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Home My WebLink About; Dam Site Adjacent to Mt. Hinton; Dam Site Adjacent to Mt. Hinton; 1960-08-12SOILS INVESTIGATION Proposed Dam Site Adjacent1 to Mt. Hinton San Diego County, California for the Carlsbad Municipal Water District Boyle Engineering Engineers Project No. 60-6-8AF August 12, 1960 BENTON ENGINEERING, INC. 4342 Fairmount Avenue San Diego 5, California SOILS INVESTIGATION Objectives The objectives of this investigation were to determine the existing subsurface conditions along the axis of a proposed dam to be constructed adjacent to Mt. Hinton, east of Carlsbad, California and also investigate possible sources of borrow material for earth fill. In order to accomplish these objectives, field explorations were made at three locations along the proposed axis of the dam and at ten possible borrow sources northeast of the dam axis. Laboratory tests were performed on representative samples of the proposed borrow material in order to classify the soils and to determine the physical characteristics of the soils when compacted. Field Investigation Three borings were drilled along the axis of the dam using a rotary diamond coring drill rig and continuous core recovery was attempted. However, in the more weathered zones little recovery was possible. The samples recovered have been stored in our laboratory. The depths of these borings varied from 73.8 to 80 feet below the existing ground surface. The ten borings in the proposed borrow areas were drilled to depths varying from 2.2 to 10 feet with a truck- mounted rotary bucket-type drill rig. Loose representative bag samples were obtained of the soils encountered in Boring IB to 6B, inclusive, and undisturbed samples were obtained at frequent intervals in the soils ahead of the drilling in Borings 1C to 4C, inclusive. Also, representative loose samples were obtained in Borings 1C to 4C, inclusive. The drop weight used for driving the sampling tube into the soils was the "Kelly" bar of the drill rig which weighs 1360 pounds, and the average drop was 12 inches. The driving energy required to force the sampling tube through one foot of soil is shown on Drawing No. 13. -2- The approximate locations of the exploration borings are shown on Drawing No. 1, entitled, "Location of Test Borings". Acontinuous log of the soils and rock formations encountered in the borings was recorded at the time of drilling and is shown on Drawing Nos. 2 to 13, inclusive, each entitled, "Summary Sheet". The soils were visually classified by field identification procedures in accordance with the Unified Soil Classification Chart. A simplified description of this classification system is presented in the attached Appendix A at the end of this report. Field pressure tests were performed at various depths in Borings 1A, 2A, and 3A. Laboratory Tests Laboratory tests were performed on three representative samples of the proposed borrow materials in order to classify, establish compaction criteria and to determine the permeability, internal angle of friction and cohesion of the compacted soils. A permeability test was also performed on an undisturbed sample obtained at a depth of 2 feet in Boring 1C. TEST PROCEDURES AND RESULTS Compaction Tests Compaction tests were performed on