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| issue date = 11/14/1979
| issue date = 11/14/1979
| title = Forwards Response to 790801 Ltr Requesting Info on SEP Structural Topics III-2,III-3.A & III-7.B.Relevant Articles from Ny State Bldg Const Code & Subcontracter 1966-67 Tech Specs Encl
| title = Forwards Response to 790801 Ltr Requesting Info on SEP Structural Topics III-2,III-3.A & III-7.B.Relevant Articles from Ny State Bldg Const Code & Subcontracter 1966-67 Tech Specs Encl
| author name = WHITE L D
| author name = White L
| author affiliation = ROCHESTER GAS & ELECTRIC CORP.
| author affiliation = ROCHESTER GAS & ELECTRIC CORP.
| addressee name = ZIEMANN D L
| addressee name = Ziemann D
| addressee affiliation = NRC OFFICE OF NUCLEAR REACTOR REGULATION (NRR)
| addressee affiliation = NRC OFFICE OF NUCLEAR REACTOR REGULATION (NRR)
| docket = 05000244
| docket = 05000244
Line 17: Line 17:


=Text=
=Text=
{{#Wiki_filter:
{{#Wiki_filter:~,, .-      REGULATORY        ORMATION DISTRIBUTION SYS        i (RIOS)
ACCESS'ION NBR:7011200454            DOC s DATE: 79/11/14      NOTARIZED: NO          DOCKET FACIL:50-244 Robert Emmet Ginna Nuclear Plantp Unit AOTH, NAME            AU'l HOR AFFILIATION lr  Rochester  G 05000244 WHITED L, 0 ~          Rochester Gas 8      Electric  Corp, RECIP ~ NAME          RECIPIENT AFFILIATION ZiKA'A'NN,D, L,          Oper at ing Reactors Branch 2


==SUBJECT:==
==SUBJECT:==
Forwardsresponseto790801ltrrequesting infoonSEPStructural
For wards  r esponse  to 790801 l tr r equesting info on SEP Structural 'lopics III-2E III 3,A 8 III>>7.B.Relevant articles Specs encl.
'lopicsIII-2EIII3,A8III>>7.B.Relevant articlesfromNYStateBldgConstCodeLsubcontracted 1966"67TechSpecsencl.~~%DISTRIBUTION CODE:ASSESCOPIESRECEIVED:LTR
DISTRIBUTION CODE: ASSES TITLE:  SEP
$ENCI.JTITLE:SEPTopicsNOTES:~QCPPFmaP~Wgl94tPMLME RECIPIENT COPIESRECIPIENT IOCODE/NAME LTTRENCLIOCODE/NAME ACTION:19BC~g8~~INTERN~~REGF11RE'PERFBR1114REACSFTYBR1116EEB1i88RINKMANiSEP8R33SIZE:COPIESLTTRENCL111111111122~,,.-REGULATORY ORMATIONDISTRIBUTION SYSi(RIOS)ACCESS'ION NBR:7011200454 DOCsDATE:79/11/14NOTARIZED:
                                            ~~%
NODOCKETFACIL:50-244 RobertEmmetGinnaNuclearPlantpUnitlrRochester G05000244AOTH,NAMEAU'lHORAFFILIATION WHITEDL,0~Rochester Gas8ElectricCorp,RECIP~NAMERECIPIENT AFFILIATION ZiKA'A'NN, D,L,OperatingReactorsBranch2EXTERNAL; 23ACRS7NSEC161613LPOR11Z$3fTOTALNUMBEROFCOPIESREQUIRED:
from NY State Bldg Const Code L subcontracted 1966"67 Tech COPIES RECEIVED:LTR $
LTTR87ENCL t4l(E1~'1lC1"11l'1I<w>4a~'1"v7,~l~l~+'aIIIQw4IIP
Topics ENCI. J    SIZE:
//l////9<
NOTES:~       Q      C PPFmaP~ W                gl94tPMLME RECIPIENT           COPIES              RECIPIENT          COPIES IO CODE/NAME           LTTR ENCL          IO CODE/NAME       LTTR ENCL ACTION:     19 BC    ~g8 ~   ~
///'/////Pr..
INTERN   ~~REG        F                1      1                              1    1 RE'PERF  BR      1      1                              1    1 14  REAC SFTY BR          1      1                              1    1 16 EEB                    1                                      1    1 i8 8RINKMAN                i                                      1    1 SEP  8R                3      3                              2    2 EXTERNAL; 23 ACRS                      16    16      3 LPOR                  1    1 7  NSEC                  1 TOTAL NUMBER OF COPIES        REQUIRED: LTTR Z$
//////////////////////
87  ENCL 3f
ROCHESTER GASANDELECTRICCORPORATION
",IIATCI,lo89EASTAVENUE,ROCHESTER, N.Y.14649LEOND.WHITE.JR.VICEPRESII7ENT ITELEPHONE AREACODETIE546.2700November14,1979DirectorofNuclearReactorRegulation Attention:
Mr.DennisL.Ziemann,ChiefOperating ReactorsBranchNo.2U.S.NuclearRegulatory Commission Washington, DC20555Subject,:
Systematic Evaluation Program-TopicsIII-2,III-3.A,III-7.BR.E.GinnaNuclearPowerPlantDocket,No.50-244


==DearMr.Ziemann:==
t 4l                                          (
EnclosedpleasefindourresponsetoyourletterofAugust1,1979inwhichyourequested information onSEPstructural topicsIII-2,III-3.AandIII-7.B.Ifthereareanyquestions regarding thisinformation, pleasecontactus.Verytrulyyours,L.D.White,Jr.Enclosures
E 1 ~
>>>iE0o9<'
        '1 l
N Kl'll5IOKMIIRl)MIKE'ILY III-2WindandTornadoLoadsQuestion:
C l
Foreachsafetyrelatedstructure,'nclosure Go299i)~'ll->lRiiue%591.Describetheprocedures totransform winddataintodesignpressureandgustfactors.2.Providedesignbasis,ifany,fortornadoloadingincluding:
1 "1                                  1
a.translational windspeedb.radiusofmaximumrotational windspeedc.procedures totransform tornadodataintodesignpressure.
                  '1        I <w  >4            a  ~ '
1
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II P


===Response===
    //l////9< ///'/////Pr..
TheoriginaldesignofGinnaStationdidnotincludetornadoeffects.Windloadswereappliedasspecified bySectionC304-4oftheNewYorkStateBuildingCon-struction Code.Thiscodeisbasedona'windspeedof75milesperhourata30ft..height.
  ////// ///    /////////////
Thewindspeedisconverted toapressureloadingandappliedasshownintheCodetables'hich areincludedasAttachment, I.Anevaluation oftheplant'scapability towithstand tornadoeffectswasperformed in1968.Thisevaluation, whichisincludedintheFSARasAppendix14A,wasbasedonatangential windvelocityof300mphandanexternalvacuumof3psig.TheportionofAppendix14A'thatdiscusses thetornadoeffectsonstructures isprovidedasAttachment II.Kle~~mImmmMmHl5 In1976anadditionwasmadetotheauxiliary buildingforastandbyauxiliary feedwater system.Thedesigncriteriaforthestandbyauxiliary feedwater pumpbuild-ingweresubmitted totheNRCbyletterdatedMay20,1977.Furtherinformation wassuppliedwithourletterdatedJuly28,1978.Staffapprovalofthestandbyauxiliary feedwater system,including thebuilding, wasissuedbyletterdatedAugust24,1979.Thisbuildinghadditionwasdesignedinaccordance withtheprovisions ofReg.Guide1.76.Asindicated inAttachment III,thebuildingwasdesignedforawindvelocityof360mph,a3psigexternalpressuredrop,plusmissileloading.Thedesignwindvelocitywasconverted toapressureequivalent bytheequations ofparagraph 6.3.4ofANSIA58.1.
I,
III-3.AEffectsofHihWaterLevelonStructures Question:
                                                                                                  ",IIATC l
Foreachsafety-related structure, 1.Describethewaterloadscons'idered inthedesignandtheextenttowhichdynamiceffectsduetofloodingwereconsidered.
ROCHESTER GAS AND ELECTRIC CORPORATION o 89 EAST AVENUE, ROCHESTER, N.Y. 14649 LEON D. WHITE. JR.                                                                 TELEPHONE VICE PRESII7ENT                                                          AREA CODE TIE 546.2700 I
2.Clarifythewaterlevelforeachloadcombination discussed inTopicIII-7.B.3.Explainhowthegroundwaterpressure, ontheem-beddedpartofthecontainment, wasconsidered.
November 14, 1979 Director of Nuclear Reactor Regulation Attention: Mr. Dennis L. Ziemann, Chief Operating Reactors Branch No. 2 U.S. Nuclear Regulatory Commission Washington, DC 20555 Subject,:                    Systematic Evaluation Program    Topics    III-2, III-3.A, III-7.B R. E. Ginna Nuclear Power    Plant Docket, No. 50-244


===Response===
==Dear Mr. Ziemann:==
Thehighestinstantaneous stillwaterlakelevelrecordedforLakeOntariowas250.2feetUSGS(FSARSection2.6.4).ThemaximumstillwaterlevelofLakeOntarioattheGinnasitewasestablished as250.78feetUSGSinAppendix2CoftheFSAR.Theprobablemaximumstillwater levelwasrevisedonMay10,1973to253.28feetUSGSorLSD1935datum.Thereasonsforthisrevisionandsubsequent additionofcapstonestothebreakwall wereexplained inourletterdatedNay15,1973toMr.DonaldJ.Skovholt, Assistant.
DirectorforOperating
: Reactors, USAEC.Also,ourletterofMay31,1973toMr:Skovholtdescribes additional floodprotection measures.
Theplantisprotected fromwinddrivenwavesbyabreak-waterwithatopelevation of261.0feet(initially constructed to254.0feet)andbythedischarge canalwhichrunsparalleltothelakeshore betweenthebreak-waterandtheplant.Designdetailsofthebreakwall arepresented inquestion3inSupplement ItotheTechnical 3
Supplement Accompanying Application foraFull-Term Operating license,datedDecember20,1973.Thegeneralplantgradeisaboutelevation 270feet,withtheexcep-tionoftheareabetweenthelakeandtheturbinebuildingwhichisatelevation 253feet.Becauseofthebreakwater, thedischarge canalorientation andtheelevation ofthegeneralplant,floodingisnotaproblemandtheplantstructures are,therefore, notdesignedforthedynamicaffectsofflooding.
Normalwaterloadsfromgroundwaterareconsidered inthedesignoftheplantstructures whicharesupported belowthegroundwatertable(elev.250'-0").
Ofthesafetyclassstructures, onlytheContainment, Auxiliary BuildingandScreenHousearesupported belowthegroundwatertable.ThewallsoftheAuxiliary Buildingweredesignedforalateralhydrostatic waterpressureandthebasematwasdesignedforahydrostatic upliftpressure.
TheScreenHousewasdesignedforafullhydrostatic,and upliftpressureassumingcompletede-wateringofthefacility.
TheContainment designprovidesfornobackfillagainstthecontainment wall.Assuchnolateralgroundwaterpressureontheembeddedpartofthecontainment wascon-sidered(FSARpage5.1.2-36-"AbsenceofBackfillAroundContainment"
).However,thebaseslabofthecontainment isdesignedtowithstand thefullhydrostatic headofwater,eguivalent to7.16psi(16.5ft.ofwater).
III-7.BDesinCodes,DesinCriteriaandLoadCombinations Question:
Foreachsafety-related structure (exceptthecontain-ment,shell),Listthecodesandstandards (including editiondate)usedfordesignandconstruction ofconcreteandsteelelements(containment internalstructures, auxiliary
: building, intermediate
: building, turbinebuilding, controlroom,batteryroom,diesel2.3.generator room).,Providetheloads,loadcombination andacceptance criteriaemployedforthedesign.Providethedesignand/oractualmaterialproperties (fyandfc)usedforsteelandconcreteelements.
Forconcrete, providetheagespecified andany'ad-mixturesused.Provideacopyofdesignspecifications usedfordesignandconstruction.
Providerepresentative stresslevel(compression, 1tensionandshear)atthecriticallocationofeachstructure (e.g.,atbaseofcontainment internalstructures) foreachoftheloadcombinations pro-videdinresponseto(2)above.(Forthisquestion, information atthebaseofthecontainment, shellisalsoneeded.)


===Response===
Enclosed please find our response to your                letter of August 1, 1979          in which you requested information on SEP                structural topics III-2, III-3.A and III-7.B.
1.Thecodesandstandards (including editiondate)usedfordesignandconstruction ofconcreteandsteelelementsaregiveninFSARSection5.1.1.5"Codesand2.Classifications",
contact us.
pages5.1.1-10through5.1.1.-16.
If there are any questions regarding this information, please Very  truly  yours, L. D. White,  Jr.
Thislistingisincludedasattachment.
Enclosures
IV.Thefollowing loadshavebeenconsidered inthestructural designofthesafety'relatedstructures.
                                                                                >>>iE0o9<                  '
A.DeadloadsB.Liveloads(uniformloads/sg.
 
ft.toallowforanyhungloadsfromfloorframingsystem,whichmayincludepiping,H&Vducts,electrical cabletrays,ceiling,etc.whereapplicable, and'alsosnowloadsforroof)C.Permanent.
N Kl'll5 IO KMIIR      l)MIKE'ILY Go  299 structure,'nclosure i) 'll->
equipment loadsD.SeismicloadsE.WindloadsThespecificloads,loadingcombinations, andacceptance criteriaforeachsafetyrelatedstructure arelistedbelow:(1)Containment ShellThedesignloadsaredescribed inSection5.1.2.3oftheFSAR.Thefundamental loadsforthecontainment structure aretabulated inTable5.1.2-4A.
III-2    Wind and Tornado Loads
Theloadcombinations forthecontainment structure aregiveninTable5.1.2-4I.
                                                                      ~
Theacceptance criteriaisdescribed intheFSARSection5.1.2.3undertheheadingsof"DesignStressCriteria" and"LoadCapacity."
l Question: For each safety related                                Riiue%59
(2)Containment InternalStructures a~Loads1.Operating FloorLiveLoad1000psfwithappro-priatedeadload(D.L.)2.Intermediate FloorLiveLoad200psfwithappro-priateD.L.3.AirFilterPlatformLiveLoad200psfwithappro-priateD.L.4.Foundation MatForupwardwaterpressure=1030psf.5.Loadgenerated bytheOperating BasisEarthquake (OBE).6.Loadgenerated bytheSafeShut-downEarthquake (SSE).7.Compartment pressuredifferential duetoaccident.
: 1. Describe the procedures to transform wind data into design pressure        and gust factors.
8.Equivalent staticloadgenerated bythereactiononthebrokenreactorcoolantsystempipeduringthepostulated break.9.OverheadCraneLiftedLoad=200Trolley=150BridgeGirder=100kVertical, lateralandlongitudinal loadsareusedasperAISCorN.Y.code,whichever governs.LoadCombinations 2.3.D+L+T=S0D+L+T+E=1.33S0D+L+T+P+Y+E=UorY0T=Thermaleffectsandloadsduring0normaloperating condition.
: 2. Provide design basis,        if any, for tornado loading including:
Loadgenerated bytheOperating BasisEarthquake (0.08g)at2%Edamping(maxm.acceleration
: a. translational wind speed
=0.19g)Loadg'enerated bytheSafeShut-downEarthquake (0.20g)at2%damping(maxm.acceleration
: b. radius of maximum rotational wind        speed
=0.47g)TherequiredsectionstrengthbasedonUltimateStrengthdesigndescribed inACI-1963.
: c. procedures to transform tornado data into design pressure.
DForStructural Steel,Yisthesectionstrengthbasedonyieldstrengthofmaterialusingelasticdesign.Pressureequivalent staticloadwithinthecompartment generated bypostulated break.Deadloadincluding anypermanent equipment loadsandhydrostatic loadsLiveloads.Y=Equivalent staticloadduetorpostulated highenergypipebreak.Forconcretestructure, SistherequiredsectionstrengthbasedonworkingstressdesignmethodasperACI1963.Forstructural steel,SistherequiredsectionstrengthbasedontheelasticdesignmethodsasperAISC."Specifications fortheDesign,Fabrication andErectionofStructural SteelforBuildings",
Response: The  original design of Ginna Station did not include tornado effects. Wind loads were applied as specified by Section C304-4 of the New York State Building Con-struction Code. This code is based on a'wind speed of 75 miles per hour at a 30 ft..height.          The wind speed is converted to a pressure loading and applied as shown in the Code tables'hich are included as Attachment, I.
adoptedApril17,1963.  
An  evaluation of the plant's capability to withstand tornado effects was performed in 1968. This evaluation, which is included in the FSAR as Appendix 14A, was based on a tangential wind velocity of 300 mph and an external vacuum of 3 psig. The portion of Appendix 14A 'that discusses the tornado effects on structures is provided as Attachment    II.
(3)DieselGenerator Buildina~b.LoadsRoofdeckingRoofing&insulation Fireprotection PipingMiscellaneous SnowloadLoadCombinations 2.5lbs/sqft10.0lbs/sqft7.5lbssq/ft,5.0lbssq/ft3.0lbssq/ft28.0lbs/sqft40.0lbs/sqftD+L+E=S(forroofbracingandcolumnfoundation)
Kle~~ m Immm                Mm Hl5
ForwallpanelsD+L+E=1.33SD+L+E=Uwhere,Loadgenerated bytheoperating basisearthquake (0.08g)at.5%damping(maximumacc.=0.13g);Loadgenerated bythesafeshut-downearthquake (0.2g)at5%damping(maximumacc.=0.32g).Forconcretestructure, Sistherequiredsectionstrengthbasedon'orking stressdesignmethodasperACI1963.Forstructural steel,Sistherequiredsection10 strengthbasedontheelasticdesignmethodsasperAISC."Specifications fortheDesign,Fabrication andErectionofStructural SteelforBuildings",
 
adoptedApril17,1963.U=TherequiredsectionstrengthbasedonUltimateStrengthdesigndescribed inACI-1963.
In  1976 an  addition  was made to the auxiliary building for  a standby  auxiliary feedwater system. The design criteria for the standby auxiliary feedwater pump build-ing were submitted to the NRC by letter dated May 20, 1977. Further information was supplied with our letter dated July 28, 1978. Staff approval of the standby auxiliary feedwater system, including the building, was issued by h
(4)ControlBuildina~Loads2.RoofConcreteslabSnowTrussRoof&Insulation Ceiling&Misc.Floorat,Elev.289'-6"250lbs/sqft40lbs/sqft15lbs/sqft8lbs/sqft15lbs/sqft3.D.L.+L.L.=500lbs/sqftFlooratElev.271'-0"D.L.+L.L.=400lbs/sqft,b.LoadCombinations ForRoofTrussD+L+E=S 2.Buildingcolumnsaredesignedbyapplyinglateralloadinthemidspanofthecolumneguivalent to(D+1/2L)z.20ginadditiontoverticaldeadloadandliveloadcarriedbythecolumn.There-sultingallowable stressesfromtheseismicloadareincreased by331/3%.3.Concretewallsaredesignedby-applyinglateralloadinthemidspanofthewallpaneleguivalent to(panelweight)z0.20g.Thedesignisbasedonworkingstressmethodwithoutincreaseinallow-ablestresses.
letter  dated August 24, 1979. This building addition was designed in accordance with the provisions of Reg. Guide 1.76. As indicated in Attachment III, the building was designed for a wind velocity of 360 mph, a 3 psig external pressure drop, plus missile loading.
E=Loadgenerated bytheSafeShut-downEarthquake (0.20g).(5)AuxiliarBuildina~Loads1.RoofRoofing6lbs/sq.ft.Insulation anddecking7lbs/sq.ft.Misc.Snowloads7lbs/sg.ft.40lbs/sq.ft.12 Foundation a)Foundation matforupwardwaterpressure=1000psfb)Sumpbottomforupward'water pressure=2250psfc)Wallsbelowgrade(1)Aboveel.250'-0"forequivalent fluidpressure504/sqft/ftofheight'I(2)Belowel.250'-0"forequivalent fluidpressurel805/sqft/ftofheight(3)Intermediate FloorLiveload220psfwithappropriate D.L.(4)Operating FloorLiveload200psfwithappropriate D.L.(5)CraneLoadsLiftedload80Trolleyweight14Cranebridge28.8Lateral,longitudinal andverticalloadsincreased by25%toincludeeffectofimpactandbraking.13 b.LoadCombinations D+L=SD+L+WorE=1.33S(6)ScreenHouseBelowGradeTheentirescreenhouse-service waterbuildingisfoundedinoronbedrockwiththeexception ofthebasementoftheelectricswitchgear por-tionwhichisfoundedapproximately fourfeetabovebedrock.Sincethebuildingisfoundedinbedrockthebasementwillnot.realizeanyspectralacceleration andtheseismicloadingisequivalent, tothegroundmotionof0.08gand0.20g.Thebasementisdesignedtobedewatered.
The design wind velocity was converted to a pressure equivalent by the equations of paragraph 6.3.4 of ANSI A58.1.
Thefullheight,ofthewallisdesignedforanexternalhydrostatic pressureplusaseismicloadequaltoapercentage ofthedeadloadofthewallandthehydrostatic pressure.
 
Fortheportionofthewallbelowgradeandabovebed-rockanactiveearthpressurebasedonasaturated soilweightisapplied.Internalwalls,suchaspumpbafflesandthewingwallsbetweenthetraveling screensweredesignedforafullheighthydrostatic pressureoneithersideplusaseismicloadduetothewatermovementduringaseismicevent.
III-3.A Effects of    Hi h Water Level on Structures Question: For each safety-related structure,
AboveGrade1)Designloadings:
: 1. Describe the water loads cons'idered  in the design and  the extent to which dynamic effects due to flooding were considered.
a)DeadLoads1)Built-uproof14psf2)Pipinghungfromroof10psf3)Sidingb)Liveloads1)Snowloadtoroof(NewYorkStateBldg.iCodePara.C-304-5),5psf40pfs2)Windloada)Walls(SBCPara.304-4) 20pfsb)Roof(SBCPara.304-5)Down5pfsUp17pfs3)Craneloads(inc-live, 20,0005deadScimpact)Isupportpointsa)Lateraltorunway20%b)Longitudinal torunway10%c)Seismicloadings4,000I2,00081)0.08ggroundmotion51.33workingstress15 2)0.20g.ground motionIyieldstress2)Designloadingcombinations foranalysis:
: 2. Clarify the water level for each load combination discussed  in Topic III-7.B.
a)Deadloads+snowload+craneloadIworkingstressb)c)d)e)Deadload+snowload+craneload+windloadI1.33timesworkingstressDeadload+snowload+craneload+0.08gvert.seismic+0.08gE-Whoriz.seismic91.33workingstressDeadload+snowload+craneload+0.08gvert.seisic+0.08gN-Shoriz.seismicI1.33workingstressDeadload+snowload+craneload+0.20gvert.seismic+0.20gE-Whoriz.seismic9yieldstressf)Deadload+snowload+craneload+0.20gvert.seismic+0.20gN-Shorizontal seismicIyieldstressTheconcrete, reinforcing steelandstructural steelrequirements areaslistedbelow.16 0
: 3. Explain  how the ground water pressure, on the em-bedded part of the containment, was considered.
Theminimumultimatecompressive strengthusedfordesigning concretestructures isasfollows:1.Containment Shell-5000psiin28days2.AllOtherStructures
Response: The highest instantaneous still water lake level recorded for Lake Ontario was 250.2 feet USGS (FSAR Section 2.6.4).
-3000psiin28daysAllstructural concreteisconsidered subjecttopotentially destructive exposureandcon-tainsairinamountsconforming withTable304(b)ofACI301.Anairentraining ad-mixturewasusedconforming to"Specifications forAirEntraining Admixture forConcrete",
The maximum  still water level of Lake Ontario at the Ginna site was established as 250.78 feet USGS in Appendix 2C of the FSAR. The probable maximum stillwater level was revised on May 10, 1973 to 253.28 feet USGS or LSD 1935 datum. The reasons for this revision and subsequent addition of cap stones to the breakwall were explained in our letter dated Nay 15, 1973 to Mr. Donald J.
ASTNC260-63T.Awaterreducingdensifier wasaddedtoallstructural concretewitharequiredultimatecompressive strengthequaltoorgreaterthan3000psiat28days.(FSARpage5.1.2-70a)
Skovholt, Assistant. Director for Operating Reactors, USAEC. Also, our letter of May 31, 1973 to Mr: Skovholt describes additional flood protection measures.
The  plant is protected from wind driven waves by a break-water with a top elevation of 261.0 feet (initially constructed to 254.0 feet) and by the discharge canal which runs parallel to the lakeshore between the break-water and the plant. Design details of the breakwall are presented in question 3 in Supplement I to the Technical 3
 
Supplement Accompanying  Application for  a  Full-Term Operating license, dated December 20, 1973. The general plant grade is about elevation 270 feet, with the excep-tion of the area between the lake and the turbine building which is at elevation 253 feet. Because of the breakwater, the discharge canal orientation and the elevation of the general plant, flooding is not a problem and the plant structures are, therefore, not designed for the dynamic affects of flooding.
Normal water loads from ground water are considered    in the design of the plant structures which are supported below the ground water table (elev. 250'-0").      Of the safety class structures, only the Containment, Auxiliary Building and Screen House are supported below the ground water table. The walls of the Auxiliary Building were designed for a lateral hydrostatic water pressure and the base mat was designed for a hydrostatic uplift pressure. The Screen House was designed  for  a full hydrostatic,and  uplift pressure assuming complete de-watering of the  facility.
The Containment design provides  for no backfill against the containment wall. As such no lateral ground water pressure on the embedded part of the containment was con-sidered (FSAR page 5.1.2 "Absence of Backfill Around Containment" ). However, the base slab of the containment is designed to withstand the full hydrostatic head of water, eguivalent to 7.16 psi (16.5 ft. of water).
 
