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Home My WebLink AboutF Street Geotechnical Design Report - 2000r_" Mgers Biorlgnamics inc. I geotechnical md enviromental science and engineedng GEOTECHNICAL DESIGN REPORT F Street Im'Proaemcnts Proiect . Port TOwnsend' Washirygton I L E F ; F r iJ Prepared for:. SvR Design CoryrPanY- L008 Western Avenue, Suite 301 Seattle, Washing$on 98104 Prepared by:Myers Biodynamics, Inc' Rolling Bay Mercantile Building ]-L254 Sunrise Drive Bainbridgb Island, Washington 98110 December 15,2000 Project No. 00855-5 RSLLINGBAyMERCAN.TILEBUILDINS 1I114SUw'STSSORM BAINBRIDGSISLAND WA 98110 (206) 842-6073 @ ' I I I I I I I I I J :t t J U J J J J J FStreet00855-5 . December 15,2000 Table of Contents TABI.,E OF CONTEITTS \ SITE DESCRIPTION PROJECT DESCRIPTION.. SITE INVESTIGATION ' Roadway Surface Pavement Conditions Pavement Thickness l. Roadway Subsur-face Conditions Soil t ,2 .2 .2 .2 .3 .4 ,4 .4 .4 .4 .5 .7. .t .8 .g .9 .9 .10 '1.0.11 Groundwater. . . . . . Infiltr.ation Trench Are a'Sub surface' Cpnditions Soil Grouridwater bon INTTLTAATION CHARACTERISTICS AND RECOMMENDATI9NS. GEOTECHNI.CAL ROADWAY RECOMMENDATIONS.".. ....:.,..'" Site Preparation......... J... .l . Structural Fili. Site Soil Suit'ability for Reuse as Slructural Fill.. Pavement Consideration's . . : Rockely Qonsiderations i.......':........,'....:..:' Structural Retaining Walls RECOMMENDATIONS FOR ADDITiONEI SERVICE CLOSURE t,.FIG.URES: Figure 1 - Vicinity MaP . 11lgo"" 2-.1 - Site and Exploration Pian (Blaine Street to Matchline- Sta. 10+80) Figure 2,2: Site and Exploration Plan (Matchline Sta. 10+80 io 21+60) Figure 2.3 - Site and Exploration Plan (Matchiine Sia. 21+60 to 32+40) Figure 2.4 - Site and Exploration Plan (Matchline Sta. 32+40 to.43+20) FiSurc 2.5 - Site and Exploration Plan (Matchline Sta. 43+20 to Hastings Avenue) .Figur e 2.6 - Site'and Exploration Plan (Infiltration Trench Subbasin Areas'3 and 5) Ut*:"_ 1 -, General RockerY Detail APPENDICES: Apppntlix A - Fielcl. Exploration Fiogram Appendix B - Laboratory Testing ,l ..-.......1 Myers Biodynamics, Inc. I I 'l I J l J J J r-,IUlgers Biodgnamics inc. - geotechnical md environmental science md engineedng December 15,2000 Mr. Tom von Schrader, P.E. Mr. Jeff Lamoureux, P.E. SvR Design Company 1008 Western Avenue, Suite 301 Seattle, Washington 98104 Re Geotechnical Design Report F Street hnprovements Project Port Townsend, Washington Dear Mr. von Schrader: This 'report presents the results of our geotechnical investigations and design recommendations for the .proposed F Street Improvements Prbject in Port Townsend,Washington. The City of Port Townsend project involves roadway, pedestrian, andstormwater management improvements to the existihg F Street roadway alignment. Our scope of our work included project coordination, information review, site uiility check, observation of existing pavement conditions, subsulface explorations, laboratory testing, engineering analyses,' and preparation of this report. Our work was conducted in general accordance with our subconsultant agreement executed November 6, 2000. -SITE DESCRIPTTON The F Street Improvements project alignment incorporates approximately l mile of road.way oriented from east to west in Port Townserld, Washington. The F Street project extends from Blaine Street to Hastings Avenue on the east and west ends of the alignment, respectively. Thegeneral project location is shown on the Vicinity Map, Figure 1. The project site is an existing two-lane, asphalt roadway with occasional iidewalks and undergroun'd utiliti'es. Local topography gently drops from the east and west to a broad, north- south oriented valley crossing the project site just east of San Juan Avenue. The project alignment has a maximum elevation of 140 feet near the east end of F Street at Tyler, Street(Road Survey Station 2+00). The F Sheet alignment 'crosses the broad valley east of theinteisection with San Juan Avenue (approximate Station ib+00) with the lowest roadway.elevation at approximately 14 feet. West of Sair Juan Avende, the project alignment againincreases in elevation tg 90 feet at the west end of the project alignment (Station b1;00). Property topography adjacent to the roadway alignment is generaily within sevdral feet of theexisting roadway grade. Localiy, areas of greater roadway cut and fill have resulted in adjacent site grades of 5 to 7 feet above or below existing roadway grade. The Site andExpioration Plan, Figures 2.7 through 2.6, shows the general roadway alignment configuration and site topography.I I!i J ROLLING BAY MERCANTILE BUILDING 11254 SUNRISE DRiVE, BAINBRIDGE ISLAND WA 98110 (206)842-6073 @ ,l F l F Street 00855-5 December 15,2000 page.2 ofL1 PROJECT DESCRIPIION"t .I -1. i The proposed rpad.way improvements include localized road grade adjustments and ,urrrri*.ing of the exisiing tiaffic lanes. Roadway improvements will aiso include widening to accomm-odate bike ianes and sidewalks aiong the length of the alignment. Minor cut and fi1l of 2.ln 4 feet will be required along the alignment to accommodate the proposed podifications. At several locations, cuts of 6 tn 7 feet wiil be required for the proposed widening. Retaining walls qr rockeries wili be utili.zed to support proposed euts and fills. Stormwater collection and routing to stormwater infiltration trench areas are planned for the improvements project. T\po locations have been proposed for ttre infiltration areas. The first indltration area, ihentified as Subbasin Area 3, is located north of the roadway at approximate Station BZ+20. The infiltraticin trench is approximately 500 feet long as shown on Figure 2'6. The second infiItration area, identifipd 'as Subbasin Area 5, is located north of the F Street alignment at approximate Station 41+L5, east of the intersection rvith McNeil Street.' The Suf,basin Arca S infiltration trench is approximateiy 200 feet long, as shown in Figure 2.6. SITE II{VESTIGATION The project site was ilvestigated by conducting a reconnaissance of the existing roadway aiignmgnt to observe surface pavement conditiqns. We also copducted -a total of thirteen boi"ing'explorations, B-1 through B-13, arlvanced through the existlng roadrvay or within the propo-sed infiltration areas to investigate subsirrface. conditions. Borings 8-L through B-4, B-8, b-tZ, and B-18 were advanced within the roadway aiignrnent. BolinS-9 B-5 through B-7 agrd B- 9 through B-11'were advanced within proposed. infiltration Subbas.in Areas 3 and 5. Soil samples were obtained from the loring gxplorations and delivered to an anElytical iaboratory for further glassification and selective testing. Exploration logs for the individual borings and laboratory test results for selected samples are presented in Appendix A and Appendix B, respectively. Roadwav Surface Pavement Ciinditions Site surface paveinent conditions were observed and documented on NoYember _2, November 3, and Decernber 5, 2Q00. In general, pavement sirrface conditions observed indicated no significant pavement distress along the project roadway alignment. One localized pavement di-stress ur"u *u, observed and consisted of cracked pavement ("alligator cracking") ,in the outboard wheei path of the eastbouncl lane, just west of Albert Street (Station 8+50)' The approximate']ocition of observeci pavement'distress,is_'shown on Figure 2.1. Exposirres of the pavement eclge were observed along the margin of the roadrvay- alignment where shoulder soils were disturbed and eroded by traffic and stormwater runoff. Generall!, the pavement margins were intact at the time of our site observations and showed no sign- of significant distress or cracking Pavement Thicknesq At all of the roadway boring locations, explorations were advanced through tlre existing pavement surface. Asphalt pavement thicknesses and subgtade cond.itions for the boring locations are summarized irrTable 1. Pavement.thickness encountered within the borings varied. from 2-'j/2 inches tD 4-ll2 inches. Observation of the paverlent at the time of drilling indicated the asphalt is relatively weak and easi"Iy penelrhted. Observations_ also indicated that some pavement thictriuresses may be the result of successive layers and .build-up of asphalt emulsion/crushecl roch applications instead of the more typical nsphalt concrete pavement. .t .J ,l ./ J Myers Biodynamics, Inc. I I I I I I I :r I I J J J J J J J J J F Street 00855-5' December 15,2000 page 3ofI1 - TABI,E 1 --l -- -SUMMARY OF E)(ISTING PA\mI\{EI',{TAT BoRING LOCATIONS. F STREET IMPRO\ZEMET'ITS PROJECT F a * pavement may be compo.sbd .of sucbessive applications of asplalt emulsiop and crushed rcc\. Roadwav. Subsut'face Conditions 'Roadway subsurface conditions were explored by advqncing seven boringS, 8-L through B-4, B-8, B-1i, and.B-lb through the paveiriettt rtth" approiimatg locations shown 9n the Site and Exploratio)r Ptan (Figureq 2.1 through 2.5). \ ) Boring Errploratio.n Nuniber ApproxRoail SurpeyStbtion Approximdte'Boring Localion P4vement Section: AsphaltPavement UnderlYrqg Thiclmess * Mat€rial B-1 2+95 ' ,centeq of eastbound. Iane 2-1l2 ipches weah, easily penetrated No Base Material B:2 12+60 center of ea,stboind lane- 3-112 inches weak, easily penetrated" No Base Mciterio,l B-3 20+13 centbrline of .roaclway 4-114 inches weak,- easily penetrated' No Base Material B-4 27+8.9 , center of .' eastbound. lane 3 hrches' weah,' easily penetrated No Ba:st IVlaterial B-8 35+4 /.center of' eastbouttd lane 3 inches weak, easily penetrated' ' No Base Material B-12 42-F47 , center of westbgvnd lahe 4 inches weak, easily penetrated No Base Material B-73,48+13 cdnter'of westbound, Iane 3"1-/2 inches weak, easily penetrated -No Base Mq.teriaL Myers Biodynamics, Inc. L,J F Street 00855-5 December 15,2000 page 4 of11 Soil. Site soil composition observed in the roadway boring pxplorations and immediately below the pavement surface was typically granular. soils generally consisted of loose .to medium. dense, gravelly silty' ruird, g"u,r"ily sand, to silty sandy gravel. Some of the p.""