three representative samples of the proposed borrow soils to establish compaction criteria. The soils were tested according too modified A.S.T.M. D-698 method of compaction which uses 26 blows of a 10 pound hammer dropping 18 inches on each of 3 layers in a 4 inch diameter l/30th cubic foot mold. The results of the tests are presented below: Boring Depth Number in Feet 2C 4B 5B 2-4 1-2 4-5 Maximum Soil Dry Density Description Ib/cu ft Slightly silty fine to coarse sand Clayey fine to medium sand Slightly clayey fine to coarse sand 127.1 122.0 126.0 Optimum Moisture Content % dry wt 9.0 12.1 8.9 Note: all soil types are of "granitic" origin -3- Triaxiol Shear Tests Triaxial shear tests were performed on the three representative samples of the proposed borrow soils remolded at optimum moisture to 90 percent of the maximum dry density. The samples were allowed to become saturated by imposing a pressure head of water of approximately one half of the surcharge pressure. After the sample was saturated, the saturation pressure was removed and the sample was allowed to stand 24 hours. The triaxial test was run in approximately 15 minutes without permitting sample drainage. A representative moisture content was obtained after testing. Deviator stress versus strain curves were plotted for each test, and the devlator stress at 12 1/2 percent strain was picked for the ultimate stress. Mohr circle diagrams were plotted for each test to form a shear envelope. The plotted Mohr circles and shear envelopes are shown on Drawing Nos. 14,15, and 16, entitled "Shear Strength Remolded Soils". A correction of minus 200 pound per square foot should be applied to the cohesion shown on the drawings. This correction is due to a calibrated resistance in the testing apparatus. The internal angle of friction and corrected cohesion for the compacted soil samples are presented below: Boring 2C Boring 4B Boring 5B Depth 2'-4' Depth 1'-2' Depth 4'-5' Internal angle of friction 30 1/2° 26° 32° Cohesion (pounds per sq. ft.) 500 400 500 Grain-Size Analysis Tests were performed on four representative samples of the proposed borrow soils to determine the amount and size of the soil particles. The tests were performed in accordance with the procedures outlined in A. S.T. M. D422-54T with some modifications. A sieve analysis of the sample obtained between depths of 1 and 3 feet in Boring 4C indicated this soil to be -4- similar to the soil between depths of 4 and 5 feet in Boring 5B, therefore, hydrometer tests, to determine the percentage of silt and clay, were not performed on this sample. The results of the mechanical analyses are presented in graphical form on Drawing No. 17. Atterberg Limit Tests Atterberg Limit Tests were performed on the material passing the No. 40 sieve in accordance with the procedures outlined in A.S.T.M. D423-54T and A.S.T.M. D424-54T. The results of these tests are as follows: Liquid Limit Plasticity Index Permeability Tests Boring 2C Depth 2 '-4' Less than 25 Non-Plastic Boring 4B Depth T-21 25.6 7.6 Boring 5B Depth 4' -5' Less than 25 Non-Plastic A constant head test was performed on the soil sample from Boring 2C at a depth of 2 to 4 feet and falling head tests were performed on three other representative soil samples. Samples from Borings 2C, 4B, and 5B were