III-7.B  Desi n Codes, Desi n    Criteria and Load Combinations Question: For each safety-related structure (except the contain-ment, shell),
List the codes and standards (including edition date) used for design and construction of concrete and steel elements (containment internal structures, auxiliary building, intermediate building, turbine building, control room, battery room, diesel generator room).,
: 2. Provide the loads, load combination and acceptance criteria employed for the design.
: 3. Provide the design and/or actual material properties (fy and fc) used for steel and concrete elements.
For concrete,  provide the  age specified and any 'ad-mixtures used.
Provide  a copy  of design specifications  used for design and construction.
Provide representative    stress level (compression, tension and shear) at the critical location of 1
each  structure (e.g., at base of containment internal structures) for each of the load combinations pro-vided in response to (2) above. (For this question, information at the base of the containment, shell is also needed.)
 
Response: 1. The codes  and standards    (including edition date) used for design and construction of concrete and steel elements are given in FSAR Section 5.1.1.5 "Codes and Classifications", pages 5.1.1-10 through 5.1.1.-16.
This  listing is  included as attachment. IV.
: 2. The following loads have been considered in the structural design of the safety 'related structures.
A. Dead loads B. Live loads    (uniform loads/sg. ft. to allow for any hung loads from floor framing system, which may include piping, H&V  ducts, electrical cable trays, ceiling, etc. where applicable, and'also  snow loads for roof)
C. Permanent. equipment loads D. Seismic loads E. Wind loads The  specific loads, loading combinations, and acceptance criteria for each safety related structure are listed below:
(1) Containment Shell The  design loads are described in Section 5.1.2.3 of the FSAR. The fundamental loads for the containment structure are tabulated in Table 5.1.2-4A.
 
The  load combinations for the containment structure are given in Table 5.1.2-4I.
The acceptance    criteria is  described in the FSAR  Section 5.1.2.3 under the headings of "Design Stress Criteria" and "Load Capacity."
(2) Containment Internal Structures a ~   Loads
: 1. Operating Floor Live Load 1000 psf with appro-priate dead load (D.L.)
: 2. Intermediate Floor Live Load 200 psf with appro-priate D.L.
: 3. Air Filter Platform Live Load 200 psf with appro-priate D.L.
: 4. Foundation Mat For upward water pressure  =
1030  psf.
: 5. Load generated  by the Operating Basis Earthquake  (OBE).
: 6. Load generated by the Safe Shut-down Earthquake  (SSE).
: 7. Compartment pressure  differential due  to accident.
: 8. Equivalent static load generated by the reaction on the broken reactor coolant system pipe during the postulated break.
: 9. Overhead Crane Lifted Load      = 200 Trolley          = 150 Bridge Girder    = 100 k Vertical, lateral    and longitudinal loads are used as per AISC or N.Y.
code, whichever governs.
Load Combinations D+ L+   T 0
                  = S
: 2. D + L + T0 + E = 1.33S
: 3. D+L+T0 +P+           Y   +E =Uor      Y T0 = Thermal  effects  and loads  during normal operating condition.
Load generated by the Operating Basis Earthquake    (0.08g) at  2%
damping (maxm. acceleration   = 0.19g)
E    Load g'enerated by the Safe Shut-down Earthquake    (0.20g) at  2%
damping (maxm. acceleration = 0.47g)
The required section strength based on Ultimate Strength design described    in  ACI-1963.
 
For Structural Steel,   Y is the section strength based on yield strength of material using elastic design.
Pressure  equivalent static load within the compartment generated by postulated break.
D    Dead load including any permanent equipment loads and hydrostatic loads Live loads.
Y r = Equivalent static load due to postulated high energy pipe break.
For concrete structure, S is the required section strength based on working stress design method as  per ACI 1963. For structural steel, S is the required section strength based on the elastic design methods as per AISC.
      "Specifications for the Design, Fabrication and Erection of Structural Steel for Buildings",
adopted  April 17, 1963.
 
(3) Diesel Generator Buildin a ~ Loads Roof decking                  2.5 lbs/sq  ft Roofing  & insulation       10.0 lbs/sq  ft Fire protection              7.5 lbs sq/ft, Piping                        5.0 lbs  sq/ft Miscellaneous                3.0  lbs sq/ft 28.0 lbs/sq  ft Snow  load                  40.0 lbs/sq  ft
: b. Load Combinations D + L + E   = S (for roof bracing  and column foundation)
For wall panels D + L + E =   1.33S D + L + E   = U where, Load generated    by the operating basis earthquake    (0.08g) at. 5%
damping (maximum acc. = 0.13g);
Load generated by the safe shut-down earthquake    (0.2g) at 5%
damping (maximum acc. = 0.32g).
For concrete structure, S is the required section strength based on'orking stress design method as  per ACI 1963. For structural steel, S is the required section 10
 
strength based  on the  elastic design methods as per AISC.
                    "Specifications for the Design, Fabrication and Erection of Structural Steel for Buildings",
adopted  April 17, 1963.
U = The  required section strength based on Ultimate Strength design described in ACI-1963.
(4) Control Buildin a ~ Loads Roof Concrete slab            250  lbs/sq ft Snow                      40  lbs/sq ft Truss                      15  lbs/sq ft Roof  & Insulation         8  lbs/sq ft Ceiling & Misc.           15  lbs/sq ft
: 2. Floor at, Elev. 289'-6" D.L. + L.L. = 500 lbs/sq ft
: 3. Floor at Elev. 271'-0" D.L. + L.L. = 400 lbs/sq ft,
: b. Load Combinations For Roof Truss D + L + E   = S
: 2. Building columns are designed by applying lateral load in the mid span of the column eguivalent to (D + 1/2 L) z .20g  in addition to vertical dead load and live load carried by the column. The re-sulting allowable stresses from the seismic load are increased by 33 1/3%.
: 3. Concrete walls are designed by-applying lateral load in the mid span of the wall panel eguivalent to (panel weight) z 0.20g. The design  is based on working stress method  without increase in allow-able stresses.
E   = Load  generated by the Safe Shut-down Earthquake  (0.20g).
(5) Auxiliar Buildin a ~ Loads
: 1. Roof Roofing                  6 lbs/sq. ft.
Insulation   and decking 7  lbs/sq. ft.
Misc.                     7 lbs/sg. ft.
Snow  loads            40  lbs/sq. ft.
12
 
Foundation a)   Foundation mat    for  upward water pressure  = 1000  psf b)   Sump  bottom  for upward'water pressure   = 2250  psf c)   Walls below grade (1)   Above  el. 250'-0" for equivalent  fluid pressure
      'I 50  4/sq  ft/ft of height (2)   Below  el. 250'-0" for equivalent  fluid pressure 80  5/sq  ft/ft        l of height (3)   Intermediate Floor Liveload  220  psf with appropriate D.L.
(4)   Operating Floor Live load 200 psf with appropriate D.L.
(5)   Crane Loads Lifted load        80 Trolley weight      14 Crane bridge        28.8 Lateral, longitudinal   and vertical  loads increased by  25% to include effect of impact and braking.
13
: b. Load Combinations D+ L = S D + L + W  or E  =   1.33S (6) Screen House Below Grade The  entire screenhouse-service water building is founded in or on bedrock with the exception of the basement of the electric switchgear por-tion which is founded approximately four feet above bedrock. Since the building is founded in bedrock the basement will not. realize any spectral acceleration and the seismic loading is equivalent, to the ground motion of 0.08g and 0.20g.
The basement  is  designed to be dewatered. The full height, of the wall is designed for an external hydrostatic pressure plus a seismic load equal to a percentage of the dead load of the wall and the hydrostatic pressure.       For the portion of the wall below grade and above bed-rock an active earth pressure based on a saturated soil weight is applied.
Internal walls, such as pump baffles and the wing walls between the traveling screens were designed for a full height hydrostatic pressure on either side plus a seismic load due to the water movement during      a  seismic event.
 
Above Grade
: 1)   Design loadings:
a)   Dead Loads
: 1) Built-up roof              14 psf
: 2)   Piping hung  from roof 10 psf
: 3)   Siding                    ,5 psf b)   Live loads
: 1) Snow  load to roof        40  pfs (New  York State Bldg.
i Code  Para. C-304-5)
: 2) Wind load a)   Walls (SBC  Para.304-4) 20  pfs b)   Roof (SBC Para. 304-5)
Down  5  pfs Up    17  pfs
: 3)   Crane loads    (inc-live, 20,0005 dead  Sc impact) I support points a)   Lateral to runway  20%           4,000I b)   Longitudinal to runway  10%           2,0008 c)   Seismic loadings
: 1)   0.08g ground motion 5 1.33 working stress 15
: 2)   0.20g.ground motion        I yield stress
: 2) Design loading combinations for analysis:
a)       Dead loads + snow    load    +   crane load  I working stress b)       Dead  load  + snow load    +   crane load  + wind load  I 1.33      times working stress c)      Dead  load  + snow load    +   crane load  + 0.08g  vert. seismic +
0.08g  E-W  horiz. seismic 9 1.33 working stress d)      Dead  load  + snow load    +   crane load
                  + 0.08g  vert. seisic   +   0.08g N-S horiz. seismic    I 1.33    working stress e)      Dead load    + snow  load  +   crane load
                  + 0.20g  vert. seismic + 0.20g        E-W horiz. seismic 9 yield stress f)     Dead  load  + snow  load  +   crane load
                  + 0.20g  vert. seismic     +   0.20g N-S I
horizontal seismic yield stress The concrete, reinforcing steel and structural steel requirements are as    listed  below.
16
 
0 The minimum    ultimate compressive strength used for designing concrete structures is as follows:
: 1. Containment Shell 5000 psi in 28 days
: 2. All Other Structures - 3000 psi in 28 days All structural    concrete  is considered subject to potentially destructive exposure and con-tains air in amounts conforming with Table 304 (b) of ACI 301. An air entraining ad-mixture was used conforming to "Specifications for Air Entraining Admixture for Concrete",
ASTN  C  260-63T. A water reducing densifier was added  to all structural concrete with a required ultimate compressive strength equal to or greater than 3000 psi at 28 days. (FSAR page 5.1.2-70a)
Reinforcement:
Reinforcement:
Theconcretereinforcement.
The  concrete reinforcement. used is deformed bar of intermediate grade billet-steel con-forming to the requirements of "Specifica-tion for Billet-Steel     Bars for  Concrete Re-inforcement",   ASTN A  15-64, with deformations conforming to "Deformed Bars      for  Concrete Reinforcement",     ASTN A  305-56T. Special large size concrete reinforcing bars are deformed bars of intermediate grade billet-steel con-forming to "Specifications for Special Large 17
usedisdeformedbarofintermediate gradebillet-steel con-formingtotherequirements of"Specifica-tionforBillet-Steel BarsforConcreteRe-inforcement",
 
ASTNA15-64,withdeformations conforming to"Deformed BarsforConcreteReinforcement",
M 0
ASTNA305-56T.Speciallargesizeconcretereinforcing barsaredeformedbarsofintermediate gradebillet-steel con-formingto"Specifications forSpecialLarge17 M0 SizeDeformedBillet-Steel BarsforConcreteReinforcement",
 
ASTMA408-64.Reinforcing steelconforming tothesespecifications hasatensilestrengthof70,000psito90,000psiandaminimumyieldpointof40,000psi.Theprincipal mildsteelreinforcement usedinthevicinityofthelargeopening(i.e.,personnel lockandeguipment accesshatch)hasa60,000psiyieldstress.c.Structural Steel:Allstructural steelusedintheworkandnot,otherwise designated onthedrawingconformed to"Specification forStructural Steel(Tentative)",
Size Deformed  Billet-Steel Bars  for Concrete Reinforcement", ASTM A  408-64. Reinforcing steel conforming to these specifications has a tensile strength of 70,000 psi to 90,000 psi and a minimum yield point of 40,000 psi.
ASTNA36-63T,with36,000psiminimumyieldstrength.
The principal mild steel reinforcement used in the vicinity of the large opening (i.e.,
Thefollowing specifications forstructural steelandconcretewereusedfor,construction andareincludedasAttachment V.a.b.Technical Specifications forFurnishing, Fabricating andErectingStructural Steel,Grating,StairTreads,andHandRail.Technical Specifications forStructural Concrete(includes reinforcement,)
personnel lock and eguipment access hatch) has a 60,000 psi yield stress.
withAddendumNo.1toAddendumNo.9.  
: c. Structural Steel:
All structural steel used in the work and not, otherwise designated on the drawing conformed to "Specification for Structural Steel (Tentative)", ASTN A  36-63T, with 36,000 psi minimum  yield strength.
The  following specifications for structural steel and concrete were used    for,construction and are included as Attachment V.
: a. Technical Specifications for Furnishing, Fabricating and Erecting Structural Steel, Grating, Stair Treads, and Hand Rail.
: b. Technical Specifications for Structural Concrete (includes reinforcement,) with Addendum No. 1 to Addendum No. 9.
 
The  representative stress levels in the containment shell. can, be found in Appendix 5D of the FSAR.
The stresses for the 48 load combinations identified in Table 5.1.2-4I are provided as stress resultants and stress couples in the meridional and the hoop direction, including meridional shear and radial displacement s    .
Unit stresses      in the different structural  com-ponents    of the shell are described in the      FSAR as shown below:
(1) Stresses      in the hinge tension bars  are shown on page    5.1.2-37.
(2) Stresses in the liner knuckle plate are described on page=5.1.2-37A.
(3) Stresses in the elastomer bearing pads are described on page 5.1.2-37B through 5.1.2-41.
(4) Radial shear in the shell, see page 5.1.2-42 through 5.1.2-43.
(5) Longitudinal shears      in the shell, see page  5.1.2-44.
(6) Horizontal shears in the shell, see page 5.1.2-45 through 5.1.2-46.
(7) Tendon anchorage stresses, see page 5.1.2-46a through 5.1.2-46d.
(8) Liner stresses, see page 5.1.2-46e through 5.1.2-5la.
19
 
(9) Longitudinal liner shear stresses,    see page 5.1.2-51b through 5.1.2-51g.
(10) Stresses  in the concrete  and  reinforcing steel during the pressure test, see Table B on page  5.1.2-51h.
(11) Large openings,  see page  5.1.2-62, and the Third Supplement of the    FSAR  "Design of Large Opening Reinforcement    for Containment, Vessel."
20
 
  'I r'
 
N gQ X~'<< Q<<~+                                C.        D c.
Structural Requirements C 304-4        Wind Loads (833 4)
Minimum wind loads shall be in conformity with tables C 304-4a and C 304-4b, and shall be applied normal to the surface. These loads are based on a design wind velocity of 75 miles per hour at a height of 30 feet above grade level. Minimum wind loads on signs shall be in conformity with generally ac-cepted standards.
TABLE C 304.4a. (Ill.633) WIND LOADS: WALLS, EAVES< CORNICES< TOWERS< MASTS AND CHlhlNEYS In pounds por srtuaro foot Eaves            Towers, At height above grade              Wallst  1      and            masts and in feet .                          cornicess        chimneyss 501    to  600~                        34            68                60 401    to  500                        33            66                58 301    to  400                        32            64                56 201    lo  300                        30            60                53 101 to      200                        28            56                49 61 to      100                        24            48                42 41 to        60                      21            42                37 26 to        40                      18            36                32 0 to 25                            15            30                26 1 exterior walls shall bo capabto of withstanding wind load on both the fntcdor and exterior surfaces, acting non.simultaneously.
        -"Load    acting upward.
3 For heights above grade greater than 600 feet, add      1 psf to load for wane for each    interval or part of interval of 200 feet above 600 feet; for eaves snd, cornices. and towers, masts and chimneys, corresponding loads aro in proper lion to those (or walls.
4  Tabular values sre for square snd rectangular structures. For structures hexa.
gonal or octagonal in plan, use prolected aros snd multiply tabufar values by 0.6: for structures round or elnpiicsl in plan. use proiected ares and multiply values by 0.6.
C304-5 Overturning Force and Moment Due to Wind (833.5) a          The overturning force shall be the wind load.
The wind load shall be the load set forth in table C 304-4a, and shall be applied only to the windward vertical surface above the horizontal plane under consideration, and to the rise of the roof. The re-sisting force shat( be the dead load of the structure above the horizontal ptane under consideration, plus the strength of material and fastenings estabtishing b
continuity with the structure below.
The moments of stability and overturning shall be computed about the leeward edge of the horizon-tal plane under consideration.
93
 
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Structural Requirements TABLE C 304.4b. (IV.633) VtfMD LOADS: ROOFS ln pounds por square foot Mean elevation of roof above grade level in feet Direction of load>
20'lope 0'o        30'ver from horizontafg 3060'0'o to" 60'01 to 6003    Downward          8        8        8 to 24        24 Upward            29    29 to 24              24    24 401 to 500        Downward          8        8        8 to 23        23 Upward            28    28 to 23              23    23 301 to 400        Downward          7        7        7 to 22        22 Upward            27    27 to 22              22    22 201 to 300        Downward          7        7        7 to 21        21 Upward            25    25 to 21              21    21 101 to 200        Downward          6        6        Gto20          20 Upward            24    24 to 20              20    20 61 to 100      Downward          5        5        5to17            17 Upward            20    20 to 17              17      17 36 to    60    Downward          5        5        5 to 15        15 Upward            19    19 to 15              15    15 21  to  35    Downward          5        5        5 to 14        14 Upward            17    17 to 14              14    14 0 to    20    Downward          5        5        5to11          11 Upward            14    14 to 11              11    11 1  Downward snd upward loads act non slmultsneousfy.
            "For    sfopes between 20 and  30'llh  wind acting upward, snd between 60'ith    wind downward, compule loads by straight line Interpo-30'nd lation.
3 For heighls above grade gresler thsri 600 feel, sdd 1 psf to upward load lor  0'o    20'lope for each Interval or pari of Interval of 200 feet above feel; lor upward loads on other slopes, snd downward loads on sll          '00 slopes, corresponding loads are in proportion lo those for upward load for 0 to 20'lope.
c        The moment of stability of the structure above the horizontal plane under consideration shall be not less than 1'/2 times the overturning moment due to wind.
C 304-6    Sliding Force Due to Vlind (833.6)
The sliding force due to wind load, equal to the overturning force, determined in conformity with section C.304-5, shall be resisted by the dead load of the structure above the horizontal plane under consideration, by anchors, and where applicable, by soil friction, providing a total resisting force equal to not less than 1t/2 times the sliding force. Anchors used to resist overturning may also provide resist-ance to sliding.
94
: 3.      TORNADO EFFECTS ON STRUCTURES 3.1        GENERIC All structures    have been designed  for wind loads  in accordance with the requirements of the State of New York  State Building Construction Code. The wind loads tabulated in this code are based on a design wind velocity of 75 miles per hour at a height of 30 feet above grade level. The stresses resulting from these loads were considered on the basis of a working strength design approach.
'For purposes    of this study the design of all critical structures has been checked on the basis of a limiting load factor approach wherein the loads utilized to determine the required limiting capacity of any structural element are computed as follows:
C  =  (1.00 + 0.05)D + 1.0  W  + 1.0 P Symbols used    in this equation are identified    as follows:
C      required load capacity of section D    dead    load of structure wind loads based upon 300 mph tangential wind velocity W
t P    pressure load based upon an internal pressure 3 psi higher t      than the external pressure.
3.2        REACTOR CONTAINfENT Although tornado loads were not considered in the original design, this structure is capable of resisting the full strength tornado loads.
14A-4
 
3.3        AUXILIARY BUILDING Although tornado loads were not considered in the original design, this structure up to and including the Operating Floor (elev. 271"-0") is capable of resisting tornado loads. The siding on superstructure would blow outward, thus relieving the pressure and wind load. Components and systems on the operating floor and above are susceptible to impact by falling debris and potential missiles. The equipment, on the auxiliary building operating floor, required to maintain the plant in a hot shutdown condition is as follows:
a)    Boric Acid Tanks,  Pumps  and  Filter; and b)      480V Switchgear  Bus 14 The equipment  in  a) is surrounded by a    radiological shield wall as shown in Figure 14A-1. This wall offers significant lateral protection against pot;ential missiles. Furthermore, the two tanks and pump are redundant. Hence, there is reasonable assurance that there will be no loss of boration function. More details are given in Section 4.2.1  Boration System.
Damage  to Bus 14  will not  cause loss  of power supply since an independent and redundant bus (Bus 16) is provided on the intermediate floor of the auxiliary building. This floor, as previously mentioned, will not be exposed to the weather.      More details are given in Section 4.4.
In addition, the Spent Fuel Pit      has been evaluated. Potential missiles may  puncture the spent fuel pit liner but will not penetrate through the concrete walls or base causing gross leakage of water.
3.4        INTERMEDIATE BUILDING This structure, as shown in Figure 14A-2, is significantly confined by other buildings, i.e., Service Building, Turbine Building, Reactor Containment and Auxiliary Building. Consequently, a direct exposure 14A-5
 
to  a  tornado funnel is extremely remote. Due to the relative vacuum which might be created by a tornado outside of the intermediate building lateral walls may blow outward. This will relieve the pressure differential and prevent gross failure of the structural steel framing, columns and floors. Therefore, the two floors which house critical    equipment, i.e., floors  at elevations 253'" and 278'",
are afforded significant shielding by the adjoining structures and higher floor/roof elevations.
Th'e  critical  components  in this structure consist of the following:
a)      On  floor elevation 253'": two motor driven      and one turbine driven auxiliary feedwater pumps; and On  floor elevation  278'":                r the cross connection on main steam and feedwater lines to the two steam generators.
As  previously mentioned, no damage is anticipated to the equipment located on these two floors. More details are given in Section 4.1.
3.5          DIESEL GENERATOR ANNEX The    availability of on-site diesel    power was reviewed on the basis of the assumption that the tornado could      cause loss of outside power.
Siding, windows, doors      and ventilation  openings would blow outward thus relieving the pressure loading. Damage to the roof might result    if  the differential pressure is not relieved in time. Two redundant diesel generators are provided. No physical damage to the diesels is anticipated.      Furthermore, the physical separation between them is such that one missile would not be able to impact against both diesel generators, as shown in Figure 14A-3. More details are given in Section 4.4. The con'elusion has been drawn that emergency power supply is reasonably assured.
14A-6
 