-""t sobgraie goiis appearuu*oik"d and were interpreted as fill' A! -depth il tr: ,oudway borings, similar granular soil conditions. were generally present with occasional sandy ,ilt tuy"tu encountered at depth (borings B-1, B-8, and B-12). ' Groundwater. Groundwater was observed. within only one of the roadway borings, boring B-8, ut.; auptft of approxim ately 7 -Il2 feet below the existing sit'e grade. Boring B-8 was located i.n the.iow-lying portion of tire alignment" The elevation.of the groundwater in boring B.8 i| approximatJly consistent with the surface water elevation within lhe open,water.wetiand located south of the project alignment. Groqndwater'at this location,,as.well as elsewhere along the roadway aiignment,, *ltt tit uty vary with the season, precipitation events, and/or othei on-site ancl off-site influences' Subsurface eonditions along proposed infiltration lrench u,uui ' w"'e investigated by .onJuc6tig a total of six boring 6x$lorations. Borings B-5 tirrough B-7 were advanced across the proposed infiltration trench no*h of th" approximate rbadway Station 32+20 (Subbasin Area ii "'r .iio*n oti Figqre 2.6. ' Borings B-9 through B-1.1 were advanced across the proposed infiltration trench north of the approximate roadway Station 41+15 within Subbasin Area 5' Soil. Subsurface soil cond.itions' rvithin Subbasin Area 3 generall.y consisted of granular soils -ot gi"g from fine sapd to gravelly sancl to sandy gravel with varying r4inor silt content' Ho#"rr[", within two of the ihree borings, silt and ciay intelbeds or layers were observed. In the central boring, 8-6, two thin (1 to 2 inches thick) silt interbeds were observed near the base of the exploration. The north boring.(B-7) also encountered approximately 7-l/2 fdet of'sandy clay soii at4-Il2 to6foot depth. Based on the orientation,of laminations observed in the soil sample (40 degrees from hoiizontal), we inteipret this layer is a discontinuous piece of sandy ' "tuy^wiitrin tile overlying and underlying gravelty slightly silty-sand. ,Soils graded to sUgfrtiy sandy silt at dlpth in boring R-7. However, the soil in B-T.transitioned to clean sand at .Ure bottom of the boring. Due. to a lack of continuity between the silt and clay layers in the borings of Subbasin Atea.3, it-is likely that the ciay and silt layers encountered in the exploiations are discontinuous' Within. Subbasin Area 5, prnio*inantly granular soils were also observed. However, silt content within tfre soils *u, g"tr"tully greater than that observed in Subbasin Area 3' Soiis generally consisted of gravelly silty Band with some gravelly sa1d. .1nd. saldV gravel soils at iepthinbgring,;B-9andB-ff. Inallthree borings advanced in Subbasin Area 5, a sandy silt laler was enco-untered at a depth of b to 6-L/2 feet belorv the existing site grade. The silt layer was 1 to 1-I/2feet thick in borings B-9 and B-11 at the south and north ends 'of Subbasin Area 5, respectively. In boring B-fO (irithe center of thb infiltration area), the silt extended from 6foot depth to the bottom of bhe boring at 10 foot depth. Groundwater. No groundwater was observed in the borings in Subbasin Area 3 (borings. B-5, 8-6, d"d B.r). Ho*uuur, soil staining was observed in boring 8-6 below 7-U2 foot depth which likely is iqdicative of prior seasonal groundwater. The groundwater could be occurring as ',perihed" ground.watei on tnp of the silt interbeds encountered in boring 8-6' Perched grolndwater occurs where infiltrating water encounters a less permeable soii' and accu'mulales or rnounds on top of the less permeable soil. layer' !, Myers Biodynami.cs, fnc. -l l I F Street 00855-5 December 15, 2000 page I of1L ' A minor ground.water condition was also encountered in boring B-1_1,, in Subbasin Area 5' at a depth of ipproximat ely 6-l/2 feet below the existing site grade. Very moist to wet,' slightly gravelly *"dio. sani soil was noted just above'the bontact with a slightly sandy'.clayey .silt iuy"r. hhe wet soil conditions were also.interpreted. as perched groundwater at this location. lVtltu the other boring locations-in Subbasin Area 5 (borings B-9 and B-10) exhibited silt layers, no groundwatei'was observed during drilling. The absence of p'erched groundwater may be the result of discontinuous silt layers and/or the lack of significant precipitation "u"rrt, prior to the time of our explorations. We anticipate that groundw,ater conditions will ,rury uJros the proposed infiltralion areas depending on thp season) precipitati'6n, and other on-site and off-site environmental influencet. . Groundwater monitoring wells were irrstalled in boriirgs B'5 anci B-? in Subbasin Area 3 ancl in borings B-9 and g-1f in Subbasin Area 5. The wells were rneasured at the time 'of installation on November 2 and Novemier 3, 2000 and approximately one month after drilling on December 5, 2000. Measurements indicated dry condil,ions to the botbom of the wells at depths of 9-712 to 10 feet. SOIL INFILTRATION CHARACTERISTICS AND RECOMMENDATIONS The presence of silt layers within the primarily gganular soils across the two proposed infiltiation areas can create seasonal, perched groundwater conditions in the site soil profiles. During wet weather, surface water infiltrates relatively rapidly down through more permeable gru.rrrl"" soils.. When a silt layeg is encbunterecl, ternporary perched groundwater conditions can occur. Some of the perched gloundwater will move lalerally and where silt layers are discontinuous, infrltrate rapidly into acljacent granular soils' Soil mottling and staining can lre an indicator of seasonal, perched groundwater conditions. No significant soil staining or mottling was noted in the boring explorations conducted,in the infrltration arcjas, except lor soil stain--ing encountered in borihg 8-6 in the central portion of Subbasin Area 3' The.soil.textural classifiaation .typically utilized for evaluation of soil infiltrdtion capacities is the United States Department'of Agriculture (USDA) textural classification. ' The USDA textural classificatiott. ior the majority of granular site soils is a gravelly sand and sandy gravel, sand., loamy sand, and sandy loam. The silt layers generally classify as a silt loani. i6e siie granular soil classifications were correlated with infrltration rates presented irr the Washinglon State Depaltment.of Ecoigrgy (WSDOE) Draft Stormwater Management Manual for Western Washingtol. The WSDOE infiltration rates. for stormwater infiltration systems i"ai.ul" u "urgu of f d io 0.25 inphes per hour for the gtut,!lat site soils as shown in Table 2. The presence of silt layers, the variability of soil t;pes, ancl itu,lies of soil infiltration rates indicate a potential for large variation in actual infiltration trtincir capacities. Fbr design pu{poses, we recommend. the lowest (WSDOE) granular soil infiltration rate for the encountered soils be utilized for each of the tpo Subbasin Areas. A value of 1'B ilches per hour is recommenclecl for estimating infiltration capacity in Subbasin Area 3. In this proposed infiltration area, borilgs encountered sand arid gravel soils (10 inches/hour) and fine sand (1;8-inches/hour). Whiie hvo of the three borings showed silt or clay layers, the! appeared discontinuous./ In Subbasin Area 5, a rate of 0.25 inches/hour is recomntended to reflect the,lowest infiltration capacity associated with the granular soils encountered in the area. Soils ranged from slightly gravelly silty sand (USDA plassification: sandy loam) to gravelly silty fine sand (sandy loarn) to slightly silty gravely sand (gravelly sand) with correlated inJiitiaticjn rates ranging from 0.25 to 0.6 to 10 inches per hour, respectively.' Due to.the pr"esence of a continuous 1 I tI -t 'l I-) I '.J Myers Biodynamics, Inc. I l F Street 00855-5 DecemPer 15,2000 page 6 of11I l I ,J' siltlayerbeginning at 5 to 6-1/2feet, below the existing site grade, the overlying soil should be assessed fo1 stormwater storage capacity or additional design msasures should be implemented to avoid overwhelming the infiltration .trench capacity. To avoid'introduced stormwater perching on top of the silt layer, we recommend that.penetrations bb rhade through the bottom of tn" infiitration trench and underlying the silt layer to allow vertical migration of infiltrating stormwater a ininimum of l.foot below the silt layer within Subbasin Area 5.. The bottom of the silt. layer was approximat6ly 6 feet below the existing site grade in boring B-9, 8 feet below the existing site grade in B-l-1, and greater than 1,0 feet telow the existing siie grade in boring B:10. Such penetrations couid be constructed 'as sand drains consisting of arr augered hole extending ihrough the silt layer and backfilled wlth clean, free-draining sand. At-the center of the in{iltration basin in boring B-1-0, the bottom of tlre sil! layer was not penetrated. Provisions should bp made within the contract documents or further lnvestigations should be conducted before consiruction lvork to determine the depth required to penetrate the siit layer in'the central portion of the infiltration trehch of Subbasin Area 5. TAEI,E 2 INFII,TRATION ITATES BASED-ON USDA SOIL TrEXTU'RAL CI,A'SS, F STREET IMPROVEMEI{TS PROJECT Infiltrhtion Ratez'a GerotechnicalReport Textural blass (USDA)r incheultoui: SoiIDescripti"4{- Sandy Gravel and Gravclly Sand : Sand Firie Sand Loamy Sand Sandy Loam 10 Sandy Gravel aird Gravelly Saircl Sand Fine Sand , Silty to Slightly Silty Sand : Silty to Very Silty Sand I -i l J 4 1.8 0.6 0.25 - _.t r United States Departrneht of Agr-iculture soil texpural classificaLion system. 