remolded in a 4 inch diameter 1/30 cubic foot permeameter cylinder to 90 percent of the maximum dry density and a one inch high undisturbed sample obtained at a depth of 2 feet in Boring 1C was tested within a 2.5 inch O. D. brass liner ring. The head differential in the constant head test was 52 3/4 inches. The heights of head above the bottom of samples in the falling head tests were as follows: Boring Number 4B 5B 1C Depth in Feet 1-2 4-5 1.5-2.0 Trial 1 2 1 2 1 2 Height at Start of Test in Inches 71 1/8 71 1/8 71 1/8 71 1/8 493/4 49 3/4 Height at Ei of Test in Ir 50 1/4 50 1/4 50 1/4 50 1/2 44 1/4 44 1/4 The calculated coefficients of permeability, corrected to a temperature of 20° Centigrade, are presented on the following page. -5- V. Coefficient of Boring Number 2C 4B 5B 1C Depth in Feet 2-4 1-2 4-5 2.0-2.5 Type of Sample Remolded Remolded Remolded Undisturbed Trial 1 2 1 2 1 2 1 2 Type of Test Constant Head Fall ing Head Falling Head Falling Head Permeability cm/sec . 2.38x 10";? 1.64x 10"5 2.00x 10";? 1.84x 10"° 4.49x 10"5 7. 15 x ID'6 1.04x10" 7.82 x 10"° Field Pressure Tests Field pressure tests were performed at various depths in Borings 1A, 2A and 3A under a hydrostatic head of 50 psi at the ground surface. A round rubber seal which expanded when a vertical load was applied to the top of it by the drill stem was used in sealing the borings at various depths. It should be noted that during some of the tests water apparently either by-passed the seal or flowed through the fractured zones adjacent to the seal.The results of the tests and observations were as follows: Boring Number 1A 2A 3A Depth of Seal Below Surface in Feet 67.6 57.6 49.5 39.5 19.5 61 50.5 49 39.5 29.5 19.5 9.5 Water Loss in Cubic Feet Remarks 5.2 C.F. in 10 min. Water flowed out top of hole 6.7 C.F. in 10 min. Water flowed out top of hole 5 min. after start of test 1.0 C.F. in 4 min. No water flowed out top of hole 4.3 C.F. in 4 min. Water flowed out top of hole 3 min. after start of test 4.0 C.F. in 4 min. No water flowed out top of hole —- No water loss No water loss -— No water loss 4.3 C.F. in 3 min. Water flowed out top of hole 4.0 C.F. in 3 min. Water flowed out top of hole 2.6 C.F. in 7 min. No water flowed out top of hole 5.6 C.F. in 3 min. Water flowed out top of hole Should any question arise concerning the testing procedures or the interpretation of the test data/ please feel free to contact us. Respectfully submitted/ BENTON ENGINEERING/ INC.*^S;/AL^— Reviewed v~Ph~TTTp BENTON ENGINEERING, INC, APPLIED SOIL MECHANICS - FOUNDATIONS PHILIP HENKING BENTON, PREB. CIVIL ENGINEER APPENDIX A. Unified Soil Classification Chart* 4342 FAIRMOUNT AVENUE SAN DIEOO 5, CALIFORNIA ATWATEH 1-S5B1 SOU. DESCRIPTION I. COARSE GRAINED. More than half of material is larger than No. 200 sieve size.** GRAVELS CLEAN GRAVELS More than half of ^Little or no fines) coarse fraction is larger than No. U sieve size but smaller than 1 inches. GRAVELS WITH PINES (Appreciable amount of fines) SANDS CLEAN SANDS More than half of (Little or no fines) coarse fraction is smaller than No. A sieve size. SANDS WITH FINES (Appreciable amount of fines) II. FINE GRAINED. More than half of material is smaller than No. 200 sieve size.