3.6        SCREENHOUS E Siding, windows, doors    and  ventilation  openings would blow outward, thus relieving the pressure loading. No structure collapse        is expected. The critical equipment housed in the screenhouse        is represented by:
a)      four service water  pumps; and b)      480 V Switchgear-Buses  17 and  18.
The  four service water pumps are redundant and sufficient physical separation exists between them to make extremely unlikely the failure of all four pumps from the same tornado effect, as shown in Figure 14A-4.
Service water pumps lA and lC are energized from Bus 18 and service water pumps lB and 1D are energized from Bus 17. Cross-tie between the two buses    is available.
The two buses    are located in the screenhouse and are physically separated. Hence, there is reasonable assurance that at least one service water pump-bus combination will operate properly.
.More details are given in Section 4.4.
3.7        CONTROL ROOM No  gross  failure of this structure is anticipated. The only wall directly exposed is the East wall.'he siding of this wall would blow outward relieving the pressure differential and leaving the interior exposed to the weather. The same would be true for windows, doors and ventilation openings.
Local controls for the equipment required for maintaining the plant in a hot shutdown condition have been provided as a backup to the controls available in the control room. Therefore, there is reasonable assurance that controls for the critical components will be available.
14A-7
: 3. 8.      SERVICE BUiLDING The    status of this building is similar to that of the auxiliary building, i.e., the siding on superstructure above elevation 271'ould blow outward, thus relieving the pressure and wind loads. The components which might be affected by tornado are the two condensate storage tanks. There is reasonable assurance that feedwater supply will be maintained because of the available redundancy and of the fact that 2/3 of the tank volume is below grade.
3.9          CABLE TUNNELS The    cable tunnels are located underground and are capable of withstanding tornado loads.
14A-8
 
4.6    Tornado Loads
                                                                  ~        lkc4lqFww
                                                                &#xc3;<<> ~4xXwoc. Anne
                                                                            ~e~w~Q K
be I/
Tornado Design      Criteria The Pumphouse      will contain safety    class equipment (Seismic Class 1)
      ,,and will therefore be designed to        withstand short term tornado loadings, including the impact of.        tornado-generated missiles. Tne following tornadc design criteria shall          be used:
r
: a.    %Iaximum  rotational wind velocity of 290 mph, together with translational wind velocity of 70 'mph giving total design velocity of 360 mph.
Radius of maximum rotational velocity is cdnsidered to be 150              ft; Pressures and suction forces due to the 360 mph wind and all other design parameters shall be determined in accordance with ANSI-A58.1  1972.
      'b.      External pressure drop is considered to be        3  psig.
c~    A  missile equivalent to      a utility pole  35  ft. long,  14  inches in diameter, weighing,50 pcf      and  traveling at  130  ft./sec. within a height of 17 ft. above ground.
: d. A  missile equivalent to a two ton automobile traveling at 150              ft./
sec. and impacting within a height of 22          ft. above ground.
: e. A 12,  ft. long 4" x 12" wooden plank traveling at 260          ft./sec. and impacting end-on at any      height.
f.. A  missile equivalent to a 3 inch diameter Schedule 40 pipe,              10  ft.
long, traveling at 160 ft./sec. and impacting end-on within              a height of 48 ft. above ground.
: g. A  missile equivalent to a 6 inch diameter Schedule 40 pipe,              15  ft.
long, traveling at 150 ft./sec. and imoacting end-on within              a height of'0 ft. above ground.
A  missile equivalent to a 12 inch diameter Schedule 40 pipe, 15                ft.
long, traveling at 130 ft./sec. and impacting end-on within a height of 14 ft. above ground.
4.6.2 Tornado Load Combinations Each  of the above missile loading cases shall be investigated to determine which one causes the most severe loading of the Pumphouse, or of individual Pumphouse components. The most severe missile load shall be combined with the tornado wind load for the structural design, of the Pumphouse.
clLOVHT ASSOCIATES, liC.
 
The design,  materials, fabrication; inspection, and proof testing of the containment vessel complies with the applicable parts of the following:
ASME  Boiler  and Pressure  Vessel Code, Section  III  Nuclear Vessels, Section VIII  Unfired Pressure Vessels, Section IX  Welding Qualifications.
: 2. Building    Code Requirements  for Reinforced  Concrete (ACI 318-
: 63) .
: 3. American    Institute of Steel Construction Specifications:
a)    "Specifications for the Design, Fabrication and Erection of Structural Steel for Buildings," adopted April 17, 1963.
b)    "Code  of Standard Practice for Steel Buildings  and Bridges,"
revised February 20, 1963.
: 4. USAS N  6.2    1965, "Safety Standard for Design, Fabrication and Maintenance of Steel Containment Structures for Stationary Nuclear Power  Reactors."
: 5.  'CI    301-66, "Specifications  for Structural Concrete for Buildings"
: 6. ASTM C  150-64, "Specifications    for Portland Cement"
: 7. State of    New York Department of Public Works Specification 5.1.1-10
: 8. ASTM C  260-63T,  "Specifications for Air-Entrained Admixtures .for Concrete"
: 9. ASTM A  15-64T, "Specifications    for Billet-Steel Bars for Concrete Reinforcement"
: 10. ASTM A  305-56T,  "Specificat  ons  for Minimum Requirements  for Deformation of Deformed Bars    for Concrete Reinforcement" ll. ASTM A408-64T,  "Specifications for Special Large Size    Deformed Billet-Steel  Bars for Concrete Reinforcement"
: 12. ASTM C  94-65, "Recommended t
Practice  for Winter Concreting"
: 13. ACI 306-66, "Recommended  Practice for Winter Concreting"
: 14. ACI 605-59, "Recommended  Practive for 1iot Weather Goner'eting"
: 15. ASTM A  421-65, "Specifications    for Uncoated Stress-Relieved Wire for Prestressed Concrete"
: 16. ASTM C29-60, "Method of Test    for Unit  Weight of Aggregate"
: 17. ASTM C  40-66, "Method of Test  for Organic Impurities in  Sands for Concrete"
: 18. ASTM C  127-59, "Method of Test    for Specific Gravity  and Absorption of Coarse Aggregate"
: 19. ASTM C  128-59, "Method of Test    for Specific Gravity  and Absorption of Fine Aggregate"
 
l I
: 20. ASTM C  136-63, "Method of Test  for  Sieve or Screen Analysis of Fine and Coarse Aggregate"
: 21. ASTM C  39-64, "Method of Test  for  Compressive Strength  of Molded Concrete Cylinders"
: 22. ASTN C  192-66, "Method of Making and Curing Concrete Compression and Flexure Test Specimens in the Laboratory"
: 23. ASTM A  15-62T, "Specifications  for Billet-Steel  Bars for Concrete Reinforcement"
: 24. ASTM  A408-64,  "Specifications, for Special Large Sized  Deformed Billet-Steel Bars for Concrete Reinforcement"
: 25. ASTM A  432-64, "Specification for Deformed Billet-Steel Bars for Concrete Reinforcement with 60,000 psi Minimum Yield Strength"
: 26. ASTM C  31-65, "Method of Making and Curing Concrete Compression and Flexure Test Specimens in the Field",
: 27. ASTM  C33-64,  "Specifications for Concrete Aggregates"
: 28. ASTM  C42-64, "Methods  of Securing, Preparing, and Testing Specimens from Hardened Concrete for Compressive and Flexural Strengths"
: 29. ASTM C 131-64T, "Method of Test for Abrasion of Coarse Aggregate by Use of the Los Angeles Machine" 5.1.1-12
: 30. ASTM C  138-63, "Method of Test for Weight per Cubic Foot, Yield, and Air Content (Gravimetric) of Concrete"
: 31. ASTM C  143-58, "Method of Test  for  Slump of Portland  Cement  Concrete"
: 32. ASTM C  150-65, "Specifications  for Portland  Cement"
: 33. ASTM C  172-54, "Method of Sampling Fresh Concrete"
: 34. ASTM C  231-62, "Method of Test for    Air Content of Freshly  Mixed Concrete by the Pressure Method"
: 35. ASTM C  260-65T, "Specifications for Air-Entrained Admixtures"
: 36. ASTM C  494-62T, "Specifications  for  Chemical Admixtures  for Concrete"
: 37. ASTM C  173-58, "Method of Test for    Air Content of Freshly  Mixed Concrete by the Volumetric Method"
: 38. ACX 214-57, "Recommended Practice    for Evaluation of  Compression Test Results of Field Concrete"
~ 39. ACT 315-65, "Manual of Standard Practice    for Detailing Reinforced Concrete Structures"
: 40. ACE 347-63, "Recommended Practice    for Concrete  Formwork"
: 41. ASTM D  287-64, "Method of Test for APX Gravity of Crude Petroleum and Petroleum Products (Hydrometer Method) 5.1.1-13
: 42. ASTH D 97-66, "Hethod of Test  for  Pour Points"
: 43. ASTH D 92-66, "Hethod of Test  for Flash Point  by Cleveland Open Cup"
: 44. ASTH D 88-56, "Method of Test  for Saybolt Viscosity"
: 45. ASTH D 937-58, "Method of Test  for  Cone Penetration of Petroleum"
: 46. ASTH D 512-62T, "Methods of Test for Chloride Ion in    Industrial Water and Industrial Waste Water"
: 47. ASTH D 1255-65T, "Method of Test for Sulfides in    Industrial Water and Industrial Waste Water"
: 48. ASTM D 992-52, "Method of Test  for Nitrate Ion in Industrial Water"
: 49. ASTM A 442-60T, "Tenta'tive Specifications for Carbon Steel Plates with Improved Transition Properties"
: 50. ASTM A 300-63T, "Specifications for Steel Plates    for Pressure Vessels for Service at Low Temperature"
                                                '1.
ASTM A  36-63T, "Specifications  for Structural Steel"
: 52. SSPC-SP6-63,  "Commercial Blast Cleaning"
: 53. SSPC-SP8-63,  "Pickling"
: 54. SSPC-PA1-64,  "Shop, Field and Maintenance Painting 5.1.1-14
: 55. ASTM A  322-64A,  "Specification for Hot-Rolled Alloy Steel Bars"
: 56. ASTM A  29-64, "Specification  for General  Requirements  for Hot-Rolled and Cold-Finished Carbon and Alloy Steel Bars"
: 57. ASTM D  624-54, "Methods of Test  for  Tear Resistance  of Vulcanized Rubber"
: 58. ASTM D  676-59T, "Method of Test  for Indentation of  Rubber by Means of a Durometer"
: 59. ASTM B  412-66T, "Method  of Tension Testing of Vulcanized Rubber"
: 60. ASTM D  573-53, "Method of Test  for Accelerated  Aging of Vulcanized Rubber by the Oven Method"
: 61. ASTM D  395-61, "Method of Test  for  Compression Set I
of Vulcanized Rubber"
: 62. ASTM D  746-64T, "Method  of Test for Brittleness Temperature of Plastics  and Elastomers  by Impact"
: 63. ASTM D  1149-64, "Method of Test  for Accelerated  Ozone  Cracking of Vulcanized Rubber"
: 64. ASTM D  471-66, "Method of Test for Change in Properties of Elastomeric Vulcanizates Resulting from Immersion in Liquids" 65 'STM A 514-65,      "Specification for High-Yield Strength,    Quenched and Tempered  Alloy Steel Plate, Suitable for Welding"
: 66. ASTM A  441-66T,  "Specification for High-Strength    Low  Alloy Structural Manganese  Vanadium Steel" 5.1.1-15
 
0
: 67. ASTH A 53-65, "Specification  for  Welded and Seamless  Steel Pipe"
: 68. ASTH A 435-65, "Hethod and Specification for Ultrasonic Testing and Inspection of Steel Plates of Firebox and Higher Quality"
: 69. ASTH C  177-63, "Method of Test for Thermal Conductivity of Materials by Means of the Guarded Hot Plate"
: 70. ASTH C  165-54, "Method of Test  for  Compressive Strength of Preformed Block-Type Thermal Insulation"
: 71. ASTM C  355-64, "Methods of Test  for  Water Vapor Transmission of Thick Materials" 72.. ASTH C  273-61, "Method of Shear Test in Flatwise Plane of Flat Sandwich Constructions or Sandwich Cores" e 73. ASTM D  1622-63, "Hethod Cellular Plastics" of Test of Apparent Density of Rigid The  structural design also  meets the requirements established by the "State Building Construction Code," State of New York, 1961.
: 5. 1. 1-16
 
i                                                                                            p~i4c Q &<47 r                                                                                              O'KC S/19/66 Hev> X 9/9/66 Ti''.CHblICAL SPIC EPIC'ETIO.'t PC:R FUN'IIS~)I>~G    PM>UCATZKC AHD i"'iZiCTXhG Si.'hVC'"tH>i3 83."nKL GEE<'ZIi:G~ .11.EXP.        1Pa>!Xi Afto }V;lFQl'CLIL FGPi  'f'i!~
IBBERV Y.""w~'TT QIMl~JA )NCf.C(J? PCX'P"8, STATXGH            - UltlT I'JCo  1 GF "'FZ RODENT~, GAS Af!D R~~ECTRJG CORPORP.TIQH RPv'cSS~x'~ iaaf''U YOiK 1o0 SCOPZ OP '.~'OZC 1 '3. GE'i!"VLL The wn"~      to  be    f.eri'0m'nder this            Subcontract shQ1 inclL:do          Cho detailJ"'lpj fLlz'niah~ijg~ fabrication~ dolxvGPJt~ unl c                lk~rLn~ Gt orag8 where necoo 'ary> al'n or~ation              of aM~: tructLLral staol> gr'.ting>
Otair "eada and hwdraU. xeq~~'d for the Robert 8~i..tt Gin~a I~ucloar Po:mx S~tion - Unit Hoo 3.                    Yce ~~xh shan. inc3ude but not necessary bo lilJ.ted to the                  ZO3  Lo:ri~~:
Ge    Pro@M;ation      of  shop    d8t'>ils  Q'."ad  Qr8ction drPrP~goo b, Structural .tool for tho Structures including tha Ccntailuent Vee"el~ Xntezvp;.die<;e Buildinp~ Rector Au:~r3iary Building, 'lie'o3ne f1<m~ Service Bui3ding al'!d FaccdQo      Tho  structural      8tt381    consists of 5 (1}    Cola.n.~
(2)    Ba88q    ~ip  An'3 LGRrxng      plat98 (3)    ShJ.D'8:,or    scttinc,    613. bao8      w:d baal"Mir p"wte5 (4)    23aesia  md piL dere (5)    TL'uGSe8 (6)    Poets, hw~,gers, tioe and              ='ag  rods
('7)  Struts and br~cinrr (8),  ~Lrlino and      1  irt;e
()) St'ir "-t"        1 (M) T:olley b;='~
(Wi) L- daces
(>'>) Too lQ"-.tea (X3) Connections alld connoctiol1
{3A) K>>'vota, .~olde and !1iph otx "~~t;h bolto 1)) Crane Haila, clips md atop" l6) Chcckerccl plate
 
1 a  i L I                                                                                              DKC 2>>                                          9/g/66 Rev. I
: c. Steel gratings,- grating with attached. plate, grating            stair
                          .treads,  ancl  all related'ardware.
: d. Handrail    for platforms,    wall; ways  and. stairs.
                  ~
: q. Shop paint.
1.2  LfOBK NOT INCLUDED The  following items of wor". associated, with the plant structures              =
are not included        in this Subcontract but will be furnished        and erected. by others:
: a. Anchor    bolts
: b. Grouting    for colure    base  plates
: c. Field painting d.. Steel plate..liners for Containm nt      Vesse3.,  Sp"nt Fuel  Pit, Decontamination    Pit  and. Refueling Canal    end. liner penetration.
2.0 SITE DATA 2.1  LOCATICH
                'h    site fox the Robert      Enua  tt Ginna  Huclear Power Station Unit Mo. 1    is located  on the south shore    of  Lake Ontario, near Smoky Point, in    Wayne  County, approximately      l8 miles northeast of Rochester,    New  York.
TRANSPORTATIOlr The  site will be graded      and. an  access road provided      to the worl; area.      No rail facilities    are available at the      site. The nearest rail    head. is  appro imately    four miles from the site.
2.3  ACCESS TO MORK A1KA Thc Contractor      will be  provided  all r  quired. and. reasonable    access to the worl'x+a        so ns  not to impcdc his operations.
 
DXC
                                      &3                                            9/9/66 Rev. I 2.>'ERVICES AIR FACILITIES The    availability of services      and. facilities for this    Subcontractor will be    detailed. by the Contractor, Bechtel Corporation.            Generally services    and. facilities  are as follows:
Available Services
: 1. Power    will be  available at existing locations at          480 V. in  a capacity up to 60    amp . Power reauirements      in  excess  of this amount  will require    special consideration      and. a  decision  for each  contract.
: 2. Hater    still be available at existinp locations.
: g. No  compressed air will be availablc.
4.- Fo  telephone sex'vice    will 'be    available except at the coin      phone in the Pechtel office-
: 5. Clean up will be the xesponsioility of the sub-contractor                and if it ls not properly accomplished.        the work  will be  performed
        'nd. a back charge  written to cover the cost.
: 6. The use of job site cranes        will be    offered. when they are not in  use on  the base, contract work.        This service    will be  back charged with a percent aided        for overhead,.
ifork and Laydorrn    Space Adequate work and. laydovn s.oace        >rill bc,provided in    areas not acgaccnt to the main buildings.            Limited work and laydown space tr9.11 be made  availablc,  dep nding on schedule and.        coordination of crafts, in the buildings,        and surrounding areas.
Office    and Chanrre Areas
    .Ho  office  space  or craft  change    i'acilitics will be    provided. Portable toilet fccilitieo srill bc availsblc.
 
XKC 9/9/66 Rev. I Job Coordination Bechtel    will coordinate      ih= site work    and,  direct the subcontractor to promote. harmony and, provid the        overall best work      sequence.      The I
        'Bechtel inspecting engineer        may req,uest    and. shall  be permitted. to witness    all subcontract work to assuze          its  continued. quality. The subcontractor's obligation is to provide workmansiaip within the requirem nts of the sp cifications          and,  to  make  designated tests to prove quality.
3.0 STRUCTURAL STEEL 3.1  SPZCIFXCATXOHS    Am    CODES All work    under this'ubcontraci shall          comply, except as herein-          ,
after specified,, with the following Am rican Xnstitute of Steel Construction Specifications:
: 1. "Specifications      f'r the    D"-sign, I~'abrication and. Erection      of Structural Steel for 33uildings", adopted April 17, 1963.
: 2.  "Code  of Standard. Practice      for Steel Buildings        and. Bridges",
revised, February 20, 1963.
3.2  NATERXALS All structural steel      used. in the  work and not othentise designated.
shall conform to Specification for Structura3. Steel (Tentative) ",
ASTN A  36-63T.
Rivet steel shall conform 'o "Specification for Structural Rivet Steel"    ASTM A  l>sl<<'$8.
High strength bolts shall conform to            Specification i'or High Strength Bolts    for Structu;..al Steel Joints,        Xncluding Suitable Huts and Plain Hardened Slashers", ASTbl h 32$            -6'.
 
r 1 DKC
                                    &5&                                          9/9/66 Rev. I Melding electrodes shall be suitable        for the type of steel tu be welded,.
The Subcontractor    shall furnish the    EIIGZZER and. the Contractor
                                                                      /
three copies of    all mill test  reports  and. three copies of the reports of the steel    f bricacor's    inspectors    for the structural steel furnished. by him    und  r this  Subcon'cract.
3 r3 SHOP AbD    FIELD CO>HIECTIOHS Shop assembly connections may be        either  welded. or riveted,      Field connections shall be either welded. or        made  with high strength bolts except for the following items which shall          be  either welded or bolted. with structural grade bolts r4ith        hezagona3. nuts:
: 1. All beams  marked. "Removable" on    the Drawings
: 2. Stairways, landings, ladders, etc.
: 3. All girts  and  roof purlins Mhen  high strength bo3.ts are used      in erection of steel for      making permanent    field connections    the connection shall    'be  in  accordance with "Specifications
            /
or Assembly of Structural Joints Using High Strength Bolts" issued by the Research Council on Riveted              and, Bo3.ted  Joints of the Engin ering Foundation and        dated. khrch 3.962.
All welding shall    comply with the requirements      of the Specifications of the    American  Institute of Steel Construction and of the Pwerican Melding Society    for the  typo of steel to be welded..
3 4  ERHCTIOi3 The Subcontractor    shall erect  all structural steel      furnished by him and required    for thc plant 'building except
                                                      /
steel which must be  left out temporarily for erection purposes. Tais steel shall be stored. by thc Subcontractor ao d.irected by the Contractor and
 
MC
                                          .                                        9/9/66 Rev. I erected by Others.          This steel  vill be  designated on the Dravings as being erected. by Others.
Oth  r  steel    >>ill be    designated on th    Dravings  to be  left out l
temporarily during the,non'nl course of erection for erection purposes    and. to  be  later  erected. by the Subcontractor 'before he leaves thc job      site.
The Subcontxactor        shall coordinate his    flOKC vith that of other contractors and afford. other contractors reasonable opportunity for the introduction of their materials and, the            execution of their vora''. Legible and. durable erection marlins          should. be painted.
on  all members.
3.$ TEMPORARY STEEK FOR EHECTIO&#xc3; The Subcontractor        shall attach to his Proposal a dravlng shoving any temporary      steel for erection vhich the Subcontractor proposes to furnish    and,  erect. The draving    shall  shov the arrangement for the  temporary steel      for erection    and. the loading thereon.
This dravring is subject to revie'ir by the          EHGXlBEB,  out such xeviev does not relieve the Subcontractor of his responsibility to  comply  vith tnc Specification        and, D  avings.
The Subcontractor        shall,  vhen  his steel erection    NOR!C  is completed.,
xemove any temporary        steel, including equipment supporting steel, placed. for erection      pux'poses. Any holes  in building steel, resulting fzum connection of erection            stee3. thereto, shall    be permanently pit~".cd by the Subcontractor,            subject to the. approval of the Contractor.
4.O GRAnxo  AHD STAXn    TOADS 4.1 SPZCXrZCATXO!iS A!JD CODES All steel grating        and gratii>g  stair treads shall    conform  to the folio>>ing )total Gr: ting Institute Specifications:
 
I DEC
                                      ~
7 ~                                              9/9/66 Hev. X
: 1. "Standard Specifications          for bhtal Grating      and  Vital Grating Treads", adopted pctober        8p  1957..
: 2. "Code of Standard. Practice of th>>            ihtal  Grating Institute" All steel plate shall      conform      to thc follorring American Institute of Steel Construction Specifications:
: 1. "Specifications      for the Design, Fabrication and. Erection of Structural Steel for Buildings", adopted. April 17, 1963.
: 2. "Code of Standard Practice for Sicel Buildings and. Bridges'7 revised. February 20, 1963.
AU. >relding    shall  comply  with the rcouirements of the          sp cifications of the American Institute of Steel Construction                and of the American Melding Society      for AS'        36-63T  steel.
: 4. 2 MATERIALS AND IEQUIBELPK'S All materials for grating, plates, grating              treads, clip fasteners, and,  tread. bolts and. nuts exclusive of hold. down studs and nuts, shall    comply  with the requirements of "Specifications for Structural Steel",    ASTN A    36-63T, except as other>cise noted. on the Drawings.
Studs, to be used.      for fastening, shall        be 1/4 inch diameter, type'04 stainless steel of'roper length.              Nuts to 'be used,  for fas>>
tening shall be silicon bron.e nuts-All grating    and. grating  tr ads    shall be of the welded type with Qopths as shoran on the drn~~lngo.          All grating    and, grating treads unless othemrise noted on          t;he Drawings    shall  be fabricated. from 3/16 inch thiclc bearing bars on 1-3/16 inch centers ttith spiral cross bars welded on 4 inch centers.
All chccliercd steel plate      and    plain plate,    as  called for  on the drm<ings,    shall    be shop welded      to and,  furnished. srith the grating panels.
 