2 Infiltration values based on the Washington State Deparbmelt of Ecology (V/SDOE) "Draft Stormwatbr Management Manual for Western Washington". ' 3 Geotechnicai'errgineering soil classification used in this report. See boring logs and Key ' to Soii Explorations Logs in Appendix A. { IrIo correciion or safety factor ailplie$ to plesented values. i Due to the variai:le infiltration rates cf site scils and presence of silt layers, \ re recorRmend the ,lowest infiltration rate associabecl wibh the granular soils 'encountered at each proposed infiltration.area. If necessary to avoid b*ceeding trench capacity, penetration of the apparent continuous silt layer in Subbasin Area 5 shouid also be incorporated into the project design' Fieicl,infiltration testing could be considered for'site-specific infiltration irrformatiorr in the proposed trench areas io provide additional site information for use in selecting'desigii infiltration values. As previously described, further investigation of the center cf Subbasin Area 5 should be performe<lbefore construction activities commence i,o detelmine Che probable depth requirecl to penetrate llrc silt iayer. Alternatively,'unit costb,should be presented in the bid documents for-sand drain instaiiation to,allow for potentially variatile sand drain depths' I Myers Biodynamics, hrc. -1 I F Street 00855-5 December 15,2000 page 7 of11 ,f As recommend.ed in the WSDOE Draft Stormwater Management, Manual,' a suitable safety factor should be incorporated into the design to account fcir eventual ciogging; siltation, or other factors effectlng the stormwater trench p6rformance. Construction iequirements to preverit - sedimentation ir t6" facility until vegetation is established should also be incorporated into the . project plans and construction sc'hedule. Folloying construction, we r',ecommend that infiltration swales be periodically- monitq.ld .Q;;-. ttiu i"nttration capacity under field performance conditions. This should include , monitoring of both the gr;ndwater levels anld swale surface water dissipiation rades (if any surface water is presenl; during and following peak storm events. It ryhy be possible to retain the existing *oniti.itrg well-locdtio_1s in the swale aiignmQnt for reuse'as 'long'-term . groundwrtu" *ooitoririg locations. If reuse of the wells is desired., they- should be glearly i;;in"J i" the field prior to bonstruction. Protection of the wells should also be ciearly indicated in the contraci documents. New monuments and PVC riser pipes-may berequired to facilithte future rnonitoring. Altern'atively, the wells should be properly abandoned by a licensed'well driller prior to commencement of site earthwork activities ancl ,new monitoring well locationq instalfud in..accordance with WSDOE standards. ' ,l I l IIj' GEOTECHMCAL ROADWAY RECOMMENDATIONS Site Preparation Geotechnical engineering recbmmenclations for the proposed roadwa-y contained in this report are based on the proposJcl.roadway improvement t'ians and traffic inforrnation provided to our office and the subsuJace conditioni o6served during our field investigations. If project plans ;h;;;;; . rigift""t period of time passes prior ta construction, we shoirlcl be cdntacted and retained. to de,termin" th" oppropriateness of the recommendations presented in this report' The following recommendalionJ are presentg'd fqr site preparation, structural fi1l, site soil 'suitability for reuse as structural fiil, and pavement consideratibns for the proposed F Street hnprovements Project J J Roadway improvements will include grade changes along portions of the existing alignment and :wijeni.g to accommodate bicycle lanes and sidewalks. The existing alignment widening will require cut and fill sections up to 7'f'eet in height. For site subgrade soil pr"pur.tiorr, *,e "".om*end removal of existing pavement and other structures in the proposed widlning or road.way -grading areas prior to excavation to the qew proposed subgrade elevatioi. Whbie "oud*"y gru.lu changes wiil 'not occur, existing pavement tiray remain for pavement overlay or be removed for a new pavement section (reference Pauement bonsi4erapiohs). If organic soils or soft/Wet silt or ciay soils are exposed at the subgrade elevation, ihey slrolld be removed and replaced by structural fill. Ali subgrade soils should be compacted to a firm,'non-yielding condition br removed and replaced by structurai fill prior to pavgment section installation. After excavation to the proposed pavement section subgrade . elevation, we recommend proof- rolling the exposecl uolgruA" soil surface with a fully loaded, l-O-yard dump truck or other similar heavy construction equipment. Aieas of soft, loose, or yielding soil should be compacted to a firm, non.yielding condi(ion. If compaction of the subgrade soils does not turoit in a firrn condition,-tlre soiis should be moisture conditioned and recompact-ed -or the soils should be removed. and'replaced with structural fill. Firm, non-yielding subgrade.soil sudaces should be protected from clisturbance prior to pavement section construction' I I */ l I "t 1 :*J l Myers Biodynamics, Inc. F Street 00855-5 December 15,2000 phge 8 of11 I : Some of the site soiis contain a sufficient percentage of fines (soii particles passing the U'S' No. 200 sieve) to be susceptible to disturbance by site construction traffic when wdtted. If .onrtr".tion occurs durini Wet weather, care. should be taken to protect the subgrade soil surface from pondirrg .rr.iu." water. Additionally, construction traffic should be avoided if the soil surface becomes wetted' Structural Fill We recommend fiil placed within the roadway improvements area be placed as structural fill. Structural fill shouid consist of a well-graded, granular soii m'aterial and be at a moisture content to bllow for proper conr,pdction. Structura! fili should be placed in 10 to 12-inc! lqose lift thicknesses. Structuril fiil shoutd be limitecl ,to 6 to 8-inch, loose lifts rvheire hand operated equipme4t is used for compaction. Each lift shouLd be com,pacted to at least 95 percent of the ,nu*i-,r. dry density as defined by ASTM D-1557 (Modi{ierl Pioctor). For fill greatei than 2 feet below the pavement section subgrade elevation, we recommend compaction to at ieast 92 percent of the maximum dry density (ASTM D-1557). lI If constructic,n and frll placement occur during wet weather conditioni or if fill is placed on wet subgrade soil conditions, we recommend that structural fili material consist of an importeJ, well-gracled sand, and gravel with less than 5 percent fines. Such a material could consist of "Gravel Borrow" as presentecl in Section 9-03.14(1) of the Washington State . Department of Transportation (WSDOT) Standard Specilications for Road, Bridge, and Municipal Construction (Standard Specifications). Howevet, the gradaticin shouid be moilifred so that a maximum 5 percent by weight of the material passei; thg U.S- No. 200 sieve as based on the tnirrus 3/4-inch fraction. Site Soil Suitabiliiy for Reuse as Structural Fill The suitability of excavated site soils for reu-se as simctural fiil depends on the gradation and moi(ture contlnt of the soil when it is piacdd. As the arnount of fines isoil palticles passing the U.S. No. 200 sieve) increases, the soil becomes more sensitive to small changes in mQisture content and compaction levels become more difficult bo achievb. Soiis conbaining greater than bpercent fines are moisture sensitive and cannot bo consistently cornpacted to a,firm,.non- yietaing condition when the water content varies by more than 2 to 3 percent of ihe optimum moisture content. The opLimum moisture cpntent is that moisture conterit which results in tlie greatest soil compacteci dry depsity for a given compactiol effort' The existing site soils observed, in the road.way boring expiorations were generally granular, consisting of titty to slightly siLty gravelly sand, sandt or sand ancl gravel' Based on laboratory testing. firres content ranges frorn' approximately 4 tn 24 percent in lhupledominaltiy g-rarrular soils. The laboratory tests indicate a porti.on of the site granular soils are'*oi*irri" sensitive (greater thair 5 percent fines) and strould he utilized as structural fill only during periods of extended clry,we?rther when the moisture coni,ent_can be controlled ancl whbre placecl on a relatively firm, dly subgrade. Silt and clay interbeds encountered in the exploraiions, if errco1rntered at subgrade elevatioh, are, not suitable fbr leuse'as structural fili during periods,of wet weather Depending on the tinie of construction, excavated site soils may be, above or below the optimum moisture content. During the boring explolations, site soil sarnples lvere observed to be generally in a rngisi condition which is typically suitable for compaction. However, Iepending on the soil moiEture condition during construction; site scils'rnay require moisture rooditiotring plior to.or cluring placement as structural fill. This couid j.nclucle ad'ding_water to soils below the optimuin *oirt,r." condition (in a dry conditioh) or spreading and drying I lI I Myers tsiocly'namics, Inc. ,.1 I l F Street 00855-5 December 15,2000 page 9of11 :l i soils which are above the optimum moisture conciition (in a wet condition). If wet weather construction is anticipated or is required to meet the project constluction schedule, we recommend structural fill consist of an imported well-gradecl sand and gravel w'ith less than 5 percent fines, as previously recommended' Pavement C gnsiclerations