** SILTS AND CLAYS Liquid Limit Less than 50 SILTS AND CLAYS Liquid Limit Greater than 50 GROUP TYPICAL SYMBOL NAMES GW Well graded gravels, gravel-sand mixtures, little or no fines. GP Poorly graded gravels, gravel-sand mixtures, little or no fines. CM Silty gravels, poorly graded gravel- sand-silt mixtures. GC Clayey gravels, poorly graded gravel-sand-clay mixtures. SW Well graded sand, gravelly sands, little or no fines. SP Poorly graded sands, gravelly sands, little or no fines. SM Silty sands, poorly graded sand- clay mixtures. PC Clayey sands, poorly graded sand- clay mixtures. ML Inorganic silts and very fine sands, rock flour, sandy silt or clayey-silt- sand mixtures 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. MR Inorganic silts, micaceous or diatomaceous fine sandy or silty soils, elastic silts* CH Inorganic clays of high plasticity, fat clays OR Organic clays of medium to high plasticity. PT Peat and other highly organic soils.HIGHLY ORGANIC SOILS *Adopted by the Corps of Engineers and Bureau of Reclamation in January, 1952. **A11 sieve sizes on this chart are U. S. Standard. BENTON ENGINEERING, INC. APPLIED SOIL MECHANICS - FOUNDATIONS 4342 FAIRMOUNT AVENUE PHILIP HENKING BENTON, PRES. SAN DIEGO 5, CALIFORNIA CIVIL ENGINEER APPENDIX B_ ATWATER 1-5581 Description of Sampling and Laboratory Testing Procedures Sampling The undisturbed soil samples are obtained by forcing a special sampling tube into the undisturbed soils at the bottom of the boring, at frequent intervals below the ground surface. The sampling tube consists of a steel barrel 2.50 inches inside diameter, with a special cutting tip on one end and a double ball valve on the other, and with a lining of thin brass rings, each one inch long. The sampler is driven approximately 18 inches into the soil and a six inch section of the center portion of the sample is taken for laboratory tests, the soil being still confined in the brass rings, after extraction from the sampler tube. The samples are taken to the laboratory in close fitting waterproof containers in order to retain the field moisture until completion of the tests. The driving energy is calculated as the average energy in foot-kips required to force the sampling tube through one foot of soil at the depth at which the sample is obtained. Shear Tests The shear tests are run using a direct shear machine of the strain control type in which the rate of deformation is approximately 0.1 inches per minute. The machine is so designed that the tests are made without removing the samples from the brass liner rings in which they are secured. Each sample is sheared under a normal load equivalent to the weight of the soil above the point of sampling. In some instances, samples are sheared under various normal loads in order to obtain the internal angle of friction and cohesion. Where considered necessary, samples are saturated and drained before shearing in order to simulate extreme field moisture conditions. Consolidation Tests The apparatus used for the consolidation tests is designed to receive one of the one inch high rings of soil as it comes from the field. Loads are applied in several increments to the upper surface of the test specimen and the resulting deformations are recorded at selected time intervals for each increment. Generally, each increment of load is maintained on the sample