DKC g/g/66 Rev-All toc plate      shown attached. to the grating, shall      be furn9.shed.
by th9,s Subcontractor and shall be          'nstallcd in the fabrication shop except where the        erection sequence neccss9tatcs field.
installation.
All grating    treads shall have 1" x g/16 inch bearing bars, checkered plate nosings, a width          of 9-p/4 inches,      and,  lengths as shown on  the drawings.        Treads shal3. bc furnished. with 3/8" x 1" cadmium plated, mach9.ne      bolts  and nuts,    four per tread., for fastening treads to stair stringers.
All cutouts    required. for pipes,    columns, conduits, etc. shown on the drawings shall be prov9ded.          for  9n the grating.        The dimensions
                                                                        /
of openings shall      be as shown on the Drawings.          The  'cutouts  and.
openings  sm  lier than    6 inches sha13. be banded. with bars of the same  depth  and. thickness as the bearing bars.          The    cutouts    and.
openings 6 inches and. larger          shall be banded    with  1/LL  inch toe plate projecting      6 9nches above the      finished, floor.
The Subcontractor        shall furnish    ade(Luate support angles under          the grat9ng at openings, where reauired.
4'$  FXEU3 CO%'1ECT30&#xc3;S TO SUPPOBT STEEL All plain grating      panels shall be fastened to the supporting steel with    L;wo  standard  sadd3.e  clip., at'ach    end,  of the panel,      and.
with two additional clips to the intermediate              beam when      the panel
    ~
is continuous ovex two spans.
All grating with attached. steel plate shall            be fastened      to the supporting steel with two wclds at each            end. of the panel,      and.
two  additional welds to thc intcxmcc;iatc bean            when    thc panel is continuous over two spms.
 
DXC 9>>                                          9/9/66 Rev. I 4.4    GALVAi~EIKIIlG All steel grating,    attached,    plate, stair treads    and saddle  clips shall  be hot dipped galvanized        in  accordance with "Specifications for  Hot Galvanized Coatings on Products Fabricated. From Rolled, Pressed. and. Forged Steel Shapes,      Plates, Bars and Strip",    ASTM A 123-63,      All fabrication, including cutouts        and, alterations, shall  be completed before    galvanizing, 5.0 EQ!DHAIL 5 el  MATER II' All handrail    sha11 be made    of 1>>1/4" diameter> schedule      40 standard weight> black and galvanized steel pipe and          fittings  conforming to "Specification for Black      and. Elot-Dipped Zinc Coated. (Galvanized)
Uelded and Seamless Steel Pipe        for Ordinary  Uses" > ASTM A 120-63T.
All handrail shall    have one    rail  centerline 2'-0"    above the finished. floor level    and, a second    rail  center line 3'-6" above the finished floor except where noted othertrise on the Drawings.
The posts    shall  be spaced, not'more than      8'-0". on centers. All1 handrail shall be in accordance with the typical handrail detail
        . shown on  the Drawings, All points shall    be welded and, ground    to  a smooth  finish. Turns shall  be maLe by the use      of tube turns or pipe bends and all railing  extending beyond. thc posts shall be terminated with drive>>
in plugs.
5.2    FIELD CO&#xc3;lECTIOi~!S All handrail    posts shall be bolted, to the structural steel supporting the    floor grating, except where shown othe'>ise on the Drawings.      All handrail posts set in concrete shell be set
 
~ ~
DZC 9/g/66 Rev. I in  oleeves pxovided by others with the concrete slabs          and. shall be secured. in place with molten      1cad or sulphur.
All bolts,    nuts  and. clip angles required    for fastening the hand-rail posts    to the structural steel shall 'be furnished. by this Subcontractor.
All handrail indicated      on Drawings ao removable,    or fastened. to removable steel framing,      shall  have  Joints at appropriate places and. be  bolted. for  easy removal  of sections    so indicated. All handrail running into bracing        and. columns  will be field.'cut  and.
welded  to  fit,
            . All >>elding shall      comply with the reouiremento      of the  American Institute of Steel Construction        and, of the  American Melding Society.
6.0 PAIi'KING All structural steel      and. handrail to be furnished under this Sub-contract, shall be cleaned. of rust or mill scale in accordance with the Steel Structures Painting Council Surface Cleaning Specifications SSPC-SP    2-6g  "Hand. Cleanjngi'nd/oi      SSPC"SP  3-6g "Power Tool Cleaning",
as required.
Paint shall be omitted. at        all areas  of field welding  and. on  all steel surfaces>>hich      will be in    contact with concrete.      All contact  surfaces of connections shall      be painted.,  including those for trusses and plate girders.
All structural steel        and  handrail, to  be  furnished under this Sub-contract, shall receive        one shop coat    of paint which ohall    be one  of the following:
 
lEC 9/9/66 Hev ~ I
: 1. Socony-Valdura 13-Y-5 Zinc Chromate Primer
: 2. Gliddcn  HGL  32802 Zinc Chromate Primer
: 3. Pennsbury Yellow Zinc Chromate Primer Keeler  Zo  Long Ifo. 4800    Exterior    Orange Lead. Primer The shop  paint shall    be mixed, and. applied    in  accordance with the Steel Structures Paintinc Council's Paint          Sp  cification      SSPC-PA 1-64. "Shop, Pield  and ihintenance      Painting".
Shop  paint shall    have e dry    film thickness of      2 mils.
Pield paint  will be    by Others.
7.0 SHOP Ai~TD EHECTXON DHJGlZi''.OS Tne  Sub-contractor shall submit to the Engine              r, for his  approval, one  reproducible copy and one print of          all  shop and. erection drawings, data sheets,    etc. reauired for his      >lOHK. Two    copies of  all drawings, etc. shall also    'be submitted. concurrently      t,o  llestinghouse Atomic Power Division. This shall be        done    with such promptness as to cause        no delay  in either his    HOK(  or that of any oth        r  contractor. These drawings shall  be checked and. certified, prior to      submission, and shall contain all  required. information.      The Subcontractor        shall  make any  corrections required. by the Engineer      and. file with thc    Engineer    and. the Mesting-house Atomic Power      Division two copies      each    of the'corrected. drawings.
Approved, drawings      will be  so stamped and. dated. and.      shall form  a  part of the Subcontract.        One  set of the approved drawings          will be  returned.
to the Subcontxactor.        Approval of such drawings shall not relieve the Subcontractor of the responsibility            for deviation from the Contract Docum  nts, nor from      responsibilities for errors in shop-or erection drawings,
 
DXC 9/9/66 Reve X 8.0 RECORD DBAIGI<GS Upon  completion of his work the Subcontractor shall submit to the Engineer a complete set of      cQ3. drawings  for the work. These drawings shall correctly indicate the work"as        built" and shall include all modifications of the work and additions thereto which have been              in--
corporated. The drawings  shall consist of approved drawings, legibly marked, and submitted one    print  and. one  reproducible each to the Engineer and the Mestinghouse Atomic Power Division.
9.0 XHSTALLATXOI'IADD XIlSPECTXOH PHGCEDUBES The  Subcontractor shall submit to the Engineer a written, detailed description of his inspection and/or installation procedures for comm  nts and,  review. These procedures    shall  'be submitted at least e
two weeks  prior to actual start of      MOHI(. Any comm  nts  'by the Engineer shall in  no way    relieve the Contractor of his responsibility to          e.".ecute his  NOBK to  meet  the intent of the Drawings and Specifications.
 
~ ~
iKC 9/9/66 LIST OF DR/8JIi.GS Thc folio>Iing Gilbert Associatcsp Inc. dra~7ings set forth the location and extent of the  WORK to be done and are hereby e::pressly made a  part of this Specification:
DRA>1I1',G PO.                        TITLE Turbine Area>>Steel Framing D-502-0U.                Column Schedule 5 Base  Plate Dtails D-502-021                kezzmine Floor Elcv. 271'-0" D-502-022                Operating Floor Elev. 2S9'-6" D<<502-023                Control  Room <<  Plans & Elevations D-502-031                Platforms, Landings 5 Stairs D-502-051                Top Chord, Hoof Plan D-502-052                Bottom Chord  Roof'lan D-502-061                Longitudinal Section D-502-062                South Elevation D-502-063                East Elevation D-502-064                Nest Elevation D-502-065                Cross Section D-502-066                Cross Bracing Below Operating Floor D-502-071                Girts - Horth Elevation D-502-072                Girts - South Elevation D-502-073                Girls - East Elevation D-502-074                Girts - Hest Elevation Containment Vcsse3.  <<  Steel Framin, D-521-001                Column Schedule D-521-002                Intermediate Floor Elev. 253    I
 
DKC 9/9/66 DBAWIEG  Iip.                        TITLE D-521-003            Operating Floor Elevations 270'<<4"                      8: 274 '-6" D-521<<005            Msc. Platforms Elev. 267'-3", Elev. 300'-4"                          8c Stair Details D-521-011            Crane Rumray Elev.        331'-0" Forced. Stxucture      - Steel East Elevation - Columns, Girts Bracing Framin'-521-071 Zc D-521"072            West Elevation - Columns, Gix t's,& Bracing D-521-073              North L'lcvation    -  Columns, Gix'ts & Bracing D-521-074              South Elevation      - Colums, Girts                  & Bracing Reactor  Auxiliar    BuilcU.ng    - Steel            Fxamin l
D-522-001              Column Schedule      8:  Bracing D<<522-031              llisc. Steel    8: Stair  D  tails D-522-041              Roof Steel    8;  Crane Runsray Elev.              306'-10" D-522-051              Girt Elevations Xntermediate Building        - Steel Framing D-523<<011              Column Schedule D-523-021              Platform Elcvations 271'-0"                  8:  278'-4 "
D-523-022              Platform Elevations 293'-0"                  8:  2g8'-4" D-523-023              Platform Elcvations 315'>>4"                  L-  Roof 317'-6" 3051            Roof Elev. 335'-4"        8: Stair Details Service Building - Steel Framing D-531-001              Col~~    Schedule    8:  B"se Plate              Details D-531<<002              Ih canine Floor Elev. 262'-2 1/2", Floor Elcv. 271'<<0" 8: Rooi'
 
