATION DEPTH ~ ~ <z~ C SO~L (FEET) ~ ~ ~ ~ DESCRIP~ON AND REMARKS COLOR CONSIST. TYPE ~< ~ ~ o~ ~ z~ ~ ~z .~ SILTY SAND, dry to moist in upper Brown Loose SM 2', moist below (fill) to 1 -~ ,~ 98 Medium - ~ 20 6 102 0 1.5': Finer than ~200 = 26% Dense Free Swell = 10~ 2 traces of free water at 4-.5' during - 3 -X 17 7 drilling - · -I~ 12 121 CLAYEY SAND, wet, with silt Brown Loose SC - s to Medium - s - 20 13 Fill I Dense SILTY SAND. very moist, locally Brown Dense SM- _ very silty to ML ~ Gray ~ 21 112 ~ 8.5': Finer then #200 = 49~[ Brown e ~ 40 22 104 0 6': Liquid Limit == 25~ - ~0 - Plasticity Index = 10~ -X 37 19 Finer than ~200 = 18% . Free Swell = 15~[ ~rilling - X 34 12 -X 46 16 -- 3D LOG OF BORING 1 MARQUESS & ASSOCIATES, INC. ADMINIS'I~ATIVE BUILDING CONSULTING ENGINEERS ASHLAND, OREGON 1120 East Jackson Street (503) 772-7115 MEDFORD. OREGON 97504- PROJECT NO. DATE ORA~tNO NO. 7-10.4 AUO~JST, 199;3 6 EQUIPMENT 8' HOt. LOW STEI~ AUGER* ELEVATION 1892'+ LOGGED BY RS DEPTI'I TO GROUNDWATER 13.5'v~* DEPTI'I TO BEDROCK NOT ENCOUNTERED DATE DRILLED 7-21-93 DESCRIPTION AND CLASSIFICATION DE:pm ~ z~ (FEE~) ~ SO~L z DESCRIPTION AND REMARKS COLOR CONSIST. TYPE v~ u:-~ SILTY SAND, very moist Brown Dense SM SANDY CLAY, moist Brown Very CL" I_ 22 Stiff - 23 - - 24 - 22 21 Bottom of Boring = 25' - 2~ - *Drilled with Mobile B-80 - 27 - ** Boring wos bockfllled upon completion of drilling. - 2~ - Groundwoter level in borehole wos not given sufficient time to stobilize. - 32 - - 37 - LOG OF BORING 1 MAROUESS & ASSOCIATES, INC. ADMINISTRATIVE BUILDING CONSUL'I1NG ENGINEERS ASHLAND, OREGON 1120 East Jackson Street (50,3) 772-7115 IdEDFORD, OREGON 97504. PROJECT NO. DATE DR^~ING NO. 7-10.4 AUOUST, 199,3 E~UIPMENT 8" HOI.LOW STEId AUGER* ELEVA~ON 1893.3'~: LOGGED BY RS DEPTH TO GROUNDWA'I-cR 7.5' DEPTH TO BEDROC~ NOT ENCOUNTERE~ DATE DRILLED 7-21-93 DESCRIPTION AND CLASSIFICATION DEPTH ~ ~< ~ ~ SILTY SAND, moist, with brick and Brown, Loose SM concrete fragments, charred wood, Dark to ~ -~1 9 94 rags, boulders 3.5'-5', glass, Brown Very -I 9 14 92 wire (fill) and Loose Black ~ - X 4 ',NO :£COVEI ~Y) 5 SILTY SAND, moist, wet at 6.5' Gray Medium SM -~/ 16 96 free water at 6.5' during drilling Dense - s -~I 14 28 95 -X 28 12 after tilling) SILLY SAND, moist to very moist, Brown Medium SM - ~ very silty at 10' Dense 9 ~ 6': Finer than #200 -- SM- ~ 11': Finer than ~200 -- 4,t~ ML - ~ - 25 17 SILTY SAND, moist Brown Dense SM ~ 14.5': Finer than ]~200 -- 24% -X 41 12 *Drilled with Mobile B-80 _ ~? _ Bottom of boring = 20' -X 38 17 LOG OF BORING 2 MAROUESS & ASSOClAT[S, INC. CONSULTING