until the rate of deformation is equal to or less than 1/10000 inch per hour. Porous stones are placed in contact with the top and bottom of each specimen to permit the ready addition or release of water. Expansion Tests One inch high samples confined in the brass rings are permitted to air dry at 105° F for at least 48 hours prior to placing into the expansion apparatus. A unit load of 500 pounds per square foot is then applied to the upper porous stone in contact with the top of each sample. Water is permitted to contact both the top and bottom of each sample through porous stones. Continuous observations are made until downward movement stops. The dial reading is recorded and expansion is recorded until the rate of upward movement is less than 1AOOOO inch per hour* I S-J C3K l<d? f—I XXKJ X I K—I LJ I t—I I SJ ., I I N/tT dZ. t 1 1 i <n i F=>^^. i CARLSBAD MUNICIPAL WATER DISTRICT* Itk< hio u- , 6 _ 8 _ inIU L 1018 22 26 32 it 41 3 «> 1C SUMMARY SHEET BORING NO; 1A Relative Fl FV 45' Above 3A CORE RECOVERY 1 COLOR 5 jj» | t | 3 «gS £ * 3 ° >• •» "SfS~ »-: Brf it • X w tH. K. r 0-1 « K K DESCRIPTION ^memmmmm Non* /5" Froaments None 3" Fraflmenh 7" Core and Fraflmenh 14" Core 10" Cera None BROWN GRAY BROWN GRAY BLUE GRAY BROWN DECOMPOSED GRANITE (VERY FIRM) GRANITE BOULDER (HARD) DECOMPOSED GRANITE (VERY FIRM) T^A/* BENTON ENGINEERING ORAW^G N0 P-18668 CONTINUED ON DRAWING NO. 3 L2 Q cs; UJ O- y CO U z H »-o. fcJW Uo u. •SAO4 "5A-vfO 38 40- Af) -Inc. A<t44 AA*KJ .404O CrtOU COOz ' Cy*O4 H 56 ATIOU zoO/ A4 -O*» ~l 66 SAMPLENUMBERSUMMARY SHEET 1ABORING N0.__ El EV, CONTINUED FROM DRAWING NO. 2 None ^1/2" Core 9" Core None 8" Core and Fragments None 19" Core and Fragments 24" Core 18" Core and Fragment* GRAY BROWN BROWN GRAY BROWN GRAY AND PINK GRAY nRAY Bl 1 IP » H- 5 .. t £ «E 1" i » Sd -o:i 5s s- 52^^ * q o > 4 u^f S * m •£ K • i w =u. E «* o_inaeK DECOMPOSED GRANITE (VERY FIRM) (At 55'9" Lost Circulation. Added Aquajel With 350 Gallon! of Water.) GRANITE (HARD) PROJECT NO. QCM-rriM CMriKIC-CTDIMr DRAWIN6NO.60-6-8AF BENTON ENGINEERING 3 CONTINUED ON DRAWING NO. 4 0. HI W IIIo u- SUMMARY BORING NO.. ELEV SHEET 1A CONTINUED FROM DRAWING NO. 3 § t I!>• » O -I «*? ssi 60 70 72 74 76 78 20" Core and Fragments (Note; At 66*6" Lost Circulation Bit Dropped 2", Added 26" Core end Fragments 350 Gallons and Aquajel) GRAY BLUE GRANITE (HARD) 4" Cere 7'-7 1/2" Core ond Fragments Notes; Total water used between various depths is presented below: Oto5Q'-0"350 gallons 0£ I a. 0 z CO 50'-0" to 55'-9"100 gallons 55'-9" to 56'-6"350 gallons plus aquajel 56'-6" to 66'-6"350 gallons plus aquaiel 66^6" to 70'-5"350 gallons plus aquajel Cased hole to 70'-9" Used no water for 1 1/2" core between 7Q'-9" and 78'-6" PROJECT NO. 60-6-8AF BENTON ENGINEERING DRAWING NO. 4 CARLSBAD MUNICIPAL WATER DISTRICTX z ft. klhi iiia u.SAMPLENUMBERSUMMARY SHEET BORING NO. 2 A Relativepipv 62.5' Above 3A CORE RECOVERY COLOR v * 5 t H »* 1 £ 1 * 8 d Sj5 g Sfc uoK^« 8 u. C 3^ o-iMocZ DESCRIPTION 0£. 1AIU 10l£ 1 Z16 ISlo 2 26 28 <v»JU 32 None 15" Core None 2' -6" Core T-6" Core None 10" Core and Fragments GRAY BROWN GRAY BLUE BROWN DECOMPOSED GRANITE (VERY FIRM) GRANITE BOULDER(HARfiT DFCOMPOSED GRANITE (VERY FIRM) (Note: 1 O«inO ?nm« wnter at 32') PROJECT NO. C Kl ri M C C D 1 M r DRAWING NO.60-6-8AF BENTON ENGINEERING 5 ['•1866K CONTINUED ON DRAWING NO. 6 UJ I I Uz oaco X H »-0. HIU hi0 U. 1AJo opoo 40 .4142 >u*r*f ^*iO AR*|O r/-»DU 52 CA _j04 RADO «M»)O i Anou A.7OA ZJ64 AAOO 68 SAMPLENUMBERSUMMARY SHEET BORING NO.