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of thc Coat'ctor.                                      i o .'.})Op (rr          fiel<} d      ':-x.'in;;    for for!I v(or}< need            I)c sub)!.          'I"I'G }    v)      '<'rho      }'n<inoar.
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                  !~coo'; as                  nomic<'. !!ereinaf':,Gr, fore<<or<<                                  hall be consv('Uc'Gd Ho as 3!ll Urs U'.a'v QG concrcste SI.L~.'! <<cas
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                                                                                                                "'ill      c<nf          I(O>>'()'C to L. "') OS of }'<rogosed ACi >01.                                            o 8'.;(kgb:.ala".e 3inar n };hc con" ain!L)Gn.b -"G"'s.'..L 1!hcn used as ". concrs+G ..or".I sh."11 be brace(l a 1d shor'd to ensur tha('r u'.le''lee <<ion Goes no t< e:<<.ceo. 1/4 lnr fo                                                        (':  1 arc leng""a of 10        ft I"Oj<<U. !!1'g01Q<
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d3 ~t.! a3 1 Su'OJGC to 0:)G aoo'ova3. of the ):Gi leer.
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          "..'j'i;b ) T.(<E i'P.3)!KC hc3ded ')iro f"brj c                        .".Q" .(:Qncret" rcinfor(:(:):.".nt ."h33.1 conforn to "8",cc!.fj.c." ion3 fox i(- ir)e!                              -irc ~ abric for;.'o?.Crctc jleinforccmsn                                                      '!'
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car- 'in'( r(in:;Orcc? 1(:!'~:"'",.(i silali be sp3icc(l i?. accorilcnce vfith S"=ction        .'.rJ5    (b) o:;            ':;0 .Osc(!        i'. 301, 9.3 ThQ col!'>>rL'c 4.                  ha .1:>I,'),'r.t              ".    ".<'.i..!r draY!ln;;8>                rc j?:Xor
                                                                                                                              ~    n inE bar 0  tel'i)          =',i .i .)i) .'U.;)          is:!.'l    c'1 a '              u()c(.      for ii'.ic;.8 )r..c: Q.on                        c    ld placentas,'- og -i!:c x(.-'.::!:.'0:.'Ocr~=nt i)i. t!!e strhc filL>> e                                              f  x'18 En@i?!""Cr'i aoorov:.!1 (:.".~ t:.!o ("';8::.13 are                                    i    i general co~ip iMCO "lith t.le Cnpin CZin w".".;".ip.r                    ..
Jne Contr."-.c 4:; shall sublii 0 thx'l o. 03,'ilits of a3 1 bsr Fists and plack.:.i", d c'i"'in'~s: cx x si~ c'7 op ij!9 '?)cj                                          n'r      ~      .,close dry")ings 3'..~ '-!ll
        ~ oe c'ls fied Gx!<'orti::>c(t priox'o Sub;"'!!.ssion Glad sjiall cont'-'i!1                                    ~
ll 'gl'x'e'l                j 1v QrR!9. !Qn fhs 'QA trcc vor s'ia3 1 ?(si;e correc (?icns c
g 'ui        re@ b$II bhc !'naincsx cs+d Fj ! e .gi. ih thc E'>Bi'-ineer an unFQ3 6'-d rsproducib3." o<.'";ch drain< frol;..".?hich cl."..an Gnd le~'ible grin,s c' be li acc i!j:l'8,"cv('d r- producib3('.3 (i!ill. be ".3 stsQip-d cnd l=-te(j One set of th(i QG)roved dra:tint,s,"ill b" retuxned to the CQ!i>>rac l)gprova3. of such drat'irgs shall not rel ivc t):e Contractor of th(.
respo!isibi3i'..y for errors in '(hc bar. lists or pl.acj.ng (bav(i;>(is:
9.Li      !Qi."il0".Crl!C STl.,'L 'P),?CL'S Ho sp33cps Qf re info! co!!,ent sha: l. bo made c:(c~ pt as shonn on tr?.'e LPi.'Pl':" n~i(s~ oi, as specified here1ng or as Upc "Qx'ed bp'he 'En~Pi?!e(!ri Lag'                                      t sp3ices in ?!sj.cn shall not be used fo r bar sj )ies larger thl!n:r'll ))herc t);e 'oar si:>c e:;ce'=d3 /rrll, CAj:.!ELD sp3ic"s sl ."-...'.".
be used to dcve3og 1255 of the ?)inj.Li:~~ yie3.d <.oint stress of the bar. Yestin!. of C.i))i!LD splice.". '.rill b bacee on a xandc?il s'~p3in!;
i gxroccduro ti:G..".inr,." a ., iatis i ic(!1 'ovalu.'ion. Ki.nimu.") la(), sp" ic(<<
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coat'pj(atec'. v,j.+2'.i!I 3. 3/2 ilours o). befoL e ~~0 dro:n haQ been I'evolse".
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                                                                                      ~ i ta'i
                                                                                          ~    ~ a. II ~ \ ~  ~ ' ~ t)A  i ii.l.  >> *    'taa4      aiitt    ~
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caI of ul        >J    clacc(l 4i cvr.r)le ~uol              .Q. I,J  g!e    >ro'! d. bolo ] Q.c x'RL'r' twTLQjl 0!.'-',h(1"ACL S lihol a c~ .'Once! c!)LrcI'.)te )Qr faces aY o tl() be r'cv". 'Sd 7!i <a ('rou't'r Gil )-
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                      ~L'oo(l k'o .-- beCGecn cr)nero Lie rrrd f~rou't'r can b.. oo gc!3.!1OQr                                                    The corfu'-'ces sba13 hs .'cari fled rouvhenL".d;!nd all lai'ua!ce re!!Ovcd.
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                                                                                                    .resru-tensioninr vre"    '-..'. ConcrQYr-.
lysi;oaL es !.ienufacturc'..
p            AS>'~t h421-~5 cnd shall be '.he Bb!r" hy Jo.c j~ T. ".Ve so'.x .~ Son, Xn."..                                                The st,      el  t,c;!cons      for bricatr'0        v~'ii'h  ~c    folio'A'ln; col!ajity contrro!
prest(('ess:.:(.'onc."eve'L"'ll 3'
t)roc c'.liras Qei g>~, observed!
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a,"        f"nys.'.cal ".a6 ch r'$.cal test r Ports sha3.1                                                b: sl!omi.'t        d to the i.n(rinoer                                              r for each e3. o" ro.Ye.
                        'o.. The                          !;en(';on fabricator shall cut sanples fr)ln oach cn(! of a
                      ~ reel foll! bLLE'i('ron.lcs(ts a u Jlo Cn( S allot 'ue85 vh 'l SPeol!!Lene Thel O                                                                      ~
                    . tesvs shell ensure thav "vh *Tv'.r(l rup4'>res bsfo..'e ~.":).3"r('f tho bL!rv~vonpead KG '(harv Ul 'I'i re lGe!!trs 'l'he pcs L(!GL ro(!ui.&#xc3; .c'ntrs of PLulai> !~421m j
lH.:;h s+vren>"vi) '-'1."c s v..el bars 't;al3. con for.-;! t,) SL'"'C!..r~L STREGST!'FL
                        <<s manufac+~;!red o;r uhe b::.ress'L'eol Coro>ra'Cion "!ith a'~uarantced
                        ~"~ ni;eau ul"Laatc Gtrenp. b'a O.". JVG,GCO                                                D."L.o l6    0 i'iK)T'CTTO't                              0"'''!2"'!
l ock ~zlchors sh'..>.3..oe Pro!'n't(!                                          ii!  "0 s l'a~os r 0            6!e    r full lens" t l all      .'          s.'.!o'::L            on '"      . i'r,":.>>.Lngs.      Ti:c r(,cn('on. in
                        .".hall        Ue o;! LYn'c./n(.:e;i construe';ion.                                    ".L'no ton('on        s use'or                            unbonc'.e'a COB.S i:-"u U.O!l Shall "e Contre L L'U.rr!L (rl'O;.SQ "'r!"..                                                    peed      The type Or pl
                                'r'aaRS                      a g Vv'I'(-. lct A
n(r      S.?a '    Oe "r  t(.'C      C).IICa ~pons to          f.;c                              ggs!lcg,
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(!hei= 'v'lc fo) ~d ai'inn'.; o" concret(." si'ructu>:.'.".!)rc sho':.'n'n tile w3.'P-'f'.<"'"8 '1" 'Qjzl</ 'o.'aced Qn I'1'QU') .i t!)8 sub 1'a<iQ suDooi"01)1g LP hal'). L'.Q<<.83. ann "r.'.)u..d to th" 3i.ncs cnd f".).'cnsions sho:"n a'nd shal3.!)8 il':;c of (.'Qbr<..".;)nd organic fff;)vcrial. 'I'ne s! bpradc sill<ll oe co:!,!3'c(I by u .'?:P. a )I'< 'Glfbie ccfr'0ac vox'D !! dc)183. vy ox at) Less f
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cond<<. ion" shall co))cr .:" be pl'.Ccc! on fl'ozon::ubgr dc z>awol"i.al.
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and/ol" v'at            I'c      v~vin," -".'nd orcofr<iF!~ <<nd .).lail t1an c('.                        thox'Qugh3J<''!8 t)uod ZiPplo n(3<<ai3i.c ~viOn l'. aa13. b p" <<joll 'to vha K))ll<<incCl'nd<t O'                                                      CS v." nE) i "Cor'tOry r)lio" 'Vo Ol Cing COI)C('8'.8 On nubby<<a<:.8 to imraiv ther~
        /                  io insnec'(. +he subg).'adc.. Jt is 4".;8 intent of he unpin er to maI.<)
  )</I                    .. p'.:Qtogx'af;l c loco'd o eho sub:.-ade.fGl'elc(;tee            lpga                              a"Qas of ti)Q p~
CO'1 ua3.n&#xc3;~on v VOHSC".o 3.2)2      CO    lC!RT      l~G if'."!2LR II./!'.=E;!
                          <)nd    <<'o          il'Cu'ra'van(les            Shall    COIl  rCM ba              dC DS:.ted    '2:ZQCX'ateI'<<
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j!Cl 605-5'              czcco! Q)av accolc ito"'s such as c')lc);i.)a ch3ori.de an:l
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yi              Tk>8 '.O'A.i::ot')r                )nsul'iric:. -0                        3:0 'ol,.ced ver';ic .3.lj af :lil>st                                                        t  10 fo u'1(iri v'Ci!1
                <<r'l013 G a!1(l corizon v                          .i,<<"      urlder        sl(<<~o. 011 pre!(>e '}1G]., l 0 St:>xofo"",! SB
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                .".ns.i<<lied ir! !ccordalice lait!2 ti!0 rr>anufa(:tl>rcr'                                                                                  el~ lit8(}:>.r!Q 'uruC                              t'n 8 l<$ .0 <,lJflL'ETX C(X'3'F"r(OL Tj STS T rr<<>".mc        v'1  r<<ej,Qu<<GG, t/)r,'i c po;;8( 1).                                    /isis                  'c';ill ol: val 0 v,<<n Seri j ces of      .":. Tc"-'vina L<<'.'Cr-torY ':;!r<<.cj2 >0).31,                                                      Dri>ol'4):i!c ~ontrnctor gPF''10'L<.">.'.i!i:ttX  Co!l'>riencinri CO "icX" i' 1'iorj( .r 0 8 ')reLirc'Q.POX~'}8Xer> cl!ic.tio 1G Of co!2tro...>cd;i>i':GG                              !;)in')!c                is~t(:ri",3,". pep"Gec an J consiste;2cice Guitablo                fo'he;icrj( i;1 order                                                "s detorrl>ino the ."ii.z procort:>0>is neccss;:r<< to !m uco                                      concle-'8                conforr.='22@ to tb: tyoe ar!d stror!give x'0 .l!'>re!'i;n'ts 0:!3.30<<(,. fol" }!Groin or on 'U>8 IJ?"';El.'1f~s,                                                                                    fl+'~reQF'es shP13> be              'teste('n                      ".Ocox'der)('8              "ll    tr"1        i  18    lateutr            od'.ions                  of t!:8 fnl>3@xing PS:>>! ':!)Gcificetions: C20, C40, C127, C3')8 "n('33(:. .                                                                                                                        ~
                          .Corflj)rcsoioll uos'vs .,Gh1=11 con'orLQ tro flS Jfk S})('.Oi..icclt:.0PQ C3) J.> Gn(i Cl+2 iD$ >> LQG Cont>2'Pc uo). G}1G3 }. O'4'or:Q.t to 518 i Qslirlc> LaborBtory
                            ". Guf"".c en% t-:.ri. boxol" conc-"-';=- rorj( v i!)pre.".::.8.lies roquir(>d by u}1- Tesujnj Le)OX" uor<<,'OX'le'0 ill
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ccrr.'unco all. Concre-0 pre33.0'ests>>
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                        ~:  The        orocortiono for Vle conc).'8t!)                                                      >71(CG              villi        })( dc'vcl"."ii.ned by >c!Oti}206 2  of        S<)c""ion 3w of l'ro!>sed flC.':                                                  303. "Xrc! ".," }!croin'Co>ore Gpacii'iod.
3~8 T}28        .".ngineer G}1 .3.3. 3!nve th8 ).ig}rt                                                    z        1 Gj(o e(jJrsiv'!.ents                            in    col!Cxic 'ie pro@Dr"i Oils                  "f      n -CCG >GX'y 'to rlree" t<<'10 ro(,'uireb<<"-Iltrs 0                                                              f    tr!1CGN G Oeci        fi  0'<<t<<}.0210>>
Jn 62              event; 5!c Ccn'vrector x'uxnisrlod reli(l'ol( vest rocords of cotlcr ~'rzde Qui~li Gtrl GOD;,Oc'v or      Ci'J3 v<<
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f~oVel'rli.'1>c',:!Qtr}!OX'i i'n
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                                                                                                                                                                                          <<<<ul! 8 Lnpineer y (r bx>.ldinp cc(!88
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                            'j> >Fj FFc,      r>>>>rc'wn',", F; ~)s'' i': owe!                          Qlrw          'F Fee        ''F  nri '>}1        ~ >F"  'r<<>'            ~ ~
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in  '>)he  '..venC      v>)!L v  coRcre be is g3!!red                  dil:.'1!)~P f:".CGA:>.ng v>SGther        o" lj~"      Qa'v " frceze          is    e::o-.cv'd (!ia";:;n,;"Qc              rurin; -sriod, "n addi>'io))al
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Ordex charges to improve procedures for p)'objecting and curin(!                                                    v! s cP-                        concrete.
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Therepresentative stresslevelsinthecontainment shell.can,befoundinAppendix5DoftheFSAR.Thestressesforthe48loadcombinations identified inTable5.1.2-4Iareprovidedasstressresultants andstresscouplesinthemeridional andthehoopdirection, including meridional shearandradialdisplacement s.Unitstressesinthedifferent structural com-ponentsoftheshellaredescribed intheFSARasshownbelow:(1)Stressesinthehingetensionbarsareshownonpage5.1.2-37.
ADVEKPi4 HOe TO l
(2)Stressesinthelinerknuckleplatearedescribed onpage=5.1.2-37A.
TEC!iNICAL SI'LCXFICATXQNS FOR
(3)Stressesintheelastomer bearingpadsaredescribed onpage5.1.2-37B through5.1.2-41.
                            ~  STRUCTUI.W~. CaNCaWE FOIL Tf!E BROOKNOOD PI %MT UNIT NO<
(4)Radialshearintheshell,seepage5.1.2-42through5.1.2-43.
OF TIIE l
(5)Longitudinal shearsintheshell,seepage5.1.2-44.
ROC'rIESTEIK GAS AND FLEC&ilC CORPORATION ROCHES'LYB I EN YORK 4.0 Cl"'ZAT Second  line after the        words "TyI~~ XI"        insert "for @odorate            AM@ of hydration" ~
(6)Horizontal shearsintheshell,seepage5.1.2-45through5.1.2-46.
8,0  FOiBDOi>X Sol  GENERAL At the end of this            ection add tho fo3>.owing:
(7)Tendonanchorage
            "All ox!closed    edges    shall be chmferedo            Tho size of the ch"mt'er  strip shall        be 3/l. Mches unle.       s  otherwise noted on the Dra'ringso" 30.0 JOIKTS AND QIHEDDED XTI          <S 10el  CONSTPUCTXOR      ITIR!S At the end of this section add the fol3.owing:
: stresses, seepage5.1.2-46a through5.1.2-46d.
            "Construction Joint surfaces shall bo I>re~cd for tho placejfent of ccncrete thereon by cleaning thoroughly with t>ire brushes, cantor under pres"ure, or other !>cans to remove al3. coatings~
(8)Linerstresses, seepage5.1.2-46e through5.1.2-5la.
stains, debris or other foreign n t;eriaD. ~ "
19 (9)Longitudinal linershearstresses, seepage5.1.2-51b through5.1.2-51g.
lOo4 AIIClIOR BOLTS      AI'3) PXPF 81Z~/EQ At tho end of this section            M~  d the folios>ings "E>l:bedded  items shall bo chccIced            for line  and grado          after concrete is placed "
(10)Stressesintheconcreteandreinforcing steelduringthepressuretest,seeTableBonpage5.1.2-51h.
ll oO I!LKIND CQk'CRETE ll  2 TRANSIT I4LXXKG At tho end of this section add tho following:
(11)Largeopenings, seepage5.1.2-62, andtheThirdSupplement oftheFSAR"DesignofLargeOpeningReinforcement forContainment, Vessel."20
            "As rccIuirod by AS'Q) C<)4-65            a33. truclcs shall bo  cquiI>pod'ith a revolu,t,ion countor."
'Ir' NgQX~'<<Q<<~+C.c.DStructural Requirements C304-4WindLoads(8334)Minimumwindloadsshallbeinconformity withtablesC304-4aandC304-4b,andshallbeappliednormaltothesurface.Theseloadsarebasedonadesignwindvelocityof75milesperhourataheightof30feetabovegradelevel.Minimumwindloadsonsignsshallbeinconformity withgenerally ac-ceptedstandards.
TABLEC304.4a.(Ill.633)
-WINDLOADS:WALLS,EAVES<CORNICES<
TOWERS<MASTSANDCHlhlNEYS InpoundsporsrtuarofootAtheightabovegradeinfeet.501to600~401to500301to400201lo300101to20061to10041to6026to400to25Wallst1343332302824211815Eavesandcornicess 686664605648423630Towers,mastsandchimneyss 6058565349423732261exteriorwallsshallbocapabtoofwithstanding windloadonboththefntcdorandexteriorsurfaces, actingnon.simultaneously.
-"Loadactingupward.3Forheightsabovegradegreaterthan600feet,add1psftoloadforwaneforeachintervalorpartofintervalof200feetabove600feet;foreavessnd,cornices.
andtowers,mastsandchimneys, corresponding loadsaroinproperliontothose(orwalls.4Tabularvaluessreforsquaresndrectangular structures.
Forstructures hexa.gonaloroctagonal inplan,useprolected arossndmultiplytabufarvaluesby0.6:forstructures roundorelnpiicsl inplan.useproiected aresandmultiplyvaluesby0.6.C304-5Overturning ForceandMomentDuetoWind(833.5)a-Theoverturning forceshallbethewindload.ThewindloadshallbetheloadsetforthintableC304-4a,andshallbeappliedonlytothewindwardverticalsurfaceabovethehorizontal planeunderconsideration, andtotheriseoftheroof.There-sistingforceshat(bethedeadloadofthestructure abovethehorizontal ptaneunderconsideration, plusthestrengthofmaterialandfastenings estabtishing continuity withthestructure below.b-Themomentsofstability andoverturning shallbecomputedabouttheleewardedgeofthehorizon-talplaneunderconsideration.
93 0(p'Aq Structural Requirements TABLEC304.4b.(IV.633)-VtfMDLOADS:ROOFSlnpoundsporsquarefootMeanelevation ofroofabovegradelevelinfeetDirection ofload>0'o20'lopefromhorizontafg 30to"60'0'o30'ver60'01to6003401to500301to400201to300101to20061to10036to6021to350to20DownwardUpwardDownwardUpwardDownwardUpwardDownwardUpwardDownwardUpwardDownwardUpwardDownwardUpwardDownwardUpwardDownwardUpward829828727725624520519517514829to24828to23727to22725to21624to20520to17519to15517to14514to118to24248to23237to22227to2121Gto20205to17175to15155to14145to11112424232322222121202017171515141411111Downwardsndupwardloadsactnonslmultsneousfy.
"Forsfopesbetween20and30'llhwindactingupward,sndbetween30'nd60'ithwinddownward, compuleloadsbystraightlineInterpo-lation.3Forheighlsabovegradegreslerthsri600feel,sdd1psftoupwardloadlor0'o20'lopeforeachIntervalorpariofIntervalof200feetabove'00feel;lorupwardloadsonotherslopes,snddownwardloadsonsllslopes,corresponding loadsareinproportion lothoseforupwardloadfor0to20'lope.c-Themomentofstability ofthestructure abovethehorizontal planeunderconsideration shallbenotlessthan1'/2timestheoverturning momentduetowind.C304-6(833.6)SlidingForceDuetoVlindTheslidingforceduetowindload,equaltotheoverturning force,determined inconformity withsectionC.304-5,shallberesistedbythedeadloadofthestructure abovethehorizontal planeunderconsideration, byanchors,andwhereapplicable, bysoilfriction, providing atotalresisting forceequaltonotlessthan1t/2timestheslidingforce.Anchorsusedtoresistoverturning mayalsoprovideresist-ancetosliding.94 3.TORNADOEFFECTSONSTRUCTURES 3.1GENERICAllstructures havebeendesignedforwindloadsinaccordance withtherequirements oftheStateofNewYork-StateBuildingConstruction Code.Thewindloadstabulated inthiscodearebasedonadesignwindvelocityof75milesperhourataheightof30feetabovegradelevel.Thestressesresulting fromtheseloadswereconsidered onthebasisofaworkingstrengthdesignapproach.
'Forpurposesofthisstudythedesignofallcriticalstructures hasbeencheckedonthebasisofalimitingloadfactorapproachwhereintheloadsutilizedtodetermine therequiredlimitingcapacityofanystructural elementarecomputedasfollows:C=(1.00+0.05)D+1.0W+1.0PSymbolsusedinthisequationareidentified asfollows:C-requiredloadcapacityofsectionD-deadloadofstructure W-windloadsbasedupon300mphtangential windvelocitytP-pressureloadbaseduponaninternalpressure3psihighertthantheexternalpressure.
3.2REACTORCONTAINfENTAlthoughtornadoloadswerenotconsidered intheoriginaldesign,thisstructure iscapableofresisting thefullstrengthtornadoloads.14A-4 3.3AUXILIARY BUILDINGAlthoughtornadoloadswerenotconsidered intheoriginaldesign,thisstructure uptoandincluding theOperating Floor(elev.271"-0")iscapableofresisting tornadoloads.Thesidingonsuperstructure wouldblowoutward,thusrelieving thepressureandwindload.Components andsystemsontheoperating floorandabovearesusceptible toimpactbyfallingdebrisandpotential missiles.
Theequipment, ontheauxiliary buildingoperating floor,requiredtomaintaintheplantinahotshutdowncondition isasfollows:a)BoricAcidTanks,PumpsandFilter;andb)480VSwitchgear
-Bus14Theequipment ina)issurrounded byaradiological shieldwallasshowninFigure14A-1.Thiswallofferssignificant lateralprotection againstpot;ential missiles.
Furthermore, thetwotanksandpumpareredundant.
Hence,thereisreasonable assurance thattherewillbenolossofborationfunction.
MoredetailsaregiveninSection4.2.1-BorationSystem.DamagetoBus14willnotcauselossofpowersupplysinceanindependent andredundant bus(Bus16)isprovidedontheintermediate flooroftheauxiliary building.
Thisfloor,aspreviously mentioned, willnotbeexposedtotheweather.MoredetailsaregiveninSection4.4.Inaddition, theSpentFuelPithasbeenevaluated.
Potential missilesmaypuncturethespentfuelpitlinerbutwillnotpenetrate throughtheconcretewallsorbasecausinggrossleakageofwater.3.4INTERMEDIATE BUILDINGThisstructure, asshowninFigure14A-2,issignificantly confinedbyotherbuildings, i.e.,ServiceBuilding, TurbineBuilding, ReactorContainment andAuxiliary Building.
Consequently, adirectexposure14A-5 toatornadofunnelisextremely remote.Duetotherelativevacuumwhichmightbecreatedbyatornadooutsideoftheintermediate buildinglateralwallsmayblowoutward.Thiswillrelievethepressuredifferential andpreventgrossfailureofthestructural steelframing,columnsandfloors.Therefore, thetwofloorswhichhousecriticalequipment, i.e.,floorsatelevations 253'"and278'",areaffordedsignificant shielding bytheadjoining structures andhigherfloor/roof elevations.
Th'ecriticalcomponents inthisstructure consistofthefollowing:
a)Onfloorelevation 253'":twomotordrivenandoneturbinedrivenauxiliary feedwater pumps;andrOnfloorelevation 278'":thecrossconnection onmainsteamandfeedwater linestothetwosteamgenerators.
Aspreviously mentioned, nodamageisanticipated totheequipment locatedonthesetwofloors.MoredetailsaregiveninSection4.1.3.5DIESELGENERATOR ANNEXTheavailability ofon-sitedieselpowerwasreviewedonthebasisoftheassumption thatthetornadocouldcauselossofoutsidepower.Siding,windows,doorsandventilation openingswouldblowoutwardthusrelieving thepressureloading.Damagetotheroofmightresultifthedifferential pressureisnotrelievedintime.Tworedundant dieselgenerators areprovided.
Nophysicaldamagetothedieselsisanticipated.
Furthermore, thephysicalseparation betweenthemissuchthatonemissilewouldnotbeabletoimpactagainstbothdieselgenerators, asshowninFigure14A-3.MoredetailsaregiveninSection4.4.Thecon'elusion hasbeendrawnthatemergency powersupplyisreasonably assured.14A-6


3.6SCREENHOUS ESiding,windows,doorsandventilation openingswouldblowoutward,thusrelieving thepressureloading.Nostructure collapseisexpected.
\
Thecriticalequipment housedinthescreenhouse isrepresented by:a)fourservicewaterpumps;andb)480VSwitchgear-Buses 17and18.Thefourservicewaterpumpsareredundant andsufficient physicalseparation existsbetweenthemtomakeextremely unlikelythefailureofallfourpumpsfromthesametornadoeffect,asshowninFigure14A-4.ServicewaterpumpslAandlCareenergized fromBus18andservicewaterpumpslBand1Dareenergized fromBus17.Cross-tie betweenthetwobusesisavailable.
                                                ~ <<2<<<<
Thetwobusesarelocatedinthescreenhouse andarephysically separated.
11~6 BATCH    RECORD At the end    of this sect,ion          add the following:
Hence,thereisreasonable assurance thatatleastoneservicewaterpump-buscombination willoperateproperly.
uAs  roqui ed by ASTk~ C9$ -6g th batch t,ickot sha'U. also include the tin.e loaded, amount or concrete and reading of revolution counter at first addit,ion of.';atero"
.MoredetailsaregiveninSection4.4.3.7CONTROLROOMNogrossfailureofthisstructure isanticipated.
, 14oO  CURIL'Q AND 5'ROTECTIOW Curing v;-thods detailed in ACI 301<<66 shall bo used cvzop5 thaC a method other than using a curing compound shall be used for initial and final curing of concreto in the containnen~ shello 19oO  QDALXTX COHTBOL 19<1 PiKLQQHARY TESTS In the  sscond paragraph change "Section 309"            to "Section 308",
TheonlywalldirectlyexposedistheEastwall.'hesidingofthiswallwouldblowoutwardrelieving thepressuredifferential andleavingtheinteriorexposedtotheweather.Thesamewouldbetrueforwindows,doorsandventilation openings.
19 2 FIELD TESTS At the end  of the third pmag.aoh add the folio:wag.
Localcontrolsfortheequipment requiredformaintaining theplantinahotshutdowncondition havebeenprovidedasabackuptothecontrolsavailable inthecontrolroom.Therefore, thereisreasonable assurance thatcontrolsforthecriticalcomponents willbeavailable.
              "This cylindor sisal be bosomed at'8 days "
14A-7
Add the following addit;ional    section.'~20 oO  le% R The  chloride content, of ai.ing ~mter shall not exceed 100            p~>
and  turbid55y shaU. not exceed 2000 cpm."


3.8.SERVICEBUiLDINGThestatusofthisbuildingissimilartothatoftheauxiliary
DYE 10.-17-66 Revised li-3-67 ADDENDUM  IIO.
: building, i.e.,thesidingonsuperstructure aboveelevation 271'ouldblowoutward,thusrelieving thepressureandwindloads.Thecomponents whichmightbeaffectedbytornadoarethetwocondensate storagetanks.Thereisreasonable assurance thatfeedwater supplywillbemaintained becauseoftheavailable redundancy andofthefactthat2/3ofthetankvolumeisbelowgrade.3.9CABLETUNNELSThecabletunnelsarelocatedunderground andarecapableofwithstanding tornadoloads.14A-8 4.6TornadoLoadsTornadoDesignCriteria~lkc4lqFww KI/&#xc3;<<>~4xXwoc.Annebe~e~w~QThePumphouse willcontainsafetyclassequipment (SeismicClass1),,andwilltherefore bedesignedtowithstand shorttermtornadoloadings, including theimpactof.tornado-generated missiles.
TO TECHNICAL SPECIFICATIONS FOR STRUCTURAL CONCRETE FOR THE BR03iY'iOOD PLA NT UIGT I'IO o 1 OF TIIE ROCHESTER GA5 A.'JD ELECTill'C CORPORATION ROCHESTER~ M"U 'lORK Add the folloii~g section:
Tnefollowing tornadcdesigncriteriashallbeused:ra.%Iaximumrotational windvelocityof290mph,togetherwithtranslational windvelocityof70'mphgivingtotaldesignvelocityof360mph.Radiusofmaximumrotational velocityiscdnsidered tobe150ft;Pressures andsuctionforcesduetothe360mphwindandallotherdesignparameters shallbedetermined inaccordance withANSI-A58.1
    "20.0'RGUi'JDXIlO 20ol  CONCRETE    REXI'PORTENT All concreto reinforcerrent embedded in the side wall up to Elevation 252'eet slnll be made eloctrically continuo:is by bonding all such items together by means of the CAD::IELD process      Arc welding concreto reinforcement, for any purpose including Cho achievement of electrical cn>>tinuity shall not be permitted unless not,od otheria.se on Che Drawings. Standard CAD<'IElJ3 porider shall be used to ireld copp..r to stoclo        The, tio3ding material shall consist of a copper thormit mixtur employing tin m tal        in  an amount  to effectively constitute from ~i.5 percent to      5 ~5  percent of t,ho resulting weld metal.
-1972.'b.Externalpressuredropisconsidered tobe3psig.c~Amissileequivalent toautilitypole35ft.long,14inchesindiameter, weighing,50 pcfandtraveling at130ft./sec.withinaheightof17ft.aboveground.d.e.Amissileequivalent toatwotonautomobile traveling at150ft./sec.andimpacting withinaheightof22ft.aboveground.A12,ft.long4"x12"woodenplanktraveling at260ft./sec.andimpacting end-onatanyheight.f..Amissileequivalent toa3inchdiameterSchedule40pipe,10ft.long,traveling at160ft./sec.andimpacting end-onwithinaheightof48ft.aboveground.g.Amissileequivalent toa6inchdiameterSchedule40pipe,15ft.long,traveling at150ft./sec.andimoacting end-onwithinaheightof'0ft.aboveground.Amissileequivalent toa12inchdiameterSchedule40pipe,15ft.long,traveling at130ft./sec.andimpacting end-onwithinaheightof14ft.aboveground.4.6.2TornadoLoadCombinations Eachoftheabovemissileloadingcasesshallbeinvestigated todetermine whichonecausesthemostsevereloadingofthePumphouse, orofindividual Pumphouse components.
P  ior to    CADllELDL~IG the su    fac of thc roinforcoz nt shall be cleaned free of file rust  and  rill  scale and filed with a coarse or grinding wneelo Every precaution snail be talcon to remove only Che minima~ petal required to obtain a smooth surface. The CAD'v.'ELD process shaU. be performed in accordance irlth the nmufacturer~s printed. instructions. Tho concrete reinforcement shall be >r~ide electrically continuous at a mnimum of th."ee lo ations p r circumferential ring or vertical bar and shall oo bonded to the contairment liner at three location approximately 120'part. The bond, connection to tho roinforcomsnC shall bo staggered in the vertical and horisontal dirccCions Co provide a minimum distance between connoct,ions of five foot . Tho staggered pattern shaU. be repeated no more frequ ntly than for every fifth bar. Thc CADYKLD splice used for 1I,.S and lQS bars will provide electrical continuity.
Themostseveremissileloadshallbecombinedwiththetornadowindloadforthestructural design,ofthePumphouse.
20o2  Tl<iIISION BARS The tension bars s)iall be bondod togothor by the CADUELD process a>>d a di". 'ct. bond;sado to tho containment li>>or at throe locations ipproximatoly 1"0" apart. Thc connoction to tho Cc>>sion bar shall bo t,o thc outboard faco of th anchor plato GILBERT ASSOCIATE~ INC,
clLOVHTASSOCIATES, liC.
Thedesign,materials, fabrication; inspection, andprooftestingofthecontainment vesselcomplieswiththeapplicable partsofthefollowing:
ASMEBoilerandPressureVesselCode,SectionIII-NuclearVessels,SectionVIII-UnfiredPressureVessels,SectionIX-WeldingQualifications.
2.BuildingCodeRequirements forReinforced Concrete(ACI318-63).3.AmericanInstitute ofSteelConstruction Specifications:
a)"Specifications fortheDesign,Fabrication andErectionofStructural SteelforBuildings,"
adoptedApril17,1963.b)"CodeofStandardPracticeforSteelBuildings andBridges,"
revisedFebruary20,1963.4.USASN6.2-1965,"SafetyStandardforDesign,Fabrication andMaintenance ofSteelContainment Structures forStationary NuclearPowerReactors."
5.'CI301-66,"Specifications forStructural ConcreteforBuildings" 6.ASTMC150-64,"Specifications forPortlandCement"7.StateofNewYorkDepartment ofPublicWorksSpecification 5.1.1-10