Recomlndndations fo( pavement design were developed bgsed-on estimated soil subgrade CBR values of 20to30. These values wersselected based on the results of published correlations of subgrade poil types and CBR values, The subgrade soil CBR values assume site soil subgrade preparation and structural fill recommendations occur as previously presented. Based on thb traffic information provided to our office and a design assumption of no signifrcant heavy truck traffic (except occasional fire and trash collection vehicles) and CBR ,ru1o"r, a pavemerlt section of 3 inches of asphait concrete pavernent over 4 inches of' crushed surfacing-is recommended for new roadway pavement.section areas. Asphalt concrete paveinent should conform io WSDOT Standard Specification Section 9-03.8, "Aggregate for. ,{sphalt Ooncrete" (Glass B). Crushed surficing ,shoulcl conform to Section 9-03.9(3) for "Crushed Surfacing" (Base Course or Top Course). Crushed surfacing should be compacted to a firm, non-yieldirrg condition prior to placement of asphait paveiment. -'l j l -l J I .J ,1 :rl Where existing,pavem.ent areas will not'be subject to grade alterations, we recommend an asphait concretJ pavement overlay of 2-inches on top of the existing pavement surface. W e have assumed the existing weak asphalt surfacing will provide similar perfor:mance to an asphalt treateci base. Prior to overlay, we recommend any areas of observed pavement distress be:repaired. by excavation and replacement with a full depth of asphalt concrete patch or the pavemdnt section as previously recomntended, At the time pf our site observatipns, the only area of observed pavement distress was at approximate Station 8+50 as shown on Figure 2.1. ' Rockerv Consideration s Dug to the granular nature of existipg soils in the area, we anticipate that rockeries could be utilized foi the majority of cuts and fills "proposed along the project alignment- Because rockeries a1e hot structural retaining walls, we recomlnend no rockeries be utilized where an existing structure\is located within a 1H:1V (1 horizontal to l vertical) projection up from the base of the back side of thq wall.' Where existing structures are present within a lH:1V projection from the back side of the wall, we recdmmend a structural retaining wail be utilized as recommended below. Where rockeries are utilized, we recommend the base of the rockery be founded within medium dense or denser, native granular soils. We also recommend that if subgrade soils are disturbed during rockery construction, or ifloose or sofi soils are encountered, they shoiild be removed to expose medium dense or d.enser native site soils. Alternatively, the unsuitable soils could be removed and replacdd by structurai fill. Important considerations in rockery construction include the following: 1) th,e rockery' must have a firm foundation; 2) the rocks must be sound ahd have a minimum lvidtll of 18 to 36 inches with larger rocks placed at the base; 3) the maximum slcpe of the rockery should not exceed 1H:6V; 4) a filter material should be placed behind tlre rockcry to prevent the loss of material from between the rocks; 5) drainage material should be placecl behincl the rockery to prevent build-up ofhydtostatic, pressuies; and 6) the backfilt behjnd the rockery should be well-compqcted to ieduce potential settlement' -j l ,-/ *-/ Myers BiodynamicS, Inc. F Street 00855-5 December 15,200b page 10of11l l A rockery detail shown on Figure 3 presents a typical design wit\ w'all height and minimum rock dimensions. Slopes behind the rockeries should be cpt at least 18-inch'es and backfilied by WSDOT Standarci ^Specification 9-13.7(2), "Backfili for Rock Wall" to provide adequate drainage behind the ro&eries. A suitable filter fabric shouid be placed behlreen the rock and the natural site soils. The backfill could be capped at the gtound surface with a minimum -of 1 i;;;;;"p*iifol r"t*g"tation. We recommutrd thut perforated or slottecl drain pip-e be instalied at the base of the ro.kury backfiIl. The pipe should be a minimum of 4 inches in diameter, or as r"q"ltaj and hydraulicaily sized by the projeeircivil engineer. Specified drain pipe material 'should be ofsufficient strength to support backlill overburden pressures' i j 1 i l l I -J ,' Lateral pressures for structural retaining walis backfrlleci on one side will depend on the amgunt of lateral movement permitted a! the top of the wali during backfrlling operations. W e recommend brrbgrade walls which are free to yield at least 0.001 times the height of the wall during backfiilirlg (active conditions) be designed based on an equivalent fluid density of 35 pound"s per cubic ioot (pcg. Walls which are structurally restrained against yielding during fackfilling (at-rest conclitions) should be designed for an equivalent fluid density of 55 pcf. To account for lateral loacling associated with a structure located within a IH:IV projection up from the base of the wall, we recommend applying a factor of 0.3 to the vertical load and appiying the results uniformly aiong the backside of the wall. To aocount'for traffic loading, - we recommelcl an equivalent 2 foot soil height be'assumecl behind the wali. -The recommended values'assume a horizontal backfill with no build-up of hydr:ostatic forces behind the wall' Subglacle walls shoukl be backfilled in accorclance with the recommenrlations presented in th9 Strictural ltill section of this report. We recommend that only 1i6;ht-rveight, hand operated compaction eqlipment be aliowecl to operate within 2tD 3 feet of subgrade rvalls' 'Drainage shoritd be provijed behind the walls to prevent tlre build-up of hyclrostatic pressure. . W e recommeld footing drains consist of d perforated PVC pipe surrounded by 6 inches of drail gravei. The pipe lnd drain gravel should be surrounclecl by filter firbric with a l2-inch irini*u* ouurlup. Waiis sftouta be backfilled with clean, free-draining- sand and gravel placed within 18 inches,of the wall. We recornmenci-fre.e,draining-:lT-f and gravel conform to WSOOT Standarci Specitication 9-A3.!2(?) "Gravel Backfill for Walls". Alternati-vely, a synthetic geocomposilq ctrainage rnaterial could be utilized behind the vralis. Wail drhinage .j,aterial siould connect |ydraulica[y to the drain gravel surrounding footing drain pipes. Lateral load,s may be resisted by a combination of fr:iction qlong the base of ftlunclations- and by passive soil resistance. We recommend wali foundations on granular structural fiil or site soils be designecl using a coefficient of base friction qf 0.4. Passive soil resistance ilray be calculated based on trn equivalent fluid density of 220 pcf. The passivc value inclucles a factor . of safety of 2,0 to iimit deformation required to- fuliy mobilize passivs resistance. The passive resistalce value assurhes a horizontai grounci ,lrrft." beyond the footing' We recotnmen8. ignoring passive resistance for the upper 12 inches of soil unless coverecl by pavement. I RECOIUI/ryNDATIONS FOR ADQITIONAL SERVICE We r:ecommencl th)t our firm be retained to review those por.'tions of the plans and specificatiols that perbain to site subgrade preparation, earthrvork, and pavement section to determine whether they are consisbent with the recommendations presented in thLis report. W e also recommend that a representative'from our firm provide rnonitoring and consultation during construction to confirm that the conditions encounterecl are 'consistent rn'ith tliose indicaied by our expioratibns ancl to provide expedient recommenclatioirs should conditions be .) Myenp Biodynamics, Inc. I I -t I ,l I F Street 00855-5 December 15,2000 page 1L of11 revealed. during construction which"differ from,those anticipated. Specifically,. these should i;.I";;,t at a mlnimum: 1) subgrade soil proof-rolling; 2) soil compaction and earthwork; and 3) other geotechnical project issues. CITOSURE This report was prepared for the exclusive use of SvR Design Company and other project design tbam members for- specific application to the proposed F Street Improvements project as described he/ein. ttre data and report should be provided to prospective,dontractors'for their information but the report, conclusions, and interpretations should not be construed as a warranty of subsurface conditions. Within the limitations of scope, schedule, and budget this report was prepared in accordance ;lli ;;""rally accepted geotechnical_ engineering principles and practices in the area at the time this report *u.'p"upLed. No other warranty, either express or implied, is made' The conclusions-and recornrnendations are based on" our understanding of the project as described in this report and on-site conditions as obsi:rved at the time of our explorations' If project plans change from those described in this report, we should tre contacted and retained to review the changei- iorrditionr. We should.also be contacted and retained to review our ;;;; tf' rl irr";" ri . substantial lapse of time bet#een submission of this report and the start of construction; 2)-conditions have changed due to natursl causes or construction operations at the site; or.d) conditions appear different from thqse described in our report. The purpose of the review is to determine'the 4pplicability of the concluFions and recomrnendations considering the time lapse and/ot ctrangea conciitions. ,-^-+,,ni+i' {^ ^-^.,idA rrmr rxri*h opntrrchnie tiCeS fOf thg FWe appreciate the opportunity to provid6 you with geotechnical englneering ser\ Streeiimprouu*urrtr-project. Please contact our office at your convenience should you have urry qo"rliorrs o. tuqoite additional services. Sincerely 'Yours, MYERS BIODYNAMICS, INC N. Myers, P.E Principal Geotechnicai'Engineer JNM/saf Attachments J J Ii-i ! .,1 n I-J 1 J J Myers Biodynamics, Inc. -l I J I I I J -.J -l \J -l I \\ ti J PROJTCT LIMITS H/AVENUE I \ t4J3z,Ld 1 GOLF COURSE 1 I2TH Note: Not to Scale Vicinity Map based on "F Street/San Juan Avenue, CiU of Port Townsend, Preliminary 30% PS&E Submiftal", Sheet No. C0.1, SvR Design Company, 09/25/00. Mgers Biodgnamics inc. lsldd, Washlnglon 98110r",TELr Flolt 2061812-3797 VICINITY MAP F Street lmprovements Proiect Bainbridge lsland, Washington FIGURE NO I PROJECT NO 00855-5 DATEDecember 2000 ""\ I# lJl iAx ji:i t i61Js *et4t w*F,€isii * iz w$t tFie'lg ij.1,lx tlgi LLt&*19,E t!'