-2A El EV CONTINUED FROM DRAWING NO. 5 Frwnm»nt< 2* Core and Fragments None 26" Core and Fragments 34" Core and Fragments None Core Fragments 14" Core and Fragments 3'-4" Core (100% Recovery) 15" Core None 8" Core 3'-8" Core and Fragments 3'-6" Core and Fragments BROWN GRAY | H: \ ,. £ t <Kb. R t- — "• t» "^S ' s » 2 d ^<>«l !i «" 55;2 3 ° > « "»CS»- W^ K « I W_u. £ r O-I«K)C DECOMPOSED GRANITE (VERY HARD) GRANITE (HARD) DECOMPOSED GRANITE (VERY FIRM) PROJECT NO. QC-MTAM C M P 1 MET C D 1 MP DRAWING NO.60-6-8AF BENTON ENGINEERING 6 I'- 186ft8 CONTINUED ON DRAWING NO. 7 H »-a. ww wo u. -J^ < SUMMARY SHEET BORING NO._2A_ ELEV CONTINUED FROM DRAWING NO. 6 wIt £2 O -I «HSri •> at x 70 3'-651 Core and _ Fragments 72 74 GRAY_DECOMPOSED GRANITE (VERY FIRM) 76- 3' -10" Core and Fragments GRANITE (HARD) 80- GRAY BLUE UJ H- Note; Total water used between various depth is presented below: 700 gallons 73' to 80'No Loss O, y zD 5 C5 <03CO_Ja:< U PROJECT NO. 60-6-8AF BENTON ENGINEERING DRAWING NO. 7 (J cm.t— c/> a C£LU y z Q <ca U z A ||Jhi uo u. 2 ., 4 6- Q 10 1Q 20 OA 28 3?SAMPLENUMBERSUMMARY SHEET BORING "" 3A El EV CORE RECOVERY COLOR Non* 14" Core and Fragments 15" Core and Fragments 26" Core and Fragments 12" Core and Fragments 8" Core and Fragments 5" Co*"6 and Fragments JJGHI GRAY BROWN SIIt ? w Et g£s? it l! «!i2 s 3 ° >• •* ?Sgg*- S ->P K • X W ±u. C »^ a-JWK* DESCRIPTION DECOAAPOSED GRANITE (VERY FIRM) (Note: At 11' was first "plu.q" clayey cuttings. Enough clayey material to keep water muddy between 12' and 17'.) (Note: At 27' enough clayey material to keep water thickenec Used little water. Cutting from 27' to 44' clqyey fine to medium sand.) PROJECT NO. DRAWING NO.60-6-8AF BENTON ENGINEERING 8 P- 1866H CONTINUED ON DRAV/ING NO. 9 CARLSBAD MUNICIPAL WATER DISTRICTz JH0. hiM u0 U. 1AJ4 1A ooJo Af\4U A"> -4.C 44 /1X4O AO4o enOU CO3£ C£DO COD<5 ZAOU n /,oOx M 66 SAMPLENUMBERSUMMARY SHEET BORING NO. 3A Fi FV, CONT. FROM DRAWING NO. 8 5" Core and Fragments None 6" Core and Fragments 5" Core 17" Core and Fragments 20" Core and Fragments 20" Core and Fragments 26" Core and Fragments GRAY GRAY BLUE i H- 5 .. t £ *,£K u. ^H — • 0"^ | ^ £ » fi 3 Z0 «I |i «" :2"> K 3 ° > * "5ffS^ Q ^ c « x u±u. C^ OJ«AKX DECOMPOSED GRANITE (VERY FIRM) (Note: At 43' water became to thick with clay, therefore. water had to be changed.) (Note: Between 54 and 55 feet water thickening with clay.) GRANITE (HARD) PROJECT NO. DC-MTnM C M n MET CD 1 Mr DRAWING NO.60-6-8AF BENTON ENGINEERING 9 I'- 18668 CONTINUED ON DRAWING NO. 10 a. ww uo u. SUMMARY SHEET BORING NO.3A ELEV. CONTINUED FROM DRAWING NO. 9 g> Z i £ w a # fc £ O -I 68 70 72 " Core gtxJ Frogments GRAY BLUE GRANITE fHARDl 8" Core ond Fragments U "5.*-to Nofe: Tofal Wafer Used Between Various Depfhs: Oto44' 44' to 74' 200 gallons No loss a. 0 1 o U PROJECT NO. 60-6-8AF BENTON ENGINEERING DRAWING NO. 10 1'- 18668 D a; UJ I Uz Q eato U z K »-a. wM wo u. 0 4- A 10 SAMPLENUMBER" *. '. . .- • « t * •'.]-— 1 •31 1-»•""! :•.','• •.