8.ASTMC260-63T,"Specifications forAir-Entrained Admixtures
ei.bedded  in the side wall Mell away from tho l-3/8 inch diarrater bar.
.forConcrete" 9.ASTMA15-64T,"Specifications forBillet-Steel BarsforConcreteReinforcement" 10.ASTMA305-56T,"Specificat onsforMinimumRequirements forDeformation ofDeformedBarsforConcreteReinforcement" ll.ASTMA408-64T, "Specifications forSpecialLargeSizeDeformedBillet-Steel BarsforConcreteReinforcement" 12.ASTMC94-65,"Recommended PracticeforWinterConcreting" t13.ACI306-66,"Recommended PracticeforWinterConcreting" 14.ACI605-59,"Recommended Practivefor1iotWeatherGoner'eting" 15.ASTMA421-65,"Specifications forUncoatedStress-Relieved WireforPrestressed Concrete" 16.ASTMC29-60,"MethodofTestforUnitWeightofAggregate" 17.ASTMC40-66,"MethodofTestforOrganicImpurities inSandsforConcrete" 18.ASTMC127-59,"MethodofTestforSpecificGravityandAbsorption ofCoarseAggregate" 19.ASTMC128-59,"MethodofTestforSpecificGravityandAbsorption ofFineAggregate" lI 20.ASTMC136-63,"MethodofTestforSieveorScreenAnalysisofFineandCoarseAggregate" 21.ASTMC39-64,"MethodofTestforCompressive StrengthofMoldedConcreteCylinders" 22.ASTNC192-66,"MethodofMakingandCuringConcreteCompression andFlexureTestSpecimens intheLaboratory" 23.ASTMA15-62T,"Specifications forBillet-Steel BarsforConcreteReinforcement" 24.ASTMA408-64,"Specifications, forSpecialLargeSizedDeformedBillet-SteelBarsforConcreteReinforcement" 25.ASTMA432-64,"Specification forDeformedBillet-Steel BarsforConcreteReinforcement with60,000psiMinimumYieldStrength" 26.ASTMC31-65,"MethodofMakingandCuringConcreteCompression andFlexureTestSpecimens intheField",27.ASTMC33-64,"Specifications forConcreteAggregates" 28.ASTMC42-64,"MethodsofSecuring, Preparing, andTestingSpecimens fromHardenedConcreteforCompressive andFlexuralStrengths" 29.ASTMC131-64T,"MethodofTestforAbrasionofCoarseAggregate byUseoftheLosAngelesMachine"5.1.1-12 30.ASTMC138-63,"MethodofTestforWeightperCubicFoot,Yield,andAirContent(Gravimetric) ofConcrete" 31.ASTMC143-58,"MethodofTestforSlumpofPortlandCementConcrete" 32.ASTMC150-65,"Specifications forPortlandCement"33.ASTMC172-54,"MethodofSamplingFreshConcrete" 34.ASTMC231-62,"MethodofTestforAirContentofFreshlyMixedConcretebythePressureMethod"35.ASTMC260-65T,"Specifications forAir-Entrained Admixtures" 36.ASTMC494-62T,"Specifications forChemicalAdmixtures forConcrete" 37.ASTMC173-58,"MethodofTestforAirContentofFreshlyMixedConcretebytheVolumetric Method"38.ACX214-57,"Recommended PracticeforEvaluation ofCompression TestResultsofFieldConcrete"
20+3 LIMITAL CONDUIT Ths metal  conduit for the side;;~ll tendons shall be m-de electrically continuou for their full height 'oy tao!c welding at throaded co>plings. The conduit" shall be bonded togefih"r at approximately Elevation 235 feet and a dire b bond rade to the liner at three locations appro::imate+
~39.ACT315-65,"ManualofStandardPracticeforDetailing Reinforced ConcreteStructures" 40.ACE347-63,"Recommended PracticeforConcreteFormwork" 41.ASTMD287-64,"MethodofTestforAPXGravityofCrudePetroleum andPetroleum Products(Hydrometer Method)5.1.1-13 42.ASTHD97-66,"HethodofTestforPourPoints"43.ASTHD92-66,"HethodofTestforFlashPointbyCleveland OpenCup"44.ASTHD88-56,"MethodofTestforSayboltViscosity" 45.ASTHD937-58,"MethodofTestforConePenetration ofPetroleum" 46.ASTHD512-62T,"MethodsofTestforChlorideIoninIndustrial WaterandIndustrial WasteWater"47.ASTHD1255-65T, "MethodofTestforSulfidesinIndustrial WaterandIndustrial WasteWater"48.ASTMD992-52,"MethodofTestforNitrateIoninIndustrial Water"49.ASTMA442-60T,"Tenta'tive Specifications forCarbonSteelPlateswithImprovedTransition Properties" 50.ASTMA300-63T,"Specifications forSteelPlatesforPressureVesselsforServiceatLowTemperature"
120'part,.'XLDEPiT ASSOCIhT""S) ZiXC.
'1.ASTMA36-63T,"Specifications forStructural Steel"52.SSPC-SP6-63, "Commercial BlastCleaning" 53.SSPC-SP8-63, "Pickling" 54.SSPC-PA1-64, "Shop,FieldandMaintenance Painting5.1.1-14


55.ASTMA322-64A,"Specification forHot-Rolled AlloySteelBars"56.ASTMA29-64,"Specification forGeneralRequirements forHot-Rolled andCold-Finished CarbonandAlloySteelBars"57.ASTMD624-54,"MethodsofTestforTearResistance ofVulcanized Rubber"58.ASTMD676-59T,"MethodofTestforIndentation ofRubberbyMeansofaDurometer" 59.ASTMB412-66T,"MethodofTensionTestingofVulcanized Rubber"60.ASTMD573-53,"MethodofTestforAccelerated AgingofVulcanized RubberbytheOvenMethod"61.ASTMD395-61,"MethodofTestforCompression SetofVulcanized IRubber"62.ASTMD746-64T,"MethodofTestforBrittleness Temperature ofPlasticsandElastomers byImpact"63.ASTMD1149-64,"MethodofTestforAccelerated OzoneCrackingofVulcanized Rubber"64.ASTMD471-66,"MethodofTestforChangeinProperties ofElastomeric Vulcanizates Resulting fromImmersion inLiquids"65'STMA514-65,"Specification forHigh-Yield
9 ADDZHliUH HO. 3 TO TECH!APICAL SPECIFICATIOi~lS FOR STRUCTURhL CONCRETE FOR THE BROGiiVCOD PLAIV. UillT HO+ 1 OF THE ROCHESTER GAS AND ELECTRIC CORPGRATIObl IKCliIESTER>> IWi'/ YCK<
: Strength, QuenchedandTemperedAlloySteelPlate,SuitableforWelding"66.ASTMA441-66T,"Specification forHigh-Strength LowAlloyStructural Manganese VanadiumSteel"5.1.1-15 0
10,0 JOXilTS Ag) EIQEDDED ITi~~"IS 10,3. COI'ISTRUCTIOil XTEHS At  thc end of this seci;ion      dd the follosnng:
67.ASTHA53-65,"Specification forWeldedandSeamlessSteelPipe"68.ASTHA435-65,"HethodandSpecification forUltrasonic TestingandInspection ofSteelPlatesofFireboxandHigherQuality"69.ASTHC177-63,"MethodofTestforThermalConductivity ofMaterials byMeansoftheGuardedHotPlate"70.ASTHC165-54,"MethodofTestforCompressive StrengthofPreformed Block-Type ThermalInsulation" 71.ASTMC355-64,"MethodsofTestforWaterVaporTransmission ofThickMaterials" 72..ASTHC273-61,"MethodofShearTestinFlatwisePlaneofFlatSandwichConstructions orSandwichCores"e73.ASTMD1622-63,"HethodofTestofApparentDensityofRigidCellularPlastics" Thestructural designalsomeetstherequirements established bythe"StateBuildingConstruction Code,"StateofNewYork,1961.5.1.1-16
            "On con  truction joint surface in 'che Containment Vessel including a13. vortical jo5,nts in the cylindrical boll and all joini;s in the dope an epo:qr-resin compound shall be used t,o boind  thc net concrete with the abut~in@ pov~. The
          .epo~-resin compound shall be one of the following:
: a. Epo:o;ice field    Serviciscd Prcducts Corp.
b, Colma Bonding      Compound  Silva Chemical Epotox Bonding Compound      - Toch Brothers, Inc.
Corp'.,
Concrete rurfaco preparation and ~he mixin;~ and application of the epos-resin shall be in accordance with who manu-facturer"s pr'nted instructions. Ego."g-resin cori'pounds o~h"=r than those listed hcroinboforc shall not be used unloss approved by She Engine r."


irTi''.CHblICAL SPICEPIC'ETIO.'t PC:RFUN'IIS~)I>~G PM>UCATZKC AHDi"'iZiCTXhG Si.'hVC'"tH>i3 83."nKLGEE<'ZIi:G~
I I
.11.EXP.1Pa>!XiAfto}V;lFQl'CLIL FGPi'f'i!~IBBERVY.""w~'TT QIMl~JA)NCf.C(J?
PCX'P"8,STATXGH-UltlTI'JCo1GF"'FZRODENT~,GASAf!DR~~ECTRJG CORPORP.TIQH RPv'cSS~x'~
iaaf''UYOiKp~i4cQ&<47O'KCS/19/66Hev>X9/9/661o0SCOPZOP'.~'OZC1'3.GE'i!"VLL Thewn"~tobef.eri'0m'nder thisSubcontract shQ1inclL:doChodetailJ"'lpj fLlz'niah~ijg~
fabrication~
dolxvGPJt~unlclk~rLn~Gtorag8wherenecoo'ary>al'nor~ationofaM~:tructLLral staol>gr'.ting>
Otair"eadaandhwdraU.xeq~~'dfortheRobert8~i..ttGin~aI~ucloarPo:mxS~tion-UnitHoo3.Yce~~xhshan.inc3udebutnotnecessary bolilJ.tedtotheZO3Lo:ri~~:GePro@M;ation ofshopd8t'>ilsQ'."adQr8ctiondrPrP~goo b,Structural
.toolforthoStructures including thaCcntailuent Vee"el~Xntezvp;.die<;e Buildinp~
RectorAu:~r3iary
: Building,
'lie'o3ne f1<m~ServiceBui3dingal'!dFaccdQoThostructural 8tt381consistsof5(1}Cola.n.~(2)Ba88q~ipAn'3LGRrxngplat98(3)ShJ.D'8:,or scttinc,613.bao8w:dbaal"Mirp"wte5(4)23aesiamdpiLdere(5)TL'uGSe8(6)Poets,hw~,gers, tioeand='agrods('7)Strutsandbr~cinrr(8),~Lrlinoand1irt;e())St'ir"-t"1"-.(M)T:olleyb;='~(Wi)L-daces(>'>)ToolQ"-.tea(X3)Connections alldconnoctiol1
{3A)K>>'vota,.~oldeand!1iphotx"~~t;hbolto1))CraneHaila,clipsmdatop"l6)Chcckerccl plate 1
aiLI2>>DKC9/g/66Rev.Ic.Steelgratings,-
gratingwithattached.
plate,gratingstair.treads,anclallrelated'ardware.
d.Handrailforplatforms, wall;waysand.stairs.~q.Shoppaint.1.2LfOBKNOTINCLUDEDThefollowing itemsofwor".associated, withtheplantstructures
=arenotincludedinthisSubcontract butwillbefurnished anderected.byothers:a.Anchorboltsb.Groutingforcolurebaseplatesc.Fieldpaintingd..Steelplate..liners forContainmntVesse3.,Sp"ntFuelPit,Decontamination Pitand.Refueling Canalend.linerpenetration.
2.0SITEDATA2.1LOCATICH'hsitefoxtheRobertEnuattGinnaHuclearPowerStationUnitMo.1islocatedonthesouthshoreofLakeOntario,nearSmokyPoint,inWayneCounty,approximately l8milesnortheast ofRochester, NewYork.TRANSPORTATIOlr Thesitewillbegradedand.anaccessroadprovidedtotheworl;area.Norailfacilities areavailable atthesite.Thenearestrailhead.isapproimatelyfourmilesfromthesite.2.3ACCESSTOMORKA1KAThcContractor willbeprovidedallrquired.and.reasonable accesstotheworl'x+asonsnottoimpcdchisoperations.


&3DXC9/9/66Rev.I2.>'ERVICES AIRFACILITIES Theavailability ofservicesand.facilities forthisSubcontractor willbedetailed.
DEC 2-13-67 ADDHHDUI4 170. 4 TO TI&
bytheContractor, BechtelCorporation.
TECHHXCAL SPECXFXCATXOHS FOR STRUCTURAL CONCRETE FOR THE ROBERT EiYNETT GXHMA HUCLHAR POz/ER PLANT UHXT mo. 1 OF THE ROCHESTER GAS AKiD ELECTRXC CO'RPORATXOH ROCIIESTER, HEN YORK Add the  following additional section:
Generally servicesand.facilities areasfollows:Available Services1.Powerwillbeavailable atexistinglocations at480V.inacapacityupto60amp.Powerreauirements inexcessofthisamountwillrequirespecialconsideration and.adecisionforeachcontract.
"21.0  NATERPROOFXHG 21.1  General The  exterior walls of the Containment Vessel and Auxil-iary Building from the edge of the base mat/ring girder to Elevation 253'-0" shall be waterproofed on the out-side face. The waterproofing material shall be as manufactured by the Plinth':ote Company, llew York, H. Y.,
2.Haterstillbeavailable atexistinplocations.
or approved equal, applied in accordance with the man-ufacturer's printed instructions.
g.Nocompressed airwillbeavailablc.
21.2 Specific Requirements Concrete surfaces shall be dry before applying the water-proofing materials and "hall be free of all zins, ties and similar projections.     All holes, voids and honey-combed ar as shall be filled, patched or repaired to produce a smooth surface.
4.-Fotelephone sex'vicewill'beavailable exceptatthecoinphoneinthePechteloffice-5.Cleanupwillbethexesponsioility ofthesub-contractor andifitlsnotproperlyaccomplished.
The  first. application shall consist of a thin pene-trating coat. of Asphalt Primer applied at the rate of one  gallon per 100 sc[. ft;   Prior to the application of  membrane coux es the angles at   the intersection of GXLBERT ASSOCXATES,   X11C ~
theworkwillbeperformed
'nd.abackchargewrittentocoverthecost.6.Theuseofjobsitecraneswillbeoffered.whentheyarenotinuseonthebase,contractwork.Thisservicewillbebackchargedwithapercentaidedforoverhead,.
iforkandLaydorrnSpaceAdequateworkand.laydovns.oace>rillbc,provided inareasnotacgaccnttothemainbuildings.
Limitedworkandlaydownspacetr9.11bemadeavailablc, depndingonscheduleand.coordination ofcrafts,inthebuildings, andsurrounding areas.OfficeandChanrreAreas.Hoofficespaceorcraftchangei'acilitics willbeprovided.
Portabletoiletfccilitieo srillbcavailsblc.
XKC9/9/66Rev.IJobCoordination Bechtelwillcoordinate ih=siteworkand,directthesubcontractor topromote.harmonyand,providtheoverallbestworksequence.
TheI'Bechtelinspecting engineermayreq,uestand.shallbepermitted.
towitnessallsubcontract worktoassuzeitscontinued.
quality.Thesubcontractor's obligation istoprovideworkmansiaip withintherequiremntsofthespcifications and,tomakedesignated teststoprovequality.3.0STRUCTURAL STEEL3.1SPZCIFXCATXOHS AmCODESAllworkunderthis'ubcontraci shallcomply,exceptasherein-,afterspecified,,
withthefollowing AmricanXnstitute ofSteelConstruction Specifications:
1."Specifications f'rtheD"-sign,I~'abrication and.ErectionofStructural Steelfor33uildings",
adoptedApril17,1963.2."CodeofStandard.
PracticeforSteelBuildings and.Bridges",
revised,February20,1963.3.2NATERXALS Allstructural steelused.intheworkandnotothentise designated.
shallconformtoSpecification forStructura3.
Steel(Tentative)
",ASTNA36-63T.Rivetsteelshallconform'o"Specification forStructural RivetSteel"ASTMAl>sl<<'$8.
HighstrengthboltsshallconformtoSpecification i'orHighStrengthBoltsforStructu;..al SteelJoints,Xncluding SuitableHutsandPlainHardenedSlashers",
ASTblh32$-6'.
r1
&5&DKC9/9/66Rev.IMeldingelectrodes shallbesuitableforthetypeofsteeltubewelded,.TheSubcontractor shallfurnishtheEIIGZZERand.theContractor
/threecopiesofallmilltestreportsand.threecopiesofthereportsofthesteelfbricacor's inspectors forthestructural steelfurnished.
byhimundrthisSubcon'cract.
3r3SHOPAbDFIELDCO>HIECTIOHS Shopassemblyconnections maybeeitherwelded.orriveted,Fieldconnections shallbeeitherwelded.ormadewithhighstrengthboltsexceptforthefollowing itemswhichshallbeeitherweldedorbolted.withstructural gradeboltsr4ithhezagona3.
nuts:1.Allbeamsmarked."Removable" ontheDrawings2.Stairways,
: landings, ladders,etc.3.AllgirtsandroofpurlinsMhenhighstrengthbo3.tsareusedinerectionofsteelformakingpermanent fieldconnections theconnection shall'beinaccordance with"Specifications orAssemblyofStructural JointsUsingHigh/StrengthBolts"issuedbytheResearchCouncilonRivetedand,Bo3.tedJointsoftheEngineringFoundation anddated.khrch3.962.Allweldingshallcomplywiththerequirements oftheSpecifications oftheAmericanInstitute ofSteelConstruction andofthePwericanMeldingSocietyforthetypoofsteeltobewelded..34ERHCTIOi3 TheSubcontractor shallerectallstructural steelfurnished byhimandrequiredforthcplant'building exceptsteelwhichmust/beleftouttemporarily forerectionpurposes.
Taissteelshallbestored.bythcSubcontractor aod.irected bytheContractor and  .MC9/9/66Rev.IerectedbyOthers.Thissteelvillbedesignated ontheDravingsasbeingerected.byOthers.Othrsteel>>illbedesignated onthDravingstobeleftoutltemporarily duringthe,non'nl courseoferectionforerectionpurposesand.tobelatererected.bytheSubcontractor
'beforeheleavesthcjobsite.TheSubcontxactor shallcoordinate hisflOKCviththatofothercontractors andafford.othercontractors reasonable opportunity fortheintroduction oftheirmaterials and,theexecution oftheirvora''.Legibleand.durableerectionmarlinsshould.bepainted.onallmembers.3.$TEMPORARY STEEKFOREHECTIO&#xc3;TheSubcontractor shallattachtohisProposaladravlngshovinganytemporary steelforerectionvhichtheSubcontractor proposestofurnishand,erect.Thedravingshallshovthearrangement forthetemporary steelforerectionand.theloadingthereon.Thisdravringissubjecttorevie'irbytheEHGXlBEB, outsuchxevievdoesnotrelievetheSubcontractor ofhisresponsibility tocomplyvithtncSpecification and,Davings.TheSubcontractor shall,vhenhissteelerectionNOR!Ciscompleted.,
xemoveanytemporary steel,including equipment supporting steel,placed.forerectionpux'poses.
Anyholesinbuildingsteel,resulting fzumconnection oferectionstee3.thereto,shallbepermanently pit~".cdbytheSubcontractor, subjecttothe.approvaloftheContractor.
4.OGRAnxoAHDSTAXnTOADS4.1SPZCXrZCATXO!iS A!JDCODESAllsteelgratingandgratii>gstairtreadsshallconformtothefolio>>ing
)totalGr:tingInstitute Specifications:
I
~7~DEC9/9/66Hev.X1."Standard Specifications forbhtalGratingandVitalGratingTreads",adoptedpctober8p1957..2."CodeofStandard.
Practiceofth>>ihtalGratingInstitute" Allsteelplateshallconformtothcfollorring AmericanInstitute ofSteelConstruction Specifications:
1."Specifications fortheDesign,Fabrication and.ErectionofStructural SteelforBuildings",
adopted.April17,1963.2."CodeofStandardPracticeforSicelBuildings and.Bridges'7 revised.February20,1963.AU.>reldingshallcomplywiththercouirements ofthespcifications oftheAmericanInstitute ofSteelConstruction andoftheAmericanMeldingSocietyforAS'36-63Tsteel.4.2MATERIALS ANDIEQUIBELPK'S Allmaterials forgrating,plates,gratingtreads,clipfasteners, and,tread.boltsand.nutsexclusive ofhold.downstudsandnuts,shallcomplywiththerequirements of"Specifications forStructural Steel",ASTNA36-63T,exceptasother>cise noted.ontheDrawings.
Studs,tobeused.forfastening, shallbe1/4inchdiameter, type'04stainless steelof'roperlength.Nutsto'beused,forfas>>teningshallbesiliconbron.enuts-Allgratingand.gratingtradsshallbeoftheweldedtypewithQopthsasshoranonthedrn~~lngo.
Allgratingand,gratingtreadsunlessothemrise notedont;heDrawingsshallbefabricated.
from3/16inchthiclcbearingbarson1-3/16inchcentersttithspiralcrossbarsweldedon4inchcenters.Allchccliercd steelplateandplainplate,ascalledforonthedrm<ings, shallbeshopweldedtoand,furnished.
sriththegratingpanels. DKCg/g/66Rev-Alltocplateshownattached.
tothegrating,shallbefurn9.shed.
byth9,sSubcontractor andshallbe'nstallcd inthefabrication shopexceptwheretheerectionsequenceneccss9tatcs field.installation.
Allgratingtreadsshallhave1"xg/16inchbearingbars,checkered platenosings,awidthof9-p/4inches,and,lengthsasshownonthedrawings.
Treadsshal3.bcfurnished.
with3/8"x1"cadmiumplated,mach9.neboltsandnuts,fourpertread.,forfastening treadstostairstringers.
Allcutoutsrequired.
forpipes,columns,conduits, etc.shownonthedrawingsshallbeprov9ded.
for9nthegrating.Thedimensions
/ofopeningsshallbeasshownontheDrawings.
The'cutoutsand.openingssmlierthan6inchessha13.bebanded.withbarsofthesamedepthand.thickness asthebearingbars.Thecutoutsand.openings6inchesand.largershallbebandedwith1/LLinchtoeplateprojecting 69nchesabovethefinished, floor.TheSubcontractor shallfurnishade(Luate supportanglesunderthegrat9ngatopenings, wherereauired.
4'$FXEU3CO%'1ECT30&#xc3;S TOSUPPOBTSTEELAllplaingratingpanelsshallbefastenedtothesupporting steelwithL;wostandardsadd3.eclip.,at'achend,ofthepanel,and.withtwoadditional clipstotheintermediate beamwhenthepanel~iscontinuous ovextwospans.Allgratingwithattached.
steelplateshallbefastenedtothesupporting steelwithtwowcldsateachend.ofthepanel,and.twoadditional weldstothcintcxmcc;iatc beanwhenthcpaneliscontinuous overtwospms.