ENGINEERS ADMINISTRA~VE BUILDING ASHLAND, OREGON 1120 East Jackson Street (505) 772-7115 MEDFORD, OREGON 97504 PROdECT NO. DATE DRA~ING NO. 7-10.4 AUGUST, 1993 EQUIPMENT 8° HOLLOW S'l~ AUG~~ ELEVAI~ON 1893.7"1' LOGGED BY RS DEP~I TO GROUNOWA'IER 4.5' DEPI~'t TO BED~OC}< NOT ENCOUNTERED DATE DRILLED 7-21-95 DESCRIPTION AND CLASSIFICATION DEPm ~ DESCRIP~ON AND REMARKS COLOR CONSIST. TYPE m a m ,_ SILTY SAND, moist, with pebbles Gray Medium SM Brown Dense ~ -I~j B 119 ~ 2 O 1.5': Finer than ~200 = 20% O 4': Finer than ~200 = 2.~% Brown - 3 -X 25 8 Free Swell = 4.0~ Free water on soil particles at 5.5' t ~1~ , 126 during drilling I - '~ -I ~2 SILTY SAND. moist, v~ry ,~ilty locally Brown Medium SM Dense - ~ -X 24 15 ~ 9': Finer than ~200 = 54% 7 - 8 - ~Free water tit 15' · Drilled with Mobile B-80 - ~7 - Bottom of boring = 20' X 35 15 LOG OF BORING MAROUESS & ASSOCIA'I~S, INC. CONSULTING ENGINEERS ADMINISTRATIVE BUILDING ASHLAND, OREGON 1120 East J~ckaon Street (505) 772-7115 IdEDFORD. OREGON 97504 PROJECT NO. DATE DR^~INO NO. 7-10.~- AUGUST. 1995 6O C3_z CL ~ U3 20 or <~ / OH ~ ~-JL ~ ~ ~ ML or OL I 0 0 10 20 ~ ~ ~ 60 70 ~ 90 1 O0 LIQUID LIMIT (~) UNIR~ NA~R~ P~NG KEY B~NG S~P~ WA~ U~ID P~Q~ NO. 2~ U~lOl~ ~L S~B~ NO. ~ ~NT UMIT IND~ ~E~ IN~X ~S~RCA~ON (~t) ~ ~ ~ ~ S~ ~ 1 6.0 13 25 10 18 --0.2 SC* *Clessifi ~d as cia ~y send s ~ce fracti ,n finer ti an ~200 rove is le: s than 5( percent PLAS~CITY CHART MARQUESS · ASSOClA~S, INC. ADMINIS~A~ BUI~ING CONSUL~NG ENGINEERS 1120 East Jecks~ Street (503) ~2-7115 A~L~D, OREG~ MEDFORD, OREGON 97504 PR~CT NO. DA~ DRAMNG NO. 7-10.4 AU~, 1993 1 0 '~ or oH O_-UL ,' ,~ ML or OL I P1 Depth (Feet) 0-5 5-9.2 Material Description Silty Sand and Sand (SM, SW) (Fill) Low to high plasticity Silt (ML to MH) L2 Depth (Feet) 0-6 6-9.2 Material Description Sand and Silty Sand (SW, SM) with rocks at 4' Silty Sand (SM) (Fill) Depth (Feet) 0-7.5 7.5-8.4 Material Description Sand and Silty Sand (SW, SP, SM) with minor Silt (ML) (Fill) Very dense Silty Sand (SM) P4 Depth (Feet) 0-5.5 5.5-6.5 Material Description Sand and Silty Sand (SW, SM, Very dense Silty Sand (SM) SP) with organics (Fill) Depth (Feet) 0-5.5 5.5-5.8 Material Description Sand and Silty Sand (SP, (Fill) Very dense Silty Sand (SM) SW, SM) with organic lense at 2' Depth (Feet) 0-4.1 4.1-4.8 Material Description Sand (SW, SP) with organics Very dense Silty Sand (SM) (Fill) P_Z7 Depth (Feet) 0-4 Material Description Sand and Silty Sand (SM, SW) with rocks (Fill) Summary of Borehole and Testhole Data by Others ADMINISTRATIVE BUILDING Ashland, Oregon HAI Job No. 7-10.4 Drawing 11