• • . T ." ' • V " " ;:R1 ' . * '. " *. * " . * • SUMMARY SHEET BORING NO. IB EI.FV, Brown, Slightly Molst^ Medium Firm Dark Brown Light Brown to Light Gray Brown Very Firm :INE SANDY CLAY FINE TO COARSE SAND (DECOMPOSED GRANITE)VE ENER6YKIPS/FT.S Hu. UlhitQ a t # i*15 >• «K «O -I SHEAR 1RESISTANCEKIPS /SO. FT.n BORING NO. 2Bu 2 •«"*•* *• i ••••;., * /* * . •".*r™™V" • ^[yT Brown to Dark Brown, MoUt, Medium Firm, 3% to 10% Granite Froflmcntsbark Srown, Moist, \ AnAflf IN** l*irrn f^rfiinlt'C* \ Fragments FINE TO SANDY CLAY fJffWPcf^RSE fo.c;.} BORING NO. 3B0 2 »•*•"•• ^r J-^i; . * • *T * .*».'»j'h' Light Brown to Yellow Brown, Slightly Moist,firm V/^il B_ Cl*—l il, Yellow Brown, Slightly \/Vbist, Very Firm FINE SANDY CLAV (DECOMPU5fcD GRANITE) FINE TO COARSE DECOMPOSED GR/NITE BORING NO. 48 o£. — | A • *JHM^k ^ £T> • * * >K-i ° '" •*— ~ r-77 . . , < T~. — "^ .^" 7~".~- ~ Lignr sea D'own, ^ngnriy Moisl-, Mec ium Firm Light Brown to Lfpht Gray Brown, Slightly Moist, Firm FINE SANDY CLAY CLAYEY FINE TO MEDIUM SAND MERGES TO A DECOMPOSED GRANITE P^!FN° BENTON ENGINEERING DRAWING NO. 11 O b.< =>(A Z SUMMARY SHEET BORING NO._J[§—« c § |3 S5 5£Light Brown, Slightly CLAYEY FINE TO Moist, Medium Firm COARSE SAND MERGES TOD jj, L 0 c,Reddish Brawn, Firm GRANITE ~j ;.- BORING NO. T- 1 £ " •*• * - - •'."'i'*.'* Dork Reddish Brown, Slightly Moist, Firm FINE SANDY CLAY MERGES TO ADECOMPOSED GR>MITF u LU I <!a. y Z ID a CQ BENTON ENGINEERING DRAWING NO. 12 I'- 18ft68 Q ct: UJ y 031/1 —4Ci < U X H0. hi 1 »-u111 0 SAMPLENUMBER,"*•' ' • * • •"»' tffy $T$ &?^ •.•.•,•;."•.••• Light < SUMMARY BORING NO SHEET 1C pray Brown, Dry, Very Firm DECOMPOSED .GRANJTJE.DRIVE ENERGYFT. KIPS /FT.27.3 36.9"FIELD MOISTURE% DRY WT.2 ouj Oa ^ O -1 SHEARRESISTANCEKIPS /SO. FT.0 i?>"-* /• • •/• .^ *QJ£ ^-/2wiFA^-/V :££& ,/y v;:. lightl BORING NO. 2C Dry, Very Firm SLIGHTLY SILTY FINE TO COARSE SAND (ALLUVIAL) DFPO MPO<\ F n GRANITE 4.0 41,0 79.2 .A "* 4 - 6 i 4*r • * . ** * •" • * ' .'• .':'*•• •':".'•''> • • "JL ^••» *• '^(2\\ :-\^_/:.; BORING NO. 3C Light Brown. Hrv. 1 twa* ijght Brown, Dry 1 tnUt f^ „__ . Ei fV— ,Ltyrir Vw/iu/ UIVTTII, \j\y , Very Firm Slightly Moist DECOMPOsFD GRANITE ALLUVIAL D.G. f\-9 O27.3 ^54. 6H 54.6 BORINfi NO AC •".V- •.'.•'••', •'•iTFl:^vJ ••i^S-- : JV" V; •': Light Gray Brown, Dry Slightly Moist, Very Firm DECOMPOSED GRANITE 50.6 54.6 PR°0EJ™F°'BENTON ENGINEERING DRAWING NO. 13 5X5 TO THE '/J INCH 359-6 trength Remolded So /-.^~ 5 X 5 TO THE Vt INCH 359-6 \Vc^ •- F i • •- r E L t L S -C-. '•' C O ' ' >•..,.-..=,. oso CA U.SBAO WATER EXSTiUGT I Shecfrr Strenjgth Rerpolded Soils Dam iite Ad acent;o Mt. IHinton Bqrinfi4B Average/ Bqg ompac loislxm Depfh I* ^ dens if) it 16. i percdnt ed dry rorate 110). 9 pourds per cubic: f&pt i rn -o-ir- a -S- I C =600 2n .-ii. % Stress" in Kip:per irerp fV^ 5 x s TO THE '/2 INCH 359-6 CARLSBAD WATER plSTRfilTO a >z rn Z •e-z mZ BojlngSB Average t Avjerage T l xxnpac Shear iSirength Remolded Sotls Dep ecf dry densir) cbrTreiit =14 6am Sire Adjacent to h4' - ' = 113.3 pourds per cubic percfenF Mt. Hmron Zmm~7O~ Zo <t>= 32 s S -n"a3 7g1 \\- Normil Stress in Ki w per !<^oare :«ot CARLSBAD MUNICIPAL WATER DISTRICT U. S. Standard Sieve Series 2DO 100 60 40 30 10 ^Boring 4B Depth l'-2'" B<pf|n i Depth Particle Siz$ in mm.; • PARTICLE-SIZE DISTRIBUTION Project No. 60-6-8AF BENTON ENGINEERING, INC. Drawing No. 17