9>>DXC9/9/66Rev.I4.4GALVAi~EIKIIlG Allsteelgrating,attached, plate,stairtreadsandsaddleclipsshallbehotdippedgalvanized inaccordance with"Specifications forHotGalvanized CoatingsonProductsFabricated.
DEC 2-13-67 Page 2 walls and base mat/ring. girder and at corners of any offsets shall be reinxozced with an additional appli-cation of I'.OIifOPOPJ4 compounQ and YELLOW JACYET glass fabric which shall be allowed to tacf" dry prior to the application of the first course. Two plies of membrane waterpz'oofing shall be applied using YELLON SACHET glass fabric embedded in GI1R-100 compound.       The Quantities of components and the rate of application shall be in accordance with the manufacturer's printed
FromRolled,Pressed.and.ForgedSteelShapes,Plates,BarsandStrip",ASTMA123-63,Allfabrication, including cutoutsand,alterations, shallbecompleted beforegalvanizing, 5.0EQ!DHAIL5elMATERII'Allhandrailsha11bemadeof1>>1/4"diameter>
'nstructions xor a hydrostatic head ox 20 feet. >%ere bacl:fill is to be placeQ against the waterproofed sux'-
schedule40standardweight>blackandgalvanized steelpipeandfittingsconforming to"Specification forBlackand.Elot-Dipped ZincCoated.(Galvanized)
faces, panels shall be'urnished and installed to pro-tect the membrane. These panels shall be 1/2." thief Plintfcote asphalt coated insulation panels attached to the membrane arith spots o - asphalt plastic cement.
UeldedandSeamlessSteelPipeforOrdinaryUses">ASTMA120-63T.Allhandrailshallhaveonerailcenterline 2'-0"abovethefinished.
GXLBERT jASSOCXATES, XMC.
floorleveland,asecondrailcenterline3'-6"abovethefinishedfloorexceptwherenotedothertrise ontheDrawings.
Thepostsshallbespaced,not'morethan8'-0".oncenters.All1handrailshallbeinaccordance withthetypicalhandraildetail.shownontheDrawings, Allpointsshallbeweldedand,groundtoasmoothfinish.TurnsshallbemaLebytheuseoftubeturnsorpipebendsandallrailingextending beyond.thcpostsshallbeterminated withdrive>>inplugs.5.2FIELDCO&#xc3;lECTIOi~!S Allhandrailpostsshallbebolted,tothestructural steelsupporting thefloorgrating,exceptwhereshownothe'>ise ontheDrawings.
Allhandrailpostssetinconcreteshellbeset


~~-10-DZC9/g/66Rev.Iinoleevespxovidedbyotherswiththeconcreteslabsand.shallbesecured.inplacewithmolten1cadorsulphur.Allbolts,nutsand.clipanglesrequiredforfastening thehand-railpoststothestructural steelshall'befurnished.
V
bythisSubcontractor.
~ ~                                                                                      DEC
Allhandrailindicated onDrawingsaoremovable, orfastened.
~     ~
toremovable steelframing,shallhaveJointsatappropriate placesand.bebolted.foreasyremovalofsectionssoindicated.
3.0-3.t-67 O
Allhandrailrunningintobracingand.columnswillbefield.'cut and.weldedtofit,.All>>eldingshallcomplywiththereouiremento oftheAmericanInstitute ofSteelConstruction and,oftheAmericanMeldingSociety.6.0PAIi'KING Allstructural steeland.handrailtobefurnished underthisSub-contract, shallbecleaned.ofrustormillscaleinaccordance withtheSteelStructures PaintingCouncilSurfaceCleaningSpecifications SSPC-SP2-6g"Hand.Cleanjngi'nd/oi SSPC"SP3-6g"PowerToolCleaning",
ADDEi'Kv'!i 'lO. 5 TO
asrequired.
                                        = TECHIiXCP L S~i";CXI 1CAT3 0"S FOR STRUC'TURAX, COZCRVr=
Paintshallbeomitted.atallareasoffieldweldingand.onallsteelsurfaces>>hich willbeincontactwithconcrete.
FOR THE BROO'C:.OOD    'KIlT      U~IXT I'IO.
Allcontactsurfacesofconnections shallbepainted.,
ROCHE"'STER, Gi.S P.ilD i"'LKTRXC CORPO~d<TXOlJ RQC;l~iv<ig    r J,'i:;I 3'Qg' Md tahe folloi'll'p~ sect 1oil:
including thosefortrussesandplategirders.Allstructural steelandhandrail, tobefurnished underthisSub-contract, shallreceiveoneshopcoatofpaintwhichohallbeoneofthefollowing:
              "22. 0  Pr".uP'.KT CO<~tCRKT",
e    'Nec caied on the        Drair ~a.-s.   'hrv "turn x'equ>.re.".';cps for PRZPA'i(T COil"ZTE sha3.:L be iri accordance;ri&#xc3;a ~he "Guide SpecJ.-
fications for .'".:"'PAiii'Oi<CPU~'Z" as p:.'e"..ared by tne Prepa!N, Concrete Compmry, Cr.evclsad, Oh~ o, a copy of
                      .'.l3 ch 1 s al't L ac'1 - d Rex'etto as pa 4 of tt.'1" s spec" f3.cat1on


lEC9/9/66'Hev~I1.Socony-Valdura 13-Y-5ZincChromatePrimer2.GliddcnHGL32802ZincChromatePrimer3.Pennsbury YellowZincChromatePrimerKeelerZoLongIfo.4800ExteriorOrangeLead.PrimerTheshoppaintshallbemixed,and.appliedinaccordance withtheSteelStructures PaintincCouncil's PaintSpcification SSPC-PA1-64."Shop,Pieldandihintenance Painting".
                                                                        '. I  a.0.
Shoppaintshallhaveedryfilmthickness of2mils.PieldpaintwillbebyOthers.7.0SHOPAi~TDEHECTXONDHJGlZi''.OS TneSub-contractor shallsubmittotheEnginer,forhisapproval, onereproducible copyandoneprintofallshopand.erectiondrawings, datasheets,etc.reauiredforhis>lOHK.Twocopiesofalldrawings, etc.shallalso'besubmitted.
70 Ianna  ia  ar l    ~ ~    I", .) I'I,,            I,          r,    ~ a,   ar      >a  ~  Aa iraaa" i a'Jaa avgas
concurrently t,ollestinghouse AtomicPowerDivision.
    'I        'I  a.h'A.:,1        . I',        I I'a      s''Ir.h            I~ I t  " 1, 'a:                ~ra    a aalu'I
Thisshallbedonewithsuchpromptness astocausenodelayineitherhisHOK(orthatofanyothrcontractor.
                                                                                                                              ~  Iaa j    I ';    a ~
Thesedrawingsshallbecheckedand.certified, priortosubmission, andshallcontainallrequired.
AU j      (,   Ic1 lghaahhh iaQ~.I. IiarY          !.'haa,'~i'I          ~
information.
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TheSubcontractor shallmakeanycorrections required.
                                                                  ~~
bytheEngineerand.filewiththcEngineerand.theMesting-houseAtomicPowerDivisiontwocopieseachofthe'corrected.
a    I .:<r~:    (a    ~ ~
drawings.
I
: Approved, drawingswillbesostampedand.dated.and.shallformapartoftheSubcontract.
                                                                                                          )fh)h,,
Onesetoftheapproveddrawingswillbereturned.
                                                                                                          .       ~ ~a        ri( 'a'  I
totheSubcontxactor.
                                                                                                                                            ~
ApprovalofsuchdrawingsshallnotrelievetheSubcontractor oftheresponsibility fordeviation fromtheContractDocumnts,norfromresponsibilities forerrorsinshop-orerectiondrawings, DXC9/9/66ReveX8.0RECORDDBAIGI<GS Uponcompletion ofhisworktheSubcontractor shallsubmittotheEngineeracompletesetofcQ3.drawingsforthework.Thesedrawingsshallcorrectly indicatethework"asbuilt"andshallincludeallmodifications oftheworkandadditions theretowhichhavebeenin--corporated.
aa~.           I.II'.:aDq!:r'I'~ <'.
Thedrawingsshallconsistofapproveddrawings, legiblymarked,andsubmitted oneprintand.onereproducible eachtotheEngineerandtheMestinghouse AtomicPowerDivision.
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9.0XHSTALLATXOI'I ADDXIlSPECTXOH PHGCEDUBES TheSubcontractor shallsubmittotheEngineerawritten,detaileddescription ofhisinspection and/orinstallation procedures forcommntsand,review.Theseprocedures shall'besubmitted atleastetwoweekspriortoactualstartofMOHI(.Anycommnts'bytheEngineershallinnowayrelievetheContractor ofhisresponsibility toe.".ecute hisNOBKtomeettheintentoftheDrawingsandSpecifications.
                                                ~          +; i'."h
~~iKC9/9/66LISTOFDR/8JIi.GS Thcfolio>Iing GilbertAssociatcsp Inc.dra~7ings setforththelocationandextentoftheWORKtobedoneandareherebye::pressly madeapartofthisSpecification:
                                                        'Ia'        ~    'ra q ' 0
DRA>1I1',G PO.D-502-0U.
                                                                              ~
D-502-021 D-502-022 D<<502-023 D-502-031 D-502-051 D-502-052 D-502-061 D-502-062 D-502-063 D-502-064 D-502-065 D-502-066 D-502-071 D-502-072 D-502-073 D-502-074 TITLETurbineArea>>Steel FramingColumnSchedule5BasePlateDtailskezzmineFloorElcv.271'-0"Operating FloorElev.2S9'-6"ControlRoom<<Plans&Elevations Platforms, Landings5StairsTopChord,HoofPlanBottomChordRoof'lanLongitudinal SectionSouthElevation EastElevation NestElevation CrossSectionCrossBracingBelowOperating FloorGirts-HorthElevation Girts-SouthElevation Girls-EastElevation Girts-HestElevation D-521-001 D-521-002 Containment Vcsse3.<<SteelFramin,ColumnScheduleIntermediate FloorElev.253I
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DKC9/9/66DBAWIEGIip.D-521-003 D-521<<005 TITLEOperating FloorElevations 270'<<4"8:274'-6"Msc.Platforms Elev.267'-3",Elev.300'-4"8cStairDetailsD-521-011 CraneRumrayElev.331'-0"Forced.Stxucture
ADDENDPi1 NO.
-SteelFramin'-521-071 D-521"072 D-521-073 D-521-074 EastElevation
TO TECHNICAL SPECIFICATIONS I"OR STRUCTURAL CONCRETE FOR THE BROOlSJOOD PLP~VZ UNIT Iso 1 ROCHESTER GAS AM) ELECTRIC CO~iRATXON ROCHESTER, m: r YORK 10 1 JOINTS QS EllBEDDZD  ITEM 10+2   EXP(QJSION JOINTS At the cnd 'of this subsection; insert the    fol3.owing:
-Columns,GirtsZcBracingWestElevation
                "The sealant  for all  expansion joints crithin the Conta~'>ment Vessel shall be  Do:J Corning 780 Builds.ng Se 3~.ant as manufactured by Doe Corning  Corporation."
-Columns,Gixt's,&BracingNorthL'lcvation
-Columns,Gix'ts&BracingSouthElevation
-Colums,Girts&BracingD-522-001 D<<522-031 D-522-041 D-522-051 ReactorAuxiliarBuilcU.ng
-SteelFxaminlColumnSchedule8:Bracingllisc.Steel8:StairDtailsRoofSteel8;CraneRunsrayElev.306'-10"GirtElevations D-523<<011 D-523-021 D-523-022 D-523-023 3051Xntermediate Building-SteelFramingColumnSchedulePlatformElcvations 271'-0"8:278'-4"PlatformElevations 293'-0"8:2g8'-4"PlatformElcvations 315'>>4"L-Roof317'-6"RoofElev.335'-4"8:StairDetailsD-531-001 D-531<<002 ServiceBuilding-SteelFramingCol~~Schedule8:B"sePlateDetailsIhcanineFloorElev.262'-21/2",FloorElcv.271'<<0"8:Rooi'  
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DEC f s I ef                                                                              2-28-69 PHELBIZI8'Z<7 ADDEI DKI KO. 9 TO TECIKZCAL SPECZFZCATZOIIS FOR STRUCTURAL COi'CRETE FOR TIF BROOIG'IGOD    PI/ill,'IITT I'!0. 1 ROCh' THP. G IS fiND EL>CTRiC CORPORATZOil ROCHESLM~ iv"8'f YOIIK Deleie Sec'~ion 21.0   VATERPROOFZKG        in its entirety  and insert the following:
)nsul'iric:.
        "m.o iu,r npRoo".xtr/wire piicozxw, 21.'"ncral Tne e:c'ccrior wall of the Auxiliar Building from the edge of the base mat to Elevation 25)'-0" and the elherior wall of the Cont~i.n!aent Vessel from the edge of the ring girdor io Elevation 235'-0" shall be waterproofecl on the outside face. The water-proofing material shall be as mmufac~ured by the Flin~kote Compa!Iy, I<a:r YorI<, I'Iew Yor!c, or approved equa1, applied in accordance w:ith the manufacturers printed instructions. The exterior wall of the Cont, inment Ve sel from Elevation 235'-0" to Elevation 253 -0" shall bc dnwpproofed using PZIJ Iiarine lfastic HD as manufactured! by Toch l3ros. Znc., Paterson, New Jersey, or approved equal~ applied in accordance Itri4h the mtu!ufacturer's
-03:0'ol,.cedver';ic.3.ljaf<<r'l013Ga!1(lcorizonv.>.i,<<"urldersl(<<~o.011pre!(>e'}1G].,l0;:,".Wdod 0'.<<;vg->>'.'n.':t-OniOOcrc}aSr~,n>:.f.::;Cl;l)X Co!r>>):12<<>>'h>'nsu.Li;:i'>.Ox 3;oi'.ri.>2-')3.1 3)eone:322C.!
                      'printed instruct'rions      ~
t.".ns.i<<lied ir!!ccordalice lait!2ti!0rr>anufa(:tl>rcr' el~:lil>stt10fou'1(iriv'Ci!10St:>xofo"",!
21.2    'klaCs~r~rooi'in  ~
SBcd>)!~v}20Dov>C}rer.".ic:.:"..
Rooniromsnss Concrete surfaces sha11 be dry before applying the waterproofi~i materials a!id shall be free of all fins, ties and similar pro-joctions. All holes, voids and. honeycombed areas shall be filled, patched or repaired tn produce a smooth surface.
ic};"n(c:;}lell 3)clit8(}:>.r!Q
Tho  first application        shall consist, of a thin penetrating coat of   Asphalt, Primer applied at, the xato        of ono ga1.1on per 100 sq.
'uruCt'n8l<$.0<,lJflL'ETX C(X'3'F"r(OL FgPF''10'L<.">.'.i!i:ttX TjSTSTrr<<>".mcv'1r<<ej,Qu<<GG, t/)r,'icpo;;8(1)./isis'c';illol:val0v,<<nSerijcesof.":.Tc"-'vina L<<'.'Cr-torY
ft,. Prior to tho application of membrane course,. tho angles aC tho intersection of walls and base mat/ring girdor and at corners of any offsets;;i!a3.1 be reinforced with an additional application of IIOIIOFORII compound a!!d XELLO'I JACI(ET Glass fab! ic which shall bc allow d to taclc dry prior to thc applicat,ion of the first course. Two p3.ies of mcm'oran,"; wat, rproofir r .,hal3. bc applied using Xx'LLQl JACIG:T glas fabric embedded in Gi".;1-3.00 compound. Tho quantities of components and who rate of app3.ication shall bc in accorclancc with the manufacturcx's pI'intcd instructions for a h~xl::ostatic head of .20 feet.s. Nhere baclcfill is to bo placed against thc watcrproofcd surfaces, panols shall bo furnished and inst;allcd to pro~oct, the membrane. Ti!c e pa!!cia hall bo 1/2" Chic!c Flintlcot,c asphalt coated insul, tion panels aM;ached t,'o thc ll% lbranc Ifitll spot, of asphalt; pla tie ccmenh
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>71(CGvilli})(dc'vcl"."ii.ned by>c!Oti}206 2ofS<)c""ion 3wofl'ro!>sed flC.':303."Xrc!".,"}!croin'Co>ore Gpacii'iod.
3~8T}28.".ngineer G}1.3.3.3!nveth8).ig}rtz1Gj(oe(jJrsiv'!.ents incol!Cxic'iepro@Dr"iOils"fn-CCG>GX'y'torlree"t<<'10ro(,'uireb<<"-Iltrs 0ftr!1CGNGOecifi0'<<t<<}.0210>>
Jn62event;5!cCcn'vrector x'uxnisrlod reli(l'ol(
vestrocordsofcotlcr~'rzdev>l.thrr.;1'ueli;lG fx(>11d!eGcmcso!:locoendoftjlcG.".mQui~liv<<illcoMoc'~to!1
'iJ1cu!'10'1'vrror;ip'Glenill3.ox'lpcs'troft18Gtrle!1P';jt>csv<8r,l)c<<-."ie(j31,.);1-',
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!Oi"8'e'!'io Gll)~')rcdisiorlsi'ntc!cc-n'h':1y(rfbx>.ldinp cc(!88orCi'J3nan>ces(i'4GF8f~oVel'rli.'1>c',:!Qtr}!OX'i ty~'j>>FjFFc,r>>>>rc'wn',",
F;~)s''i':owe!Qlrw'FFee''Fnri'>}1~>F"'r<<>'~~3}ll.<<)r~c>>>>>~Ci0i3)4)%(ilCic4<<1'Fr(>(V10,i}reC)l(iG>>)rl)JF(~(t'<<rllV~',*<<)\CC3,'1>I1rt>w~~ir'W'i~~>+~I(".!.C"8' ill>.r'".
'.t'orl".'.)".'.'"..G')"(
t:)':"uV'C.V.:1'vrro ii'.('1P'0<</,1~~'F~c8>,~>~~l1lr>~~%t\F',',<<d(F(F(>.~1><<c<<X(F>1l'>"">7~~C'ice"")E;>
'.<".C'r"(lu'C01C"ncc'.~11<<'."~K<<'"0(>'l(.l.'<<',}(XC>1'"'F.11.>>!'1:.";.'1 Or.1"0(.;p('"<<"..>)
'.'<<G><<'>>l!0>>!
)ll'.1.i'(~O!
p3':(:C'.!!F(.,"r~1l,><<1"~l'>FOC1<<-'1<<,1F>a')(,'1,',Fil':'r,l;'>r,(>>>>(>1r.}i<<';$'S 8end"'r."remxi!)in'v'>.'o cylin<!Crs ab2!3d:.!ys.Slunntc.",;;s;vill L.mode:.vr!!di.!i".,!).".minimu)>.
ofonotesvforeachlOcubic.-"!resGl&#x17d;@nore"Gpic"..Gd,alsos3.))irpt>est".i.illbonadconvhcconc'."'>o ber'chusedfo.~".s'vcylinders.
lj~"~(l)+81Gin'>)he'..venCv>)!LvcoRcrebeisg3!!reddil:.'1!)~P f:".CGA:>.ng v>SGthero"Qa'v"frcezeise::o-.cv'd
(!ia";:;n,;"Qc rurin;-sriod,"naddi>'io))al cy..iI;d'::
'.)i3.7.'o.".'>-!ds fore,".chsotendbecur.dund(QLA')J~icondit>ion8t.>e3hl'iOf'3he~'vrut>i)"(L>ic:h).t>l'o"4QsenG19,3Ti)SVj;il!1,!JATOS(Xf T!)esvsluc)tion cf".3v'"Gsults">"'l)oin-"ccord!x)ce
.'i'~!)ChQD~v1'(of~ropose'.t
.-".:T.331.Gufficint,i)ss'i)s'.illbeconducted toprovidean::vel.:..>>"..On ofconcrevestrengti) inaccord::,nce
)'!iththissgccificQt>ion
~19.4-Ear.Cr:t;:T C:":'CJL.:.".'.
)ihenever 3.'c".s".";..':
~!)e'est, or"t::~e7x)boretory cilr,".dcylinders feilcomeeti'>))crogvirc>m absetfol'hin5)isspecif>c:>t>ion.
Q!elepineerendforTosh.ngLs>borewrg SI)OilhRvcthcr'.-".)b8tv))eConh~'ecvox'ezc>'n>se
*">0cP-dOraerch;;,)L!es
$a'thopzopoltionsor",.themixtoincrc~seta>>sCrengt!loHe!U7xeo'dQ.-'ona"i'estsofsp"ci!Iens curedea>tirely
))ndexficldcondi'a.o)>s.
Ordexchargestoimproveprocedures forp)'objecting andcurin(!v!sconcrete.
'7G()uiro eddivien<!1iceto>3.nsccordsncc
">it>)'.G%:lods ofObi(ei));.>
snG'Resti).rigl>'.GdCores:aco"'>xeQ)."G"PsofC')cro'"'!
'ia"..'e.CJ!2-6)!!(,/If>>:).:5~yU'ZQlec.'.Ors!>>Gn Y>.o).Gc.testsf>)~.~.topl'ovsconcre'('>o i.>ox'i2)Gspcc3.f3.ed oil!iJ.".5';Tpt>hcthecoriclc'ce)orl;-;s'direct,".d.,
':.llctShetl!",'1thecus~.on.".ble Co)3)'iiectox'63>'pBI?SG ADVEKPi4HOelTOTEC!iNICAL SI'LCXFICATXQNS FOR~STRUCTUI.W~.
CaNCaWEFOILTf!EBROOKNOOD PI%MTUNITNO<lOFTIIEROC'rIESTEIK GASANDFLEC&ilCCORPORATION ROCHES'LYB IENYORK4.0Cl"'ZATSecondlineafterthewords"TyI~~XI"insert"for@odorateAM@ofhydration"
~8,0FOiBDOi>X SolGENERALAttheendofthisectionaddthofo3>.owing:
"Allox!closed edgesshallbechmferedo Thosizeofthech"mt'erstripshallbe3/l.Mchesunle.sotherwise notedontheDra'ringso" 30.0JOIKTSANDQIHEDDEDXTI<S10elCONSTPUCTXOR ITIR!SAttheendofthissectionaddthefol3.owing:
"Construction JointsurfacesshallboI>re~cdforthoplacejfent ofccncretethereonbycleaningthoroughly witht>irebrushes,cantorunderpres"ure, orother!>canstoremoveal3.coatings~
stains,debrisorotherforeignnt;eriaD.~"lOo4AIIClIORBOLTSAI'3)PXPF81Z~/EQAtthoendofthissectionM~dthefolios>ings "E>l:bedded itemsshallbochccIcedforlineandgradoafterconcreteisplaced"lloOI!LKINDCQk'CRETE ll2TRANSITI4LXXKGAtthoendofthissectionaddthofollowing:
"AsrccIuirod byAS'Q)C<)4-65a33.truclcsshallbocquiI>pod'ith arevolu,t,ion countor."
\
~<<2<<<<11~6BATCHRECORDAttheendofthissect,ionaddthefollowing:
uAsroquiedbyASTk~C9$-6gthbatcht,ickotsha'U.alsoincludethetin.eloaded,amountorconcreteandreadingofrevolution counteratfirstaddit,ion of.';atero"
,14oOCURIL'QAND5'ROTECTIOW Curingv;-thodsdetailedinACI301<<66shallbousedcvzop5thaCamethodotherthanusingacuringcompoundshallbeusedforinitialandfinalcuringofconcretointhecontainnen~
shello19oOQDALXTXCOHTBOL19<1PiKLQQHARY TESTSInthesscondparagraph change"Section309"to"Section308",192FIELDTESTSAttheendofthethirdpmag.aohaddthefolio:wag.
"Thiscylindorsisalbebosomedat'8days"Addthefollowing addit;ional section.'~20 oOle%RThechloridecontent,ofai.ing~mtershallnotexceed100p~>andturbid55y shaU.notexceed2000cpm."
DYE10.-17-66 Revisedli-3-67ADDENDUMIIO.TOTECHNICAL SPECIFICATIONS FORSTRUCTURAL CONCRETEFORTHEBR03iY'iOOD PLANTUIGTI'IOo1OFTIIEROCHESTER GA5A.'JDELECTill'C CORPORATION ROCHESTER~
M"U'lORKAddthefolloii~g section:"20.0'RGUi'JDXIlO 20olCONCRETEREXI'PORTENT Allconcretoreinforcerrent embeddedinthesidewalluptoElevation 252'eetslnllbemadeeloctrically continuo:is bybondingallsuchitemstogetherbymeansoftheCAD::IELD processArcweldingconcretoreinforcement, foranypurposeincluding Choachievement ofelectrical cn>>tinuity shallnotbepermitted unlessnot,odotheria.se onCheDrawings.
StandardCAD<'IElJ3 poridershallbeusedtoireldcopp..rtostocloThe,tio3dingmaterialshallconsistofacopperthormitmixturemploying tinmtalinanamounttoeffectively constitute from~i.5percentto5~5percentoft,horesulting weldmetal.PiortoCADllELDL~IG thesufacofthcroinforcoz ntshallbecleanedfreeofrustandrillscaleandfiledwithacoarsefileorgrindingwneeloEveryprecaution snailbetalcontoremoveonlyCheminima~petalrequiredtoobtainasmoothsurface.TheCAD'v.'ELD processshaU.beperformed inaccordance irlththenmufacturer~s printed.instructions.
Thoconcretereinforcement shallbe>r~ideelectrically continuous atamnimumofth."eeloationsprcircumferential ringorverticalbarandshalloobondedtothecontairment lineratthreelocationapproximately 120'part.
Thebond,connection tothoroinforcomsnC shallbostaggered intheverticalandhorisontal dirccCions Coprovideaminimumdistancebetweenconnoct,ions offivefoot.Thostaggered patternshaU.berepeatednomorefrequntlythanforeveryfifthbar.ThcCADYKLDspliceusedfor1I,.SandlQSbarswillprovideelectrical continuity.
20o2Tl<iIISION BARSThetensionbarss)iallbebondodtogothorbytheCADUELDprocessa>>dadi".'ct.bond;sado tothocontainment li>>oratthroelocations ipproximatoly 1"0"apart.Thcconnoction tothoCc>>sionbarshallbot,othcoutboardfacoofthanchorplatoGILBERTASSOCIATE~
: INC, ei.bedded inthesidewallMellawayfromthol-3/8inchdiarrater bar.20+3LIMITALCONDUITThsmetalconduitfortheside;;~ll tendonsshallbem-deelectrically continuou fortheirfullheight'oytao!cweldingatthroadedco>plings.
Theconduit"shallbebondedtogefih"r atapproximately Elevation 235feetandadirebbondradetothelineratthreelocations appro::imate+
120'part,.'XLDEPiT ASSOCIhT""S)
ZiXC.
9ADDZHliUH HO.3TOTECH!APICAL SPECIFICATIOi~lS FORSTRUCTURhL CONCRETEFORTHEBROGiiVCOD PLAIV.UillTHO+1OFTHEROCHESTER GASANDELECTRICCORPGRATIObl IKCliIESTER>>
IWi'/YCK<10,0JOXilTSAg)EIQEDDEDITi~~"IS10,3.COI'ISTRUCTIOil XTEHSAtthcendofthisseci;ionddthefollosnng:
"Oncontructionjointsurfacein'cheContainment Vesselincluding a13.vorticaljo5,ntsinthecylindrical bollandalljoini;sinthedopeanepo:qr-resin compoundshallbeusedt,oboindthcnetconcretewiththeabut~in@pov~.The.epo~-resin compoundshallbeoneofthefollowing:
a.Epo:o;ice field-Serviciscd PrcductsCorp.b,ColmaBondingCompound-SilvaChemicalCorp'.,EpotoxBondingCompound-TochBrothers, Inc.Concreterurfacopreparation and~hemixin;~andapplication oftheepos-resin shallbeinaccordance withwhomanu-facturer"s pr'ntedinstructions.
Ego."g-resin cori'pounds o~h"=rthanthoselistedhcroinboforc shallnotbeusedunlossapprovedbySheEnginer."
II DEC2-13-67ADDHHDUI4 170.4TOTI&TECHHXCAL SPECXFXCATXOHS FORSTRUCTURAL CONCRETEFORTHEROBERTEiYNETTGXHMAHUCLHARPOz/ERPLANTUHXTmo.1OFTHEROCHESTER GASAKiDELECTRXCCO'RPORATXOH ROCIIESTER, HENYORKAddthefollowing additional section:"21.0NATERPROOFXHG 21.1GeneralTheexteriorwallsoftheContainment VesselandAuxil-iaryBuildingfromtheedgeofthebasemat/ringgirdertoElevation 253'-0"shallbewaterproofed ontheout-sideface.Thewaterproofing materialshallbeasmanufactured bythePlinth':ote Company,llewYork,H.Y.,orapprovedequal,appliedinaccordance withtheman-ufacturer's printedinstructions.
21.2SpecificRequirements Concretesurfacesshallbedrybeforeapplyingthewater-proofingmaterials and"hallbefreeofallzins,tiesandsimilarprojections.
Allholes,voidsandhoney-combedarasshallbefilled,patchedorrepairedtoproduceasmoothsurface.Thefirst.application shallconsistofathinpene-tratingcoat.ofAsphaltPrimerappliedattherateofonegallonper100sc[.ft;Priortotheapplication ofmembranecouxestheanglesattheintersection ofGXLBERTASSOCXATES, X11C~
DEC2-13-67Page2wallsandbasemat/ring.
girderandatcornersofanyoffsetsshallbereinxozced withanadditional appli-cationofI'.OIifOPOPJ4 compounQandYELLOWJACYETglassfabricwhichshallbeallowedtotacf"drypriortotheapplication ofthefirstcourse.Twopliesofmembranewaterpz'oofing shallbeappliedusingYELLONSACHETglassfabricembeddedinGI1R-100compound.
TheQuantities ofcomponents andtherateofapplication shallbeinaccordance withthemanufacturer's printed'nstructions xorahydrostatic headox20feet.>%erebacl:fill istobeplaceQagainstthewaterproofed sux'-faces,panelsshallbe'urnished andinstalled topro-tectthemembrane.
Thesepanelsshallbe1/2."thiefPlintfcote asphaltcoatedinsulation panelsattachedtothemembranearithspotso-asphaltplasticcement.GXLBERTjASSOCXATES, XMC.