#.ufri &t.v, 5 /II/ // ^U/ r-F' 1F:/ x gfi4.x,* &*ta # & t*4 l0l J g{t 13we,I 6*at$ rrtf; t2&9.w33 ",iililttfl ffi6r*#i WiE /L',LAi t irx 1l E4;L1 r.fld#,F1ti g#. t6!&a9,.ttuj- +t.* WItl ?, Filfie€ lJl;+l *tkl tr:#HX gl 1S-rt *lt of Port Townsend, 1 and C|.2, SvRNote:Site Plan based on "F Street/San Juan Avenue, Preliminarv 30% PS&E Submittal", Sheet No. D es i g n Colm p a ny, 09/25/00. City C1 I j j -) .J FIGURE 00855-5 2000DATEDecember SITE AND EXPLORATION PLAN (BLAINE STREET TO MATCHLINE STA 10+80) GEOTECHNICAL DESIGN REPORT F Street lmProvements Proiect Port Townsend, Washingtonr"" Mgers Biodgnamics inc. Rolllng Bdy M€rcantlls Bulldlng' 11254 Suntlso DrivE Balnbrldge lsland, washlnglon 9811 0 TEL: 206/842-6073 Fl\t<t 2061s42-37s7 f'l :r II _i : I,'l l I I l L,J ) s t reet ilL i2 t$l^7 1& IA\ J5.: ,'lt:t l1 i\ ]a lli a'/ai PB,qtL ?t&j+ '-{ :,i€ {-- 1.-.t7",{o6t+(o (D sa{#J &f*t:t E|MSu!- v"re/?\"d L*tgib. '4 *[ lA tfill Mi\W\lS*"*'** UJz o o€+o Ur' $tr ad t: .iD ?r S*ec tj&ps' * ,,?.J ItT l;ffi E--'ai:j-, --st '.1 t I I I I J I II 1' I Ir I t I j -r.4J ":. ty"rYt&ii i ":.r'$!t tz tg"*li.ii i Ltt 3 '!:i ti-*. F firiLav,t E.Ia/i'\ 't"'dlJ|zi I5 otCI' 1I )i iti' t a? $l E Jcnlr $I#r {, *gt tz 1 It .u:€t t i ! I I 1€i wM1 t, t*1|L1 ?#Xfi 3 s: l:X tr,1 "bit*tn 91 I fi{#fr. v-v.e'$t€la,'i\-; ItIwJ*tx dea a 4Ft&?afli4}rl (\t oC\t+G' o IIJ =ol*- '6 iut#tttt!Ef:t-:€Tl 4 1i*)z tl ax*l lWA ffiV:* 's t{-4),9 3twa,& .l--:..ffi#L1 ;f 8id&rF,r* i ; -,1o e*1,&rv 4:,*.{gMF*g?6 i{yorq g :wfi % rnet #.t4,t .? a*rE L\u !n€ LEGEND: a B-1 Boring Exploration Location Approximate Scale: 1 inch = 50 feet 02550 Note: Site Plan based on "F Street/San Juan Avenue, Preliminary 30% PS&E Submittal", Sheet No. Desi g n Co mpany, 09/25/00. City of Port Townsend, Cl.3 and Cl.4, SvRF Street road centerline suruey position 5+00 (500 feet from Blaine Street/F Street intersection) B-3 .i *J MgersBiodgnamlcs inc. Bolllng Bay M€rcsntlle Bulldlng' 11254 Sunrlss orlvo Bainbrldge l6land, Washlnglon 981t0 TEL: 206/842-6073 FAx'. 2OGl812-3797r""GEOTECHNICAL DESIGN REPORT F Street lmprovements Proiect Port Townsend, Washington SITE AND EXPLORATION PLAN (MATCHLINE STA 10+80 TO 21+60) FIGURE NO 2.2 PROJECT NO 00855-5 DATEDecember 2000 --)i-IS:"* *.*1*_ -. _ _-_.Cherry Streetr l]1'"i+,ii.\{i- - -{:ir '- : .-Street'r "'1.IIIdi'>:r,i,rrj FijlsnIr:eRoseI'\27+OOqs*$p{)N,Jl1s*frge$!$STA\--..r21+60i,"TCHLINEMATCHLINE STA$$i-L:Ft l-rf;MA''$HfrSF#{"b)a"fifii{"t.*$iiiRose{\ltsCherrYStreetrl$Itr{51;{.e.*--,- - r*_sITl*L+\=s$u)!ib.oo5es\o(D+Nqeg,Guo* t$:$.***fi*;: * .****!igfi!IStreeture{:f*fr s*Fets aHs:+ Fd,\ig/\*{dtxt$ irtn}sffi*sshItl/s*s$s$ldHt*It,ISTA 32+40ss *il*NEi gr".t\d *MATCHLINE+l1"rji{;{"*"-iH,{Ffis^$ls,ti s'frcl#fs'\f,"elag1$.isxrfto$s€tlL!,);{'i/,$i{\*'sEs1i;T"fi4:P;'&RFil!h4i.t-maomtrzlobo=.Qrnxtioilor*ooA)oLt-rts'doxlrIoo$PAIooluOtqoeo(DQ$r)Edd-c'S p* =.4)$!D !sasE Hg:s o\ootf,so CD*Nfr98e$s$=f,\s's)q6=}L(D<o(d3Fo9q\otq3"!o-f,!d''-9S(,)CDQi.gGT'8gSEsdsB.;8N]\'o6+Qddpo\-\Sa;$E+=l=.oQotui+oaooo(noo[""-(')oosf($STA 27+00TCHLINEMAIctmzoNt,ooo(tlgIt('loooo3croNooo^,4==D: ni-to>-7tof,*-tu35+trt'>o-td-2Su*r-Bbaom_o- llJo"qFi== o-lo +o*7<==5l (,oH>EOF-od s<J mFE qO.+A,Jo v,-=a19d l9b'm- 9.!"aL.,I{#Fggtr=EEg HE;:qts 6*gE dlg@-d r;9 i ii6l rrt6n ns;O3. lrql:n IIrr{R*,{$I /e*,9'Qn'+{"d,$fts{"#N6'*tsHMATCHLINE STA 37+80ftt,|32+4OiIjl\Iilq'$II$MAII*sa1,1ii*$",}.Dfr\.,f't':l'r"'hbL+\=.ES(rt !i(,)0o:es\ol'seg,erbA)oMcMeiit"Street$2.5)t"HXEUi\ic**frFigure4EXFfri4Il,i{"flE$t{Es43+2O{""STA$*r*sFfi]}H4sAilsfrI".tr q4.'*;u. $$"ii/*i,'lt$dfh)rmootr2iOoo+.arnx\toqio|-ooq)o!!-r!s'doxli.' da(DHSsrool\)(Jleooa$r)Edde=S. p- =.q)$$ rsesE Hg:s o\oot5!ocD+U-fr sSpH=t!5S='5Es's)91 f,}Lo<oo3Fo9q\rQ3"ra.iQarbs(riCDQi'sGTI8gBE=ciSRila$=i5'Oo*Qddpo\sstri=.oQo'vi+oooaoooBIatrINca\oo${{iI"{t't"I$IIi$9lt,dJWlku,EEEEE*98 d,l@-d r;9 i I@-* IS6l rle=G n3;OLrrq!:lroaom_oSEil=d I-{o +or+7i==gEx=Y.-od sFdu(,r'* Jo 9,=A19d ro.a'm"sEu{^,4S-rlrri-|o>-7r_ofrv9Gx5NtrE>o-ld2AcD!+I-Bbz!oc!mzoNlbTlnlolmlot=too@grgrI('r0oio"'ooJctoNooo -t 1 -t l d"n *JttAzff a+*f]t ri:: a &+s tf#e;'it lfrtb. !2;\1 tz t*48 tr.wrfr.,t !!*1s;t VJIL )! | h h 4 *'*]4i. ,tir# tj :L 6j{Et- #ra\\ ,trir.r./,;\ 'j. '' !i \{ I 1 q j I fj *t::aft W 3t l'.l$lit *t111\;_, 4Ig5gtaf- wws#{eGr il/7 '1',J. e;t4 n .i, 1. tl4l"rf,ru{?a I i ,,", & I e1t$l S t? *;tr #gtEl"\.eeVVttltrAtH'_4/">\ = ortrzma F@+oo '=::/::r:Ek m -4. zo =! Approximate Scale: 1 inch = 50 feet 0 25 c{s{ * LEGEND: a B-1 Boring ExPloration Location F Street road centerline survey position 5+00 (500 feet from Blaine Street/F Street intersection) Note:Site Ptan based on "F Street/San Juan Avenue, City of Port Townsend, Pretiminary 30% PS&E Submittal", Sheet No. Cl.9 and C|.10, SvR Design Company, 09/25/00. Street 1 I.,' Mgers Biodgnamics inc. Rolling Bay M6roanlile Euliding '11254 Suntis€ Drivo Balnbridge lsland, Washlnglon s8t10 7 Et 2061A42-6073 F Ax'. 2OG lg42-97 97r""GEOTECHNICAL DESIGN REPORT F Street lmprovements Proiect Port Townsend, Washington SITE AND EXPLORATION PLAN (MATCHLINE STA 43+20 TO HASTINGS AVENUE) FIGURE NO 2.5 PFIOJECT NO 00855-5 DATEDecember 2000 IIfttIt-rTloomtrzisE{ts'doxlisooss+s)oGIF89 =s$Rl0{sH_ 5rn oibai +.sd :os bQdR$c q..r.,\dg;$E+ =f.=.oQo'(ri +ooooooN(}t()taeooc)-D cD3dd-d 5'rQ =.Ns{*a'< a)(o.-oNHR^\o\o9\"_(/) iHpEE\cr9cD3q)$S- ro)Qx$E*EZJDeeoqlo:"]cnf,i;rasO(')(')o(oXiIIEIai:l]; i.lqiWxgtttrIIJsI,ooIzl!t--l!=12!-{1tOmxz=o=-1Anic(/)qJtl,iaozz>str+m1,>or (,rq$JstrIa)I.iIIIitI!laaJIs1IitItizIt-{TIr9!{Tf,Omxz=o=--anicagJtl,1@ozz>otrNMilr>o(r)EIrs.{:\&'I\\iIIttI{\T!{I!:tiiiII't!xtti1ttI,\\ti\I1It\i1iiI\\ItI\\tittd,t"\!iIIlll iit 51rii illIt tl* lfsacto19ooo=zIr+*s-lJo lll=>1-f,o6s.r!U'/-gow-ra==o9rZ#PA'Ecilzg('lom_oSqil=d I-{o +9=z=3-gEE=Yr-od oFdu96a3419d r9b'm- sEI{lkEdgqE=EEE f,ET.:5E O*98 dPO-A I69 - de-i9 Js@, rl{=il nq;O'= rril:n -l I "t 1 IJ I II 'l .J l J !, . , J / I i 18" min max. backslope grade 1'min. Topsoil or granular soil Provide erosion control until revegetated.1 2 1 Existing firm, native soils 6 Filter fabric H Excavation cut slope as required for stability during construction, if fill - overbuild using structural fill and excavate back for rockery construction. finished grade Drainage material, Backfillfor Rock Wall Stand ard Specifi cati o ns 9- I 3.7 (2 ) 12" min. min. 4" dia. perforated or slotted drain pipe, sloped to drain to a su itabl e di sch a rge I ocation Place base rock on dense native undisturbed soils or structural fill Rockery height in feet(H) Minimum base rock size Schematic - Not to scale *" Mgers Blodgnamics inc. Rolllng Bay M.rcanlllo Eulldlng ' 11254 Sunrlse Driv€ Balnbrldgo lsland, Washlngton e8110 TEL: 206/8!t2-6073 FAJ{: 2OA|U2-3797 GENERAL ROCKERY DETAIL F Street lmprovements Proiect Port Townsend, Washington FIGURE NO 3 PROJECT NO 00855-5 DATEDecember 2000 cI l I -l I "l F Street 00855-5 December 15,2000 Appendix A . APPENDD(A FMLD E)(PLOBATION PROGRAM Subsurface conditions for the project site were explored by'advancing thirteen bprings, B-1 through B-13, at the approximaie locations shgwq on the Site and Exploration Plan, Figure 1. Borings 8-L through B-4, B-8, B:12, and B-13 were. advanced tlrough the existing roadway ;;;;;;"t , B;;;r B-5 through B-? and B-e tdrough B-11 were advanced- in proposed stormwater infiltration. areas. Subsurface conditions observed it tJt" explorations are presented on the logs attached to this appendix as Figures A-1 through ,A.-13. The borings were . drilled on November 2 and November 3, 2000 to depths of 9-1/2 to 11 feet below the existing site grade. I The exploratioris were located in the field by taping or pacing relative to existing physical features. The approximate ground. surface elevations presented on the logs were interpolated from topographic information obtained from "F Street/San Juan_Avenue, City of Port towtt"und, Pieliminary 30 Percent PS&E .Submittal", SvR Design Company, September 25, 2000. The locations and efevations of the explorations should be consideredz accurate !o th". degree implied by the method used. A geologist from Myers Biodynamics was present throughout the fielci rvork'ki observe the u*ploruilorrs, obtain s,oil samples, and to p""pur" field logs of the explorati.ons. Soils were - classified in general accordance rvith ASTM D-2488 "Standard Practice for Description and Identification of Soils.(Visu'al-iVlanual Procedure)". and the Key to l'ioil Exploration Logs presented in this appendix. The exploration logs presented in this airpendix represent our interpretations of thb contents of the field logs and the results of laboratory testing' Soil rr111pi*u obtained flom the proposed infiltration are&siw€l'e also,classified in accordance with criteria sdt forth by the.U.S. Deirartment of Agriculture (USDA) for correlation with published soil infiltration rates. Boring explorations ivere drilled'with a trailer-mounted, holiow-stern' auger drill rig. , Sampling was performed through the holiow stem of the auger using Stanclard Penetration 'Test methQds. Standard Penetration Tests (SPT) were.taken with a split-spoon sapPler driven into the soii a distance of 1"8 inches with a 140 pound hamrher freeli falling from a heightof 30inches. Blowsfor each 6inches of penetration are shown on theboring lbgs. The nnmb"r of blows required to drive tlre,samples the last'.l2 inches is termgd the iStandard Penetration Resistance, 'Ihis resistance provideB a qualitative meastlt:e of the relative density of cohesioniess soils and consistency of cohesive soils. Soil samples were generally obtained at2-'l-/2 foot sample intervals.in the roadway borings and conlinuous sampling (below 2 foot depth) was obtained from the Qqrings ip the proposed infiltration,. areas. Representative portions of the split:spoon samplbs were placed in plastic jars, sealed, and transported to our offic,e foq further evaluation and selective iabotatory testing. Groundwater conditions'or evidence of soii staining and rnottiing were noted during thefield explorations and presented on theboring logs..The gtoundwater level atthe,time of drilling (afpl is shown on the boring logs. Groundwater was encountere{ at approximately 7'U2 foot' depth in boring B-8. Perched groundwater was noted in boring B-11 at approximately 6-U2 foot depth in the form of wet granular soil above a less permeable silt layer. Ij I j I J' Ij I J I l iJ r.J J Myers Biodynamics, fnc. I 1 l 1 I I I :t :l l .l l iJ ll J J J J J . fStrdet00855-5. December 15,2000 Appqndix.A . t Groundwater obserfation wells were installed in borings P.-5,P.-7, B-9, and B-lL located in , il."il.;d infiltra.tion areas.. Groundwater observation.wells were installed as L-inch diameter ;i#; fvi pipe. 'After placing the PVC, a filter material of silica dand was placed around. and above the sloited pipe. The nppJ" pprtion of the pipe (non-slotted) was backfilled with bentonite ;de q;h mon*m"nt iryst-aUei'at the groutra surfacd. The general well'coastruction is ;h;; on the boring logs.- Groundwater level measurements taken within-the observation ffii;;;r""lt""tjy one month after well ,installation are ires'ented on the.boring logs and indicate dry conditions in all tbe monitoring:wetls' I I : I = t I - Myers Biodynamics, Inc. Coarse-Grained Soil Density Fine-Grained Soil Consistency SPT* Well-oraded oravels andGW grav;l-sand hirtures, tittle or no fines ^ ^ Poorly grcded gravels and(;)l gravel-iand mixtures, liftle or no lines ev 3l!AnXZl,3:,, 0,, o u," "26 Clayey gmvels,vv gravel-sand-clay mixtures sw y;tx:i[i!31;:,1ii : :1," fines ^^ Poorly graded sands andl)f gravelly sands, little or no fines sM ;j,#;3:"'sand-sitt ei Clayey sands, sand-clay9v mixtures lnoroanic silts. veru fineML sanis, rock fl6ur, 6ilty or clayey line sands lnoryanic clays of low to,^l medium plasticity, gnveilyvL clays, sandy clays, silty clays, lean clays n r Oroanic silts and oroanic\)L siliy clays of tow plisticity lnoroanic silts. micaceousMH aiatimaceous ftne sand or silty soils, elastic silts 6;y1 lnorganic clays of highvt t plasticity,fatclays oH ?Wr?'#r'"ormedium D+ Peat, muck and other1 t highly organic soils Key to Soil Exploration Logs Sample Descriptions consist of the following: Minor constituents, major constifuents; density or consistency, color, moisture, and additional comments including trace constituents. Soil classification is based on visual field soil sample observations and laboratory results on selected samples, where indicated on the logs. Soil classification is based on grain size, plastic- ity, color, density/consistency, and moisture. Visual- manual methods of ASTM D2488 were used as an identification guide. Soil Density and Consistency Soil density/consistency in borings is related to the Standard Penetration Zesr (SPT) as shown below. Soil density/consistency estimates in test pits are based on visual observation and presented parenthetically on the soil logs. Unified Soil Classilication System Highly Organic Soils Observation Well Symbols is):.s -o)!Nq: Sg EIoc(n :- Eg,=GG\ bi.Q *E{o3Eotr sPr* o E.d GCcocN tzEo.ef,icss8ErfIDtr.=o Sr dr .S ER E VeryLoose 0-4 VerySoftLoose 4-10 Soft Medium Dense 10-30 Medium Stiff Dense 30-50 Stifl Very Dense >50 Very Stiff Hard *Standard Penetration Test measured in blows per foot Minor Constituents Estimated Percentage 0-2 2-4 4-8 8-15 15-30 >30 Trace* Slightly (Silty, Sandy, etc.) Clayey, Silty, Sandy, GravellY Very (SiW Sandy, etc.) -Not identified as a Minor Constituent 0-5% 5-12% 12-30% 30-50% ffi 7 24 27 J 50 5014" I l 8me2 Y ATD V s-1 s-2 Bentonite seal Grcund Water Level: date of reading ATD: At Time of Drilling Sand pack and well screen or hydrotip Boring Symbols Moisture Dry Lifile to no perceptible moisture ";::,!!' Some perceptibte moisture, probabty betow optimum Molst Moisture content probably near optimum ni[|" Much perceptibte moisture, probably above optimum wet Visible free water Laboratory Test Sym bol s MC Maisture ContentGS Grain Size classificationAL Afterberg LimitsPP Pocket Penetrometer (compressive strength in TSF) TV Toruane (shear strength in TSF) CN ConsolidationTUU TiaxialUnconsolidatedUndrainedTCU TriaxialConsolidated UndrainedTCD Tria,xialConsolidatedDrainedQU Unconfined CompressionDS Direct ShearK PermeabilityCBR Califomia Bearing RatioMD Moisture Density CurueN Nutients P = Sampler pushed *No sample recovery Test Pit Symbols S-t Sample number Grab Sample (iar or bag) 9 Ground Water seepage g Ground Water level obsetved in test pit excavation r"" Mgers Biodgnamics inc. Rolllng Bay Mercantllo Bullding . 11254 Sunriso Drlve Bainbrldge lslend, Washlnglon 98'110 f EL. 2oala42-6073 F li<t 2061842-5797 s-3 2.0'dia. Split Spoon Sampler (SPT) 3.25'dia. Split Barrel Ring Sampler 3.0'dia. Thin Wall Tube SamplerP t* 8s Ego G.os orat$u-Go S.Q.Qtcqo.9\tS!: .c gSthce8e oo :rL o.=s 'bo EbR RSSsso- 'So sPcLl-s(/J *tsqbo R o.Qs*o*e$ o.Q '. +$; fiEE otc),c ES 3arQc.!SE 6C ! 'p hE_6:'B!'F c T;S d.6'J I I I BORING LOG B.1 This too aDDlies onlv to borino location at lhe lime ol dtitting. Subsurface conditions may diller at..olher tocatiois 'ahd nay Slso chande over tine. This log is a simplilied inteerclation ol lne aclual concttttons' III l I I Ij I 1.i -.t I .iJ J J Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX: (206) 842-3797 DATE DRILLEDNov- 2.2000 ELEVATION (FT) 141 +l- Hnrrr A_1 SH 1 OF 1 PROJECT NO 00855-5 F Street lmprovements Proiect Port Townsend, Wash i ngton zoF c lr,l JU7Jol!o= \our.-cctr =uJ'a= oo =c) oFa IJJ Glrl IFo alrJ o- =a ioa =o m E I o-lrlo zILk lrJ ul DESCRIPTION 2-1/2-inches Asphalt Concrete Pavement (AC?) - easily penetrated, over dark brown, Slightly Gravelly Silty SAND (cuttings) Stightty Gravetty Slightty Silty SAND; loose, brown, moist, dark brown in upper 2-inches of sample 5 Stightty Gravelly Silty SAND; very dense, gray brown, moist Sandy SILT hard, gray, moist, trace gravel Fine to Medium $AND; dense, brown, moist, trace silt, zones of coarser sand and fine gravel hard drilling SAND;very dense, brown, slightly moist 10 15 20 GS 6 I 136 131 126 121 s-1 a s-2 b s-3 s-4 50/5" 2 4 5 10 25 42 15 24 24 Bottom of Boring at 11 foot dePth * il1or"ol='amrcs inc- '7 MB BUS: (206) 842-607s rjl\f'rL L .-t*.' i - t-IwoTIzoFoowIN$*$s3*'AE\oQePk-8a$$€E98-os.fdEJo6=.s-d*os$e.siFdi-'!o3*s*60Boo'5fQ{d.Fis5CE;aiila{Eed6lkE'H$Eg,EqBE urBgOJ\TJCDIt!tII-Jrl* s*dG 3R=6 *;:BE5.gl\) _ =-\* KE F< -agn€5 =.(oq'@d1(oOoImE'-IZrOFzo!.)l\)ooomrmI6za4s@+tDEPTH, FTELEVATIONSAMPLESB[-OWS/6""Tl8s--to{oO'r+R=-!JE3Jt_o.6<3seo==a-t5!F_0.YOJO,4OBSERVATIONWELLMOISTURECONTENT o/oOTHER TESTSsl5(bBsz.F5qa_o(n{Desi\sd55JoG.v,G'J(r)q€o\AIoo(/,oaG'OJ+qo(,)\qsoo\.oo_-'3g=U6ea-oJ(')JDQN\od€f,iod'g(ooN6\=gaFo_o(')JDboEf,:Jo6'oilI(/)q(/)es{oo-c3o_(D3('J{Dbd€f,io6a-<o tf,pj* m+\8cd. ESd -u-(r-tRB ei[tzr<- +CDO=oi3zou'r^q)s$J-OQ5g)+-So3;!)ox'o$:otogo6\too)a\)@CDcl)C^)@Ao)Cl)cl).1$ sl\)Jluc)s tu(os{ co r\)(O{O)('I-oBoo5oao=-5Qq){{o'oo-(D'a('ltuoIIoc!mINo-oT!!ocmo-lzooo@('r('rI(Jr F Street lmprovements Proiect Port Townsend, Washington zo E EulJaJ6l!o= -o ur 9-E= iEoo =o o olu E IJJ J. o zo Lk lrlJ lrJ oul o. =a :(oa =o 6 E IFo.ulo E DESCRIPTION 4-1/4-inches Asphatt concrete Pave-meryt (ACP):easily penetrated, ou.er . brown, iei e idietti Sitty SAND to Sitty Sa)ndy GRAVEL, trace cobbles (cuttings) Gravelly Slightty Silty SAND; dense, brown, moist, massive rough drilling, gravel and cobbles grades to Silty Sandy GRAVEL; very dense, gray brown, slightly moist grades to Stightly Sitty Sandy GRAVEL; very dense, brown, moist grades te Sandy GRAVEL;very dense, brown, moist, few cobbles10 15 20 3 eol 8521 Bol 75L s-1 s-2 s-3 s-4 50/5" 27 32 27 14 19 28 I -1 "l BORING LOG B.3 This tog applies only to boting location at lhe time ol dtilting. .subsurface conditions mav dillet at othet iiAtiofri |ha mav dtso cnanje overl)ii6."miliog isi iiiptiilea inbryrctation ol the aitual conditions' I i J l I I I *i -) J L.l Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX: (206)842-3797 DATE DFILLEDNov- 2.2000 ELEVATION (FT) 95-112 +l- FIGURE A-3 SH 1 OF 1 PROJECT NO 00855-5* 11ffi;"rnicsinc.'7 MB BUS: (206) 842'6073 I -t -1 I BORING LOG B-4 This log applies only to boring location at the lime ol dtilling. Subsudace conditions may dillet at other tocatiois ahd nay also chande over time. This log is a sinlplilied interpretation of the a;lual conditions. I I j tIII II I J Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX: (206) 842-3797 DATE DRILLEDNov,2- 2OOO ELEVATION (FT) bb +/- FIGURE A-4 SH 1 OF 1 PFOJECT NO 00855-5 F Street lmprovements Project Port Townsend, Washington zo E EI,J JAJcoulo= rO ur 9-Etr rJ lua,ooEC) aFauJF G UJIFo E I o-ulo zo E IU UJ o UJ o- =o a(l'a =o dt E 10 DESCRIPTION S-inches Asphalt Concrete Pavement (ACP) - easily penetrated, aver brown, Gravelly Silty SAND (cuttings) Gravelly SAND; medium dense, brown, slightly moist, trace silt grades to Very Sandy GRAVEL; dense, gray brown, moist, trace silt grades to Sandy Fine GRAVEL; dense, gray brown, slightly moist, trace silt no sampler recovery, grab sample obtained from cuttings (S-4) Sandy Fine GRAVEL; brown, moist 15 20 51 41 46 36 2 GS s-1 s-2 s-3 s-4 26 28 21 6I 12 7 14 21 11 14 15 tL f,tgers lf Eiodgnamics inc. '7 MB BUS: (206) 842-607s I -t I BORING LOG B-5 This too apDlies onlv to botino tocation at the time ol driling. Subsudac€ conditions may dilfer at..olher ioiatiois 'ahd nay also chanje over tine. This log is a simplitied inleqratalion ot the actuat conotttons. I I J j ! ,tI I ) .J Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 Ff,X: (206) 842-3797 DATE DRILLEDNov- 3- 2O0O ELEVATION (FT) 22 +l- norrr A_s SH 1 OF 1 PROJECT NO 00855-5 J F Street lmprovements Proiect Port Townsend, Washington zo Lk Eltl J Edo= -our 9- :., lll Q,ooEO oFo IJJFE UJ IFo hf o- UJo zo E ul IJJ aul o- =o =(l'a =o o 5 Fine SAND; Ioose, brown, moist, trace silt, trace gravel and coarse sand (USDA Classification: SAND) Verv Sandv GRAVEL; dense, gray brown, slightly moist, trace silt USDA Ctassification: Sandy GRAVEL) becomes very dense, gray, slightly moist, trace silt becomes slightlY moist, trace silt DESCRIPTION Turt Grass/TOPSOIL over 10 15 20 GS GS 3 2 s-1 s-2 s-3 s-4 13 24 29 2S 5 6 4 3 2 2 3 5 10 17 17 20 Bottom of Boring at 10 foot dePth Groundwater Level 12/5/00: dry 17 12 7 2 * Itlor:l=.'-mics inc- '7 MB BUS: (206) 842-607s I,f'rI'ltL,f:kE'EHEEE OEg\IJ@rrnItIIIJrl* gr4c +R5'I3;'*R€55l\) - =--:* SE Fo F3$=b 3.(otD@d-: (ooDEPTH, FTELEVATIONSAMPLESBLOWS/6'ERSs:sS.SdN *.=gs;^ =.b(/i=.2A:F*dsart.>RBB5;eHSRSve\$*sof,si=o'Jocl)Q-= FG.r:J*Ost<-*.R:-_,o gtsdo€o-{$:S'H.E(D<s.98.oN$q56\=ts,\}*s93os5a-Q€d,=! !)\aoIFa_of,v,JDQN=Bdsv,G.=-f,oG.!*QO.tsRBq(D :JdEeQo-ilq\bUJ\ai:5s\=(nzUeo5(/)JDQN\scisqG.\=lo6'too(tFO(D sisISEEq*=ig c,)Sq=osNZ59-\ Q-\ogFUsdd$s=(')\q€o{I=!f,EAf,bd8d;Nq)EI+oJ-oci:.oSOeEoRQS.$so>A${9qs3fo!-PosQi(/)OrPq.o-e€a$-{oJtri6*.r trtci mt(/)po9:E-o(,){€6.+z=U)q)=\aaF;:l(noirsNc)Fio6'.Tl8s--FIO-{Oo- r+R=-Jfr3F5-<Jsqa=5a-a=!F_d.YO-rO+OBSERVATIONWELLMOISTUBECONTENT %OTHER TESTSf\)(Jl5N) CDooOv)ooh Cr)G)U)5(o5(oata6@u)io 6 <'$!, l^tu(tt\)J otp::G)luolu <(ootolUJJJo (t co ct)lElJJJoco-.lA(Jtoboo5otro=Qq){oI{*l=6oo_(bb(}rN)oJITDoEzoFoowICDR=j!i d'$c--S*AEQeEk--8e$qEG=oEg-o556EsFd'=.s-8*-obg6=€9a-!aa. b.€*ooGoo'550e.*Fi3iEc3e':d6'Cddc,{1TC'-:o1rof,10i.tNoom-r{6za4N)5+i!otmICDo-oa!Togmo{zooooOr(JtI('r I -t I BORING LOG 8.7 This too aoDlies onlv to botino location at the time ol dtitling. Subsurfacs condilio-ns may dillat at..other iocatiois 'aha nay also chanie over time, This log is a simplilied intepretalion ot tne actuat condnons. r& ItI J IJ II I ! I ) I :.J -) .J Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX: (206) 842-3797 OATE DRILLEDNov- 2- 2OO0 ELEVATION (FI) 27 +l- FIGUBE A-7 SH 1 OF 1 PROJECT NO 00855-5 I I F Street lmprovements Proiect Port Townsend, Washington zotr EIri JaJoluo= \o ru 9- /uJ6Eoo =o o U'ulF Gul I o oul o. =(t, -@ a =o o E J. o. lulo zo E IIJ t! stiff,brodark fewmediumtostiffmoist,WD, DESCRIPTION Grasses/TOPSOIL 5 Gravetty SAND; loose, brown, m9i9!,lrpce organics, trace silt (TJSDA- Classification: G ravelly SAND) Verv Sandv CLAY; hard, brown, moist, trace organics, thickly laminated at 40 de{rees t6 horizontal (USDA Classification: LOAM) Gravelty Slightly Silty SAND; dense, gray brown, moist grading to Stightty Sandy SILT;very stiff, gray brown, moist SAND at base of samPler 10 15 20 12 12 3 GS GS, AL 17 12 22 7 a s-1 b s-2 s-3 s-4 3 4 4 5 4 12 20 22 12 14 18 23 6 12 14 24 Bottom of Boring at 10 foot dePth Groundwater Level 12/5/00: dry --l * ltlffifl-micsinc. '7 MB BUS: (206) B4z-607s I BORING LOG 8.8 This loo aDDlies onlv to botino location al the time of drillins. Subsuiace condilions may diller at other tocatiohs 'ahd may atso chanie over time. This log is a sinplilied interpretation ol the actual conditions. ;l I iI -J )Mgers Biodgnamics inc. BUS: (206) 842-6073 Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX: (206) 842-3797 DATE DRILLEDNov 2- ?OOO ELEVATION (FT) 14 +l- FIGURE A-8 SH 1 OF 1 PROJECT NO 00855-5 E !Fo.ulo zo E ulJul o tJlJo- =a ioa =oJo F Street lrnprovements Project Port Townsend, Washin gton zoF trUJJAJmuIo= \o ur 3- /ura,oo =o @FU'ulFElrl :EFoDESCRIPTION 3-inches Asphalt Concrete Pavement (ACP) - easily penetrated, over FILL: Slightly Gravelly Slightly Silty SAND;loose, brown, moist I 4 1 -6 a s-1 b a s-2 b a s-3 b s-4 b 4 4 2 2 3 1 7 14 4250/z', 4 24 22 12 18 14 Slightly Sandy Gravelly SILT medium stiff, dark brown to black, moist, with trace organic fragments and debris (HISTORIC TOPSOIL) grades to Sandy SILT; soft Silty SAND; loose, dark brown, moist, trace gravel, trace roots, thin dark brown interbeds with trace organics grades to Stightly ]itty!,," S4!9:,"!,ut d"n:::_go! 9_"n,t:t ATD V Very Silty Fine SAND; medium dense, gray green to brown, moist, trace clay, tra6e fine roots, stained and mottled, Gravelly SAND in bottom of sampler no recovery 5 t 10 T Bottom of Boring at 10-1/2 foot depth 15 20 r-. tlrrrIatLt-EoEzol-oowt(0$*Ea'faig-6,9o3a3R€,6eE-s3dssd6=s--d--o$goSs-s'bYFqqb.s*60Go=oo5s.3:d:!Eia8$dPFs*t!HHFc,Fq;ittAJEg^-.r JwrtnUtIIIJn* B:dc dR='6 3o?,$ E=.9* SE F= -49$€6 =.(oC!@d+(oootnEz-of;soS.,NooomrmE5za-lt\){+>DEPTH, FTELEVATIONSAMPLESBLOWS/6"eoooao:.aS)(o{No'oao'b5oo'(/)ooa)(oI{tu\d-oCn AC,)3 b,o-.a bl= \s<g Rsfigs1-- cJY$<d 6'G)q nN3 r5:l $'<v)o S(.rJ- \bS cDZ.qi !u:s z:5 sQI9\:o-3(Do:E$aqi\oci€3o6'a(d'oNox.-(/)(d'\=CDS)\qoC,)O)\acnt--il(ttSTsciE:{o6'sooo3o(/)5a{o6'ec/)Uo!)CI'a.=to!)oIC,)q)f,\a|-o!Psxol-.o1.3e$(o.B==ooi(D\=(/)\q66Y(/)qCDaUoov,JDo.$*o-dEio6'j*^OYmdU,(')()6'7(e* T'o{q6szzgCnt(D.Tl8e--rr+ o-{Oo'r+R=-JE:)-J-o.b<3ffea=50II5!9AYoJO+odcfa-Eq)o\r-oo{Nao-Pa-aOBSERVATIONWELLMOISTURECONTENT %OTHER TESTS-.t5O)ooo(r) o--tN){t\)t\)@u)5('5cnN)9)a)(nro-(n(np r-.IO)Cl)Yo too)('G)J5(Ioot\)o3octmI(0o7oT!t0omo{zooo@('r(,rI(Jr J'1fk,tLt-woT-zol-oowI'Joil*3.€--s*AE.9ogk.-8a$s36qgdg:lO6 *=..F;--ooSoSf9ar-'a59gs606o6.3fae.E:FEasS.iE$d9o='gd6lkt!H$Eg,FqEE 8Eg'.1 J6) rrnll:rEEdrl* q*dc 3"R5'E *c'rt-E 3 S.ryN) _ =-\* s8F< 3_gdk6i@tD@F-(oa(Jimo-:D1c.O'msosl)Nooomrmt5za{il)\t+DEPTH, FTELEVATIONSAMPLESBLOWS/6"Qo-8S>KOS*-=oQ-s)I *-'ad*EQoIObs> (/)SG-J\=fo(t)il^f,\=tA){5'q)oa.A(,DbgB='OQFSo-*$$ciob=das-oba-E=.<\*o6':11f,o\-O)3q)ogNooo.Aq)Jd'(tQo-HXo$H -_q*s)i6=r!.=SgABtri -.5R\+erJDRsrd\E(/)F!.^€€\={oCAtoo=!.!:oo(do)d'(nFOg)qigQR;6=(D\il3=L \uQ cr)i!o=ai''<lEd€a-(/) \$:JB*l-(/)OJDss-o-d5{o(n.:+trioosodo(r)r:-JOVs' mtl aO ft) ,'l\-N ftglui t€9{rre 65ZaUooN(D\.-cr)q).o_$/)r-:6c(a{r-n8e--r+o{oo- r+R=ETJ9HgoJ-1_ob<Jffea==@EI5!t"-8.Yo-l 6+OBSERVATIONWELLMOISTURECONTENT %OTHER TESTSt$l\)tu('l\|ooo(,) cn cDoo--tN)-.tlUtu<t)aacnFCOI\)9<l-r<ot\)d)Qsa(tNl$Jr o)(tJJrt$-.t-.| J5(J|oboo{otrosas){o>$oa(D-o(nN)o3oct>t"IoaoI!:0oLmo-lzooo@('r('rT('r I -t I BORING LOG B-11 This loo aDDlles onlv to botino tocation at the lime ol dtitting. Subsuiace conditions may dilfet at..olher iociidi{^ha na| 6tso chande ovet time. This log is a sinpliliad inteprctation ol the actual conditbns. 1 l i -J : -i *..1 SJ Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX: (206) 842-37e7 DATE DFILLEDNov. 3.2000 ELEVATION (FT) 25 +l- nnrrtr_11 SH 1 OF 1 PROJECT NO 00855-5 F Street lmprovements Proiect Port Townsend, Washington oFa IJJ Gul !Fo zotr GUJJaJ!ouJo= rf iEoo =c) aul (L =a -@ a =o o l-lr Fo-ulcl zo E lrJ UJ F\L|JTOPSOIL: S1LT very stiff, black, moist, trace sand, charcoal and metal fragments becomes Slightly SandY (USDA CtasEifiiation: Sitt LOAM) DESCRIPTION Grass 5 Sliqhttv Sittv Gravetlv SAND; dense, brown, moist U"SOA Ctassificatioh: G ravelly SAN D) v ellyM e d i y m ;9 A t l2; v B ry lglpS, b!cv/-n, v gry m o i st t o w et Stiqhtlv Sandv Clavev SILT; hard, brown, slightly moist U"SoA Ctasiificatioi: Silt L2AM) recoVdry, SdmBlerdrifing on cobb|e GRAVEL and COBBLES (cuttings), grab sample (S-4) ATDto Gra Sandy no recovery, drill to 10 foot dePth 't0 15 20 18 19 5 GS (,D GS 15 10 20 5 s-1 s-2 s-3 s-4 a a b b 36 40 17 50/6', o 17 20 29 7 I 10 1'7 Bottom of Boring at 10 foot dePth Groundwater Level 12/5/00: dry * Itl"":'f'"mics inc. '7 MB BUS:(206) B4z-607s F Street lmprovements Project Port Townsend, Washi ngton zotr Elrl JAJouJo= \ou9-cctr iEoo =o @FoulFEul.LFo zo L,< UJ l! oulJo =o =(oa =o o lr Fo Lrlo DESCRIPTION 4-inches Asphalt Concrete Pavement (ACP) - easily penetrated, over FILL: Slightly Gravely SAND; loose, dark brown to brown, moist TOPSOIL: Slightly Gravelly Slightly Sandy SILT stiff, dark brown to black, moist, fine organics 5 grades to Gravelly SAND; medium dense, brawn, moist Slightly Gravelly Sandy SILT very stiff, gray green to brown, moist, mottled Fine SAND;loose, brown, moist 10 15 20 4 b 15 ssl 28L 2sL 18L s-2 a s-3 b s-4 a s-1 b 2 J 6 4 4 4 61 o 6't0 Bottom of Boring at 10 foot depth I I BORING LOG B'12 i:;:rgfl::t'1";:i'!,:g'"fr:;xg;":#i"ii,-#'n|!fs"LT't:i$i,,i:if;,gfr,nf:,ilfl"L?E{x,,";ril;;,iil"{ l J I I I Il i I! J i 1 ) J J Rolling Bay Mercantile Bldg. 11254 Sunrise Drive Bainbridge lsland, WA 98110 FAX:(206) 842-3797 OATE DBILLEDNov- 2- 2OOO ELEVATTON (Fr) 38-112 +l- ,,ourh-12 SH 1 OF 1 PROJECT NO 00855-5 lr Muersaf Erlougna,,,rcs rrr..'7 MB BUS: (206) B4z-607s 1 I BORING LOG B-1 3 This,log applies only,to boring localion at the time ol dtiiling. Subsudace conditions may dilfer at othertocauons and may also change over time. This log is a simiptilied interpretation or 6e a,liij i6iiit-iiil II I I J I I,t ! lul !i .) i ,)Mgers Biodgnamics inc. BUS: (206) 842-6023 F.o..|lin gFaV Mercantile Btd g. 11254 Sunrise Drive Bainbridge lsland, WA 99110 FAX; (206) 842-3792 FIGUREA-13 SH 1 OF 1 PFOJECT NO 00855-5I F Street lmprovements project Port Townsend, Washingtbnll. Fo- UJo zotr lrJ UJ olrl o.E o ioa =oJo zotr EulJAJ@uJoE :o ur -o-Etr ipra=Oo =o o U'ulF ccttJ IFoDESCRIPTION 3--l/2-inches Asphatt concrete pavement (ACp) - easily penetrated, overFILL: Gravely Sitty SA:ND @ittiigij' - " " TOPSOIL:FineSlightlyGravelly mediumsituSAND;darkdense,brown,moist,organics 5 Slightly Silty Fine SAND; medium dense, brown, moist, trace gravel Very Silty Fine SAND;very dense, gray, moist rough drilling grades to slightly Gravetty stighily sitty Fine sAND; very dense, gray, moist grades to Silty Fine SAND; trace coarse sand and fine gravel10 15 20 82 77 72 67 a s-1 b s-2 s-3 s-4 42 50/3" 50/5" 7 7 7 6 10 4 DATE ELEVATIONr-. F Streel00855-5. ,December l-5,2000 Appendix B APPENDD(B' I,ABOR"ATORT TESTING ./Laboratory testing was performeil on selected site'soil samples to evaluate index properties and proyid.e ^ .orretution with geotechnical engineering parameters. - Laboratory tgsts were p"tiorm"d on disturbed soil samples collected from boring_ explorations. The laboratory iesting performed and procedures followed are presented below. Tests werd conducted in g"nurul u."ordance witlr- the American Society of Testing and Materials (ASTM) standard test procedures. ' ' SOIL CI"ASSIFICATTQN Soil samples coiiected aririrrg the exploration proglam were.visualiy classifi'ed in th.e fieid' Field visual classification o? soils was conducted in general accofdance with ASTM D-2488 "standard. Practice for Description and Identification of Soils (Visual-Manual ' Procedu,.re)" rind the Kpy to Soil Exploration Lbgs presented in Appendix A. Field log Soil classifications were updated. as,necbssary based on the results of the leboratory testing. 'Laboratory soil classitrc-ations and descriptions were in general accordance with ASTM standards. In Crddition,.soils within the pioposed,infiltration areas were also classified in accordance with USDA soil textural criteria. ift" USOA description is shown in parenthesis on the infiltration area boring logs. \ ' , MOTSTURE COI.{TIINT (MC) Moisture content deterrninatidns ul'ere performed on site sojl sampies in general accordance with ASTM D-22L$. The results'of these tests are presented on the boring logs. 1 ' I cR"crN sI7.E ANALYSnS (GS) Grain size analyses were performed on seleqted site soil samplds to cletermine glain size distribution. The selected samples are indicated on the applicabl.e exploration 1ogs. Sieve dnalysis of particles greaterthanthe U.S. No. 200mesh sieve size were performe{. The te-sts were conducted in general 'accordance with ASTItf D-422.' Grain size 'analyses 'were blso perforrned for particles sqaller than the U.S. No. 200 sieve using the hydrometer method. the results of the grain size analyses are shbw-n in this'appendix ori Fi.gures B-l through 8-'6. ATTERBERG.'LilruTS (AL) Atterbere Lirrrits were .determined lbr a selectcd sample of fine grained cohesive soil "ti.o""iJ*ud ih the exploratiohs. The tests were performed in general aciordance with AS'IM D-43L8 to aid in classificatiofr and correlation with engineering'parameters of the soiis' Results of the Atterberg Limits test are shown in this appendix on Figure B-7. I .t Myers Biodynamics, Inc. PL LLAASHTO% CLAY USCSo/o SILTo/o GRAVEL % SAND% COBBLES SM14.0 55.9o GW43.6tr52.5 SP-SM94.9A \s \ \L \ \t\\ N! \\ \\\ :\ \ \ I\ \:\\ F ;\lH PARTICLE SIZE DISTRIBUTION TEST REPORT N AQ 100 90 80 70 t 2uotr L2Eo uJ C) ffioo(L 30 20 10 0 100 o GRAIN SIZE. MM SIEVE inches PERCENT FINER c)tr A .75 .50 .315 100.0 97.7 94.2 100.0 86.3 73.3 X GRAIN SIZE Doo Dso Dro 0.310 6.94 1.81 0.312 0.367 0.252 0.146XCOEFFICIENTS cc cu t.52 22.21 1.18 2.51 SIEVE number size PERCENT FINER c)tr A H4 #10 tt20 H40 #60 # 140 H200 86.0 79.5 74.2 66.6 55.0 37.0 30.1 47.5 3t.3 20.7 13.0 8,2 4.6 3.9 100.0 99.8 97.3 71.1 29.5 7.1 5.1 c) Silty sand U Well-graded gravel with sand A Poorly graded sand with silt REMARKS: o Classification based on grainsize only tr Classification based on grainsize only A Classification based on grainsize only o Source: B-1 D Source: B-4 n Source: B-5 SampleNo.:S-2b SampieNo.: S-2 SampleNo.: S-2 Elev./Depth; 5.5-6 Elev.lDepth: 5-6.5 Elev./Depth:4-6 Client: Myers Bioclynamios ino. Project: FS 00855-5 J-1366 SOIL TECHNOLOGY, INC. Figure B-1 7o COBBLES o/o GRAVEL % SAND % SILT % CLAY USCS AASHTO PL LL C)49.9 46.7 GP!38.4 57.7 SP A 32.7 60.4 SP-SM ili \\t^ '! \N N \\ il \ \ \\\,\ \ \\\\\tf,.\ \\ \I v lillirlllr \\:+# PARTICLE SIZE DISTRIBUTION TES]" REPORT itri q * 100 90 80 70 E. 9uotr Lz50uIo ffioo(L 30 20 10 0 00 0.1 GRAIN SIZE - mm SIEVE inches size PERCENT FINER c)tr A 1.5 1 .75 .50 .37s 100.0 80.9 13.4 100.0 86.3 81.5 81.5 74.3 100.0 94.8 91.6 81.7 X GRAIN SIZE Doo Deo Dro 6.39 0.941 0.294 4.35 i.05 0.301 3.02 0.595 0.15iXCOEFFICIENTS c^ cu 0.47 2t.76 0.85 14.45 0.78 20.04 SIEVE number PERCENT FINER O tr A #4#t0 #20 #40 #60 #140 #200 50.1 38.3 28.4 15.6 8.2 4.2 3.4 6t.6 43.9 25.7 14.0 8.4 4.7 3.9 67.3 52.4 35.9 24.5 15. s 8.0 6.9 Cr Poorly graded gravel with sand I Poorly graded sand with gravel A Poorly graded sand with silt and gravel REMARKS: Cr Classificatiou based on grainsize only D Classilication based on grainsize only A Classificalion based on grainsize only o Source: B-5 D Source: B-6 n Source: El-6 Sample No.: S-3 Sample No.: S-2b SampleNo.: S-4a Elev./Depth:6-8 Elev.lDepth: 5.5-6.5 Elev./Depth: 8.5-10.5 SOIL TEGHNOLOGY, INC. Client: Myers Biodynamics lnc. Project: FS 00855-5 .Project No.; J-1366 Plate 2 Figure B-2 Il -l l .J PARTICLE SIZE DISTRIBUTION TEST REPORT q e 100 90 80 70 t 2uotr L250 TUo fft oo(L 30 20 10 0 200 100 0.1 GRAIN SIZE - MM o/o COBBLES % GRAVEL % SAND o/o SILT % CLAY USCS AASHTO PL LL c)47.1 45.8 ML 54.9 SP-SM A 11.6 78.2 SP SIEVE inches size PERCENT FINER C)tr A 1 .75 .5 .37s 86.1 77.7 100.0 92.5 90.2 87.3 X GRAIN SIZE Doo Dgo Dro 0.0072 0.0029 4.71 0.889 0.243 0.745 0.362 0.210XCOEFFICIENTS cc cu 0.69 19,40 0.84 3.55 SIEVE number size PERCENT FINER c)!A #4 #10 #20 #40 #60 #140 #200 92.9 60.2 42.1 29.3 18.0 10.3 6.3 5.3 82.4 7 5.5 oJ. / 31.7 14.5 5.0 4.2 SOIL DESCRIPTION c) silt n Poorly graded sand with silt and gravel A Poorly graded sand with gravel c) Classification based on grainsize only. ! Classification based on grainsize only A Classilicafion based otr grainsize only cr Source: 8-6 ! Source: B_6a n Source: B-7 Sample No.: S-4b Sample No.: S-1 Sample No.: S-lb Elev.lDepth: 8.5-10.0 Elev.lDepth: 2.5-4.5 Eiev./Depth: 2.5-4 \Li \, \\ \ \ \\\ \ :\ l.ql \\ \\\ \ l, 1 \\ \\ \.\\\ \\I:\ E :n SOIL TECHNOLOGY, INC. Client: Myers Biodynamics inc. Project: FS 00855-5 JJ-1366 Figure B-3 IJ PARTICLE SIZE DISTRIBUTION TEST REPORT -,(!oo s**+ 100 90 BO 70 E. 2uo tL L250 tUo ffro(L 30 20 10 0 1 GRAIN SIZE - mM % COBBLES o/o GRAVEL % SAND o/o SILT o/o CLAY USCS AASHTO PL LL o 42.2 24.6 CL 23 43 n 6.3 69.4 SM A 32.6 55.2 SM SIEVE inches PERCENT FINER C)tr A .75 .5 .375 100.0 98.3 100.0 96.3 86.2 X GRAIN SIZE Doo Dgo Dto 0.0529 0.0072 0.384 0.174 3.53 0.480 X COEFFICIENTS cc cu SIEVE number PERCENT FINER o tr A #4 #10 #20 #40 #60 #140 #200 66.9 93.7 89.6 81.2 64.5 39.5 26.0 24.3 67.4 47.0 36.6 28.4 21.2 13.8 12.2 ct Sandy lean clay D Silty sand A Silty sand with gravel REMARKS: C) D Classification based on graainsize only A Classification based on grainsze only o Source: B-7 n Source: B-9 n Source: B-9 Sample No.: S-2 SampleNo.: S-2a Sample No.: S-3 Elev./Depth:4-6 Elev.lDepth:4-5 Elev.lDepth:6-7 Ll \- \ \ \\ \ \\\ \\ \ Ir \\ 'I \ a\ \\ ) \ \\\ ),\ F'rl\zi \\i. \,\ Client: lvlyers Biodynaurics Inc. Project: FS 00855-5 4 SOIL TECHNOLOGY, INC. No.: I-1366 q F: rl n hflE Figure B-4 \t\ I \i\\ \ \\ (\\\t \!-\}. 1 \\'\ \t t+ \ \. \c\\\ \ -[ PARTICLE SIZE DISTRIBUTION TEST REPORT ,Eq c! e9 100 90 80 70 tr 2uo LL L2so LrJo ffioo(L 30 20 10 0 1 1 1 GRAIN SIZE - mm o/o COBBLES % GRAVEL % SAND 06 SILT % CLAY USCS AASHTO PL LL c)15.3 60.5 SM 34.5 48.9 SM A 52.6 28.7 SIEVE inches siTe PERCENT FINER C)tr A 1 .75 .50 .375 100.0 99.0 95.0 100.0 90.5 82.5 77.5 X GRAIN SIZE Doo Deo Dto 0.654 0.166 2.80 0.289 0.0119 0.0052 X COEFFICIENTS cc cu SIEVE number PERCENT FINER o !A #4 #10 #20 #40 #60 #140 #200 84.7 75.8 64.5 50.6 36.5 26.4 24.2 65.5 57.6 50.5 39.4 26.8 18.3 16.6 81 .3 SOIL DESCRIPTION O Silty sand with gravel tr Silty saud with gravel A REMARKSI c) Classification based on grainsize only E Classificalion based on grainsize only A o Source: B-10 n Source: B-10 n Source: B-10 Sample No.: S-1 Sample No.: S-2 Sample No.: S-3 Eiev./Depth:2-4 Elev.lDepth:4-6 Elev./Depth: 6-7.5 Client: Myers Biodynamics Inc. Project: FS 00855-5 5 SOIL TECHNOLOGY, ING. I-1366 il Figure B-5 I J PARTICLE SIZE DISTRIBUTION TEST REPORT .E ccSc; A: ;q 100 90 80 70 M 2uotr L250lilo ffioo(L 30 20 10 0 0.001 GRAIN SIZE. MM o/o COBBLES o/o GRAVEL o/o SAND o/o SILT % CLAY USCS AASHTO PL LL o 21.1 71.8 SW-SM 63. I 26.1 ML SIEVE inches _size_ .75 .50 .375 PERCENT FINER C)tr 100.0 95.5 87.9 X GRAIN SIZE Doo Deo Dto 1.46 0.568 0.158 0.0153 0.006i 0.0022 COEFFICIENTS cc cu 1.40 9.26 1.13 6.95 SIEVE number size PERCENT FINER o n # # #4 #10 #20 lt40 #60 i40 200 18.9 67.1 44.0 21.6 13,6 8.1 7.1 89.2 SOIL DESCRIPTION O Well-graded sand widr silt and gravel tr silt REMARKS: C) Classification based on grainsize only tr Classification based on grainsize only o Source: B-11 n Sowce: B-11 SampleNo.: S-2 Sample No.: S-3b Elev./Depth:4-6 Elev.lDepth: 6.5-8.0 \l 1 \ '\\\\ \\ \\t \ \f- !I\\ \t \ \ x -u SOIL TECHNO!.OGY, INIC. Client: Myers Biodynamics Inc. Project: FS 00855-5 Plate 6Proiect No.: J-1366 Figure 8-6 '1 'l 'l I I I I I I :t l J l ll J J J J J Project : Myers Biodynomics lnc. FS 00855-5 Project No. : J-1366 Locotion : Dcte : Tue Nov 14 2000Soil Technology, lnc. s CH or 0H .,t+"r\. or 0L o CL-ML MH or 0H ML or 0L PLASTICITY CHART 10 43 23 lU 0 70 80 90 100 110010203040 BO 70 60 -LL >< 50LI-z. >_ 40FOF?30.Jo_ 20 50 60 LIQUID LIMIT, LL Soil Clossificotion (CL) Sondy leon cloy Wcter Content Liquid Limit Plostic Limit Plosiicity lndex SomPle Symbol Number o B-7 S-2 12 ! I . Figure B-7