V~~~~DEC3.0-3.t-67 OADDEi'Kv'!i
      ~ ~
'lO.5TO=TECHIiXCP LS~i";CXI1CAT30"SFORSTRUC'TURAX, COZCRVr=FORTHEBROO'C:.OOD
gi C                                                                DKC r
'KIlTU~IXTI'IO.ROCHE"'STER, Gi.SP.ilDi"'LKTRXC CORPO~d<TXOlJ RQC;l~iv<ig rJ,'i:;I3'Qg'Mdtahefolloi'll'p~
2-28-6g Page 2 e  Qt
sect1oil:"22.0Pr".uP'.KT CO<~tCRKT",
: 21. g Dooooo~roof i ~Rsqairemont o Concrete .urfaccs      hall b. dry bcforc applying the dw~. pproofing TiMterivQQ and sha33. be  free of all f'ns tios and sire.lar pro sections.     All holes, voids and honeycombed areas shall b filled, patched or rcpaircd to produce a nlooth surface. All suri'aces shall bo free of dirt, dust, ice etc. Apply tlTo spray coats of RBJ 4'arine iAouid DCcD to a total th>>el<ness of l/o inch over thc elltil'e Ms33  area o
e'NeccaiedontheDrair~a.-s.'hrv"turnx'equ>.re.".';cps forPRZPA'i(T COil"ZTEsha3.:Lbeiriaccordance;ri&#xc3;a
~he"GuideSpecJ.-fications for.'".:"'PAiii'Oi<CPU~'Z" asp:.'e"..ared bytnePrepa!N,ConcreteCompmry,Cr.evclsad, Oh~o,acopyof.'.l3ch1sal'tLac'1-dRex'ettoaspa4oftt.'1"sspec"f3.cat1on


'.Ia.0.70Iannaiaarl~~I",.)I'I,,I,r,~a,ar>a~Aairaaa"ia'Jaa'I'Ia.h'A.:,1
Qi:
.I',II'as''Ir.hI~It"1,'a:~raa~IaajI';a~AUj(,Ic1lghaahhh~avgas~~jwa'(a~~)fh)h,,~iaQ~.I.IiarY!.'haa,'~i'I h(:~II'.aI.:<r~:I.~~ari(I'a'aa~.I.II'.:aDq!:r'I'~
Ji J
<'.h"~xa+;i'."hq0II'(I~'ahaalu'IAh''ah''aaf~raaarI,La~~;,Ialai(J('Ia'~'ra~'~rrarI"I~'4'J~Iar~~IAa~~.;':~'';.:j4Ia'/rvia''vwa a"I~I,',ara~rIa)~'v'4a'J'I~~riv'~a~v'va're2IIQCO'aCel'"~~~'a'~~v~~aIpavaraI~I6~rahiiiaI~Vr'0"(!;)GArah13I.A~1!'0"i'I'3!''aJi>a1IIS>'3=~)'~~.ID(:
0}}
'Ura1"..'i'I.'aYH~1I1I'a)ha~a'I"1.)1.'aalu)h1"jh<<'i'qaJ~'a.jA'a)I~aOph')t1hha5I'ah'I~f"I~Ia)I/hi ADDENDPi1 NO.TOTECHNICAL SPECIFICATIONS I"ORSTRUCTURAL CONCRETEFORTHEBROOlSJOOD PLP~VZUNITIso1ROCHESTER GASAM)ELECTRICCO~iRATXON ROCHESTER, m:rYORK101JOINTSQSEllBEDDZD ITEM10+2EXP(QJSION JOINTSAtthecnd'ofthissubsection; insertthefol3.owing:
"Thesealantforallexpansion jointscrithintheConta~'>ment VesselshallbeDo:JCorning780Builds.ng Se3~.antasmanufactured byDoeCorningCorporation."
~~4g,gPiiHLXIQi'JAP.Y ADDEIBUII I'IOo8TOTECHNICAL SKCXPICATXOIG POQSTRUCTUML
: CONCRETE, I"OR'TI.rSBROG.QSOOD PIAiiITUIGTMOs1ROCIDSlaR GASAPJDEJ~~CTMCCOliPOHATZ01I ROCHESlM~
IE'3'I'XOiHiAStheendofSection22.0PMPAKTCONCRETr",'dd 440folloTAllge 4P"Thereshal1benoretemperu~
ofPrepakbConcrete."
fsIefDEC2-28-69PHELBIZI8'Z<7 ADDEIDKIKO.9TOTECIKZCAL SPECZFZCATZOIIS FORSTRUCTURAL COi'CRETE FORTIFBROOIG'IGOD PI/ill,'IITT I'!0.1ROCh&#x17d;THP.GISfiNDEL>CTRiCCORPORATZOil ROCHESLM~
iv"8'fYOIIKDeleieSec'~ion21.0VATERPROOFZKG initsentiretyandinsertthefollowing:
"m.oiu,rnpRoo".xtr/wire
: piicozxw, 21.1'"ncralTnee:c'ccrior walloftheAuxiliarBuildingfromtheedgeofthebasemattoElevation 25)'-0"andtheelheriorwalloftheCont~i.n!aent VesselfromtheedgeoftheringgirdorioElevation 235'-0"shallbewaterproofecl ontheoutsideface.Thewater-proofingmaterialshallbeasmmufac~ured bytheFlin~kote Compa!Iy, I<a:rYorI<,I'IewYor!c,orapprovedequa1,appliedinaccordance w:iththemanufacturers printedinstructions.
TheexteriorwalloftheCont,inmentVeselfromElevation 235'-0"toElevation 253-0"shallbcdnwpproofed usingPZIJIiarinelfasticHDasmanufactured!
byTochl3ros.Znc.,Paterson, NewJersey,orapprovedequal~appliedinaccordance Itri4hthemtu!ufacturer's
'printedinstruct'rions
~21.2'klaCs~r~rooi'in
~Rooniromsnss Concretesurfacessha11bedrybeforeapplyingthewaterproofi~i materials a!idshallbefreeofallfins,tiesandsimilarpro-joctions.
Allholes,voidsand.honeycombed areasshallbefilled,patchedorrepairedtnproduceasmoothsurface.Thofirstapplication shallconsist,ofathinpenetrating coatofAsphalt,Primerappliedat,thexatoofonoga1.1onper100sq.ft,.Priortothoapplication ofmembranecourse,.thoanglesaCthointersection ofwallsandbasemat/ringgirdorandatcornersofanyoffsets;;i!a3.1 bereinforced withanadditional application ofIIOIIOFORII compounda!!dXELLO'IJACI(ETGlassfab!icwhichshallbcallowdtotaclcdrypriortothcapplicat,ion ofthefirstcourse.Twop3.iesofmcm'oran,";
wat,rproofirr.,hal3.bcappliedusingXx'LLQlJACIG:TglasfabricembeddedinGi".;1-3.00 compound.
Thoquantities ofcomponents andwhorateofapp3.ication shallbcinaccorclancc withthemanufacturcx's pI'intcdinstructions forah~xl::ostatic headof.20feet.s.Nherebaclcfill istoboplacedagainstthcwatcrproofcd
: surfaces, panolsshallbofurnished andinst;allcd topro~oct,themembrane.
Ti!cepa!!ciahallbo1/2"Chic!cFlintlcot,c asphaltcoatedinsul,tionpanelsaM;achedt,'othcll%lbrancIfitllspot,-ofasphalt;platieccmenh
~~giCreQt21.gDooooo~roof i~Rsqairemont oDKC2-28-6gPage2Concrete.urfaccshallb.drybcforcapplyingthedw~.pproofing TiMterivQQ andsha33.befreeofallf'nstiosandsire.larprosections.
Allholes,voidsandhoneycombed areasshallbfilled,patchedorrcpaircdtoproduceanloothsurface.Allsuri'aces shallbofreeofdirt,dust,iceetc.ApplytlTospraycoatsofRBJ4'arineiAouidDCcDtoatotalth>>el<ness ofl/oinchoverthcelltil'eMs33areao Qi:JiJ0}}

Latest revision as of 12:09, 18 March 2020

Forwards Response to 790801 Ltr Requesting Info on SEP Structural Topics III-2,III-3.A & III-7.B.Relevant Articles from Ny State Bldg Const Code & Subcontracter 1966-67 Tech Specs Encl
ML17261A149
Person / Time
Site: Ginna Constellation icon.png
Issue date: 11/14/1979
From: White L
ROCHESTER GAS & ELECTRIC CORP.
To: Ziemann D
Office of Nuclear Reactor Regulation
References
TASK-03-02, TASK-03-03.A, TASK-03-07.B, TASK-3-2, TASK-3-3.A, TASK-3-7.B, TASK-RR NUDOCS 7911200454
Download: ML17261A149 (107)


Text

~,, .- REGULATORY ORMATION DISTRIBUTION SYS i (RIOS)

ACCESS'ION NBR:7011200454 DOC s DATE: 79/11/14 NOTARIZED: NO DOCKET FACIL:50-244 Robert Emmet Ginna Nuclear Plantp Unit AOTH, NAME AU'l HOR AFFILIATION lr Rochester G 05000244 WHITED L, 0 ~ Rochester Gas 8 Electric Corp, RECIP ~ NAME RECIPIENT AFFILIATION ZiKA'A'NN,D, L, Oper at ing Reactors Branch 2

SUBJECT:

For wards r esponse to 790801 l tr r equesting info on SEP Structural 'lopics III-2E III 3,A 8 III>>7.B.Relevant articles Specs encl.

DISTRIBUTION CODE: ASSES TITLE: SEP

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from NY State Bldg Const Code L subcontracted 1966"67 Tech COPIES RECEIVED:LTR $

Topics ENCI. J SIZE:

NOTES:~ Q C PPFmaP~ W gl94tPMLME RECIPIENT COPIES RECIPIENT COPIES IO CODE/NAME LTTR ENCL IO CODE/NAME LTTR ENCL ACTION: 19 BC ~g8 ~ ~

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ROCHESTER GAS AND ELECTRIC CORPORATION o 89 EAST AVENUE, ROCHESTER, N.Y. 14649 LEON D. WHITE. JR. TELEPHONE VICE PRESII7ENT AREA CODE TIE 546.2700 I

November 14, 1979 Director of Nuclear Reactor Regulation Attention: Mr. Dennis L. Ziemann, Chief Operating Reactors Branch No. 2 U.S. Nuclear Regulatory Commission Washington, DC 20555 Subject,: Systematic Evaluation Program Topics III-2, III-3.A, III-7.B R. E. Ginna Nuclear Power Plant Docket, No. 50-244

Dear Mr. Ziemann:

Enclosed please find our response to your letter of August 1, 1979 in which you requested information on SEP structural topics III-2, III-3.A and III-7.B.

contact us.

If there are any questions regarding this information, please Very truly yours, L. D. White, Jr.

Enclosures

>>>iE0o9< '

N Kl'll5 IO KMIIR l)MIKE'ILY Go 299 structure,'nclosure i) 'll->

III-2 Wind and Tornado Loads

~

l Question: For each safety related Riiue%59

1. Describe the procedures to transform wind data into design pressure and gust factors.
2. Provide design basis, if any, for tornado loading including:
a. translational wind speed
b. radius of maximum rotational wind speed
c. procedures to transform tornado data into design pressure.

Response: The original design of Ginna Station did not include tornado effects. Wind loads were applied as specified by Section C304-4 of the New York State Building Con-struction Code. This code is based on a'wind speed of 75 miles per hour at a 30 ft..height. The wind speed is converted to a pressure loading and applied as shown in the Code tables'hich are included as Attachment, I.

An evaluation of the plant's capability to withstand tornado effects was performed in 1968. This evaluation, which is included in the FSAR as Appendix 14A, was based on a tangential wind velocity of 300 mph and an external vacuum of 3 psig. The portion of Appendix 14A 'that discusses the tornado effects on structures is provided as Attachment II.

Kle~~ m Immm Mm Hl5

In 1976 an addition was made to the auxiliary building for a standby auxiliary feedwater system. The design criteria for the standby auxiliary feedwater pump build-ing were submitted to the NRC by letter dated May 20, 1977. Further information was supplied with our letter dated July 28, 1978. Staff approval of the standby auxiliary feedwater system, including the building, was issued by h

letter dated August 24, 1979. This building addition was designed in accordance with the provisions of Reg. Guide 1.76. As indicated in Attachment III, the building was designed for a wind velocity of 360 mph, a 3 psig external pressure drop, plus missile loading.

The design wind velocity was converted to a pressure equivalent by the equations of paragraph 6.3.4 of ANSI A58.1.

III-3.A Effects of Hi h Water Level on Structures Question: For each safety-related structure,

1. Describe the water loads cons'idered in the design and the extent to which dynamic effects due to flooding were considered.
2. Clarify the water level for each load combination discussed in Topic III-7.B.
3. Explain how the ground water pressure, on the em-bedded part of the containment, was considered.

Response: The highest instantaneous still water lake level recorded for Lake Ontario was 250.2 feet USGS (FSAR Section 2.6.4).

The maximum still water level of Lake Ontario at the Ginna site was established as 250.78 feet USGS in Appendix 2C of the FSAR. The probable maximum stillwater level was revised on May 10, 1973 to 253.28 feet USGS or LSD 1935 datum. The reasons for this revision and subsequent addition of cap stones to the breakwall were explained in our letter dated Nay 15, 1973 to Mr. Donald J.

Skovholt, Assistant. Director for Operating Reactors, USAEC. Also, our letter of May 31, 1973 to Mr: Skovholt describes additional flood protection measures.

The plant is protected from wind driven waves by a break-water with a top elevation of 261.0 feet (initially constructed to 254.0 feet) and by the discharge canal which runs parallel to the lakeshore between the break-water and the plant. Design details of the breakwall are presented in question 3 in Supplement I to the Technical 3

Supplement Accompanying Application for a Full-Term Operating license, dated December 20, 1973. The general plant grade is about elevation 270 feet, with the excep-tion of the area between the lake and the turbine building which is at elevation 253 feet. Because of the breakwater, the discharge canal orientation and the elevation of the general plant, flooding is not a problem and the plant structures are, therefore, not designed for the dynamic affects of flooding.

Normal water loads from ground water are considered in the design of the plant structures which are supported below the ground water table (elev. 250'-0"). Of the safety class structures, only the Containment, Auxiliary Building and Screen House are supported below the ground water table. The walls of the Auxiliary Building were designed for a lateral hydrostatic water pressure and the base mat was designed for a hydrostatic uplift pressure. The Screen House was designed for a full hydrostatic,and uplift pressure assuming complete de-watering of the facility.

The Containment design provides for no backfill against the containment wall. As such no lateral ground water pressure on the embedded part of the containment was con-sidered (FSAR page 5.1.2 "Absence of Backfill Around Containment" ). However, the base slab of the containment is designed to withstand the full hydrostatic head of water, eguivalent to 7.16 psi (16.5 ft. of water).

III-7.B Desi n Codes, Desi n Criteria and Load Combinations Question: For each safety-related structure (except the contain-ment, shell),

List the codes and standards (including edition date) used for design and construction of concrete and steel elements (containment internal structures, auxiliary building, intermediate building, turbine building, control room, battery room, diesel generator room).,

2. Provide the loads, load combination and acceptance criteria employed for the design.
3. Provide the design and/or actual material properties (fy and fc) used for steel and concrete elements.

For concrete, provide the age specified and any 'ad-mixtures used.

Provide a copy of design specifications used for design and construction.

Provide representative stress level (compression, tension and shear) at the critical location of 1

each structure (e.g., at base of containment internal structures) for each of the load combinations pro-vided in response to (2) above. (For this question, information at the base of the containment, shell is also needed.)

Response: 1. The codes and standards (including edition date) used for design and construction of concrete and steel elements are given in FSAR Section 5.1.1.5 "Codes and Classifications", pages 5.1.1-10 through 5.1.1.-16.

This listing is included as attachment. IV.

2. The following loads have been considered in the structural design of the safety 'related structures.

A. Dead loads B. Live loads (uniform loads/sg. ft. to allow for any hung loads from floor framing system, which may include piping, H&V ducts, electrical cable trays, ceiling, etc. where applicable, and'also snow loads for roof)

C. Permanent. equipment loads D. Seismic loads E. Wind loads The specific loads, loading combinations, and acceptance criteria for each safety related structure are listed below:

(1) Containment Shell The design loads are described in Section 5.1.2.3 of the FSAR. The fundamental loads for the containment structure are tabulated in Table 5.1.2-4A.

The load combinations for the containment structure are given in Table 5.1.2-4I.

The acceptance criteria is described in the FSAR Section 5.1.2.3 under the headings of "Design Stress Criteria" and "Load Capacity."

(2) Containment Internal Structures a ~ Loads

1. Operating Floor Live Load 1000 psf with appro-priate dead load (D.L.)
2. Intermediate Floor Live Load 200 psf with appro-priate D.L.
3. Air Filter Platform Live Load 200 psf with appro-priate D.L.
4. Foundation Mat For upward water pressure =

1030 psf.

5. Load generated by the Operating Basis Earthquake (OBE).
6. Load generated by the Safe Shut-down Earthquake (SSE).
7. Compartment pressure differential due to accident.
8. Equivalent static load generated by the reaction on the broken reactor coolant system pipe during the postulated break.
9. Overhead Crane Lifted Load = 200 Trolley = 150 Bridge Girder = 100 k Vertical, lateral and longitudinal loads are used as per AISC or N.Y.

code, whichever governs.

Load Combinations D+ L+ T 0

= S

2. D + L + T0 + E = 1.33S
3. D+L+T0 +P+ Y +E =Uor Y T0 = Thermal effects and loads during normal operating condition.

Load generated by the Operating Basis Earthquake (0.08g) at 2%

damping (maxm. acceleration = 0.19g)

E Load g'enerated by the Safe Shut-down Earthquake (0.20g) at 2%

damping (maxm. acceleration = 0.47g)

The required section strength based on Ultimate Strength design described in ACI-1963.

For Structural Steel, Y is the section strength based on yield strength of material using elastic design.

Pressure equivalent static load within the compartment generated by postulated break.

D Dead load including any permanent equipment loads and hydrostatic loads Live loads.

Y r = Equivalent static load due to postulated high energy pipe break.

For concrete structure, S is the required section strength based on working stress design method as per ACI 1963. For structural steel, S is the required section strength based on the elastic design methods as per AISC.

"Specifications for the Design, Fabrication and Erection of Structural Steel for Buildings",

adopted April 17, 1963.

(3) Diesel Generator Buildin a ~ Loads Roof decking 2.5 lbs/sq ft Roofing & insulation 10.0 lbs/sq ft Fire protection 7.5 lbs sq/ft, Piping 5.0 lbs sq/ft Miscellaneous 3.0 lbs sq/ft 28.0 lbs/sq ft Snow load 40.0 lbs/sq ft

b. Load Combinations D + L + E = S (for roof bracing and column foundation)

For wall panels D + L + E = 1.33S D + L + E = U where, Load generated by the operating basis earthquake (0.08g) at. 5%

damping (maximum acc. = 0.13g);

Load generated by the safe shut-down earthquake (0.2g) at 5%

damping (maximum acc. = 0.32g).

For concrete structure, S is the required section strength based on'orking stress design method as per ACI 1963. For structural steel, S is the required section 10

strength based on the elastic design methods as per AISC.

"Specifications for the Design, Fabrication and Erection of Structural Steel for Buildings",

adopted April 17, 1963.

U = The required section strength based on Ultimate Strength design described in ACI-1963.

(4) Control Buildin a ~ Loads Roof Concrete slab 250 lbs/sq ft Snow 40 lbs/sq ft Truss 15 lbs/sq ft Roof & Insulation 8 lbs/sq ft Ceiling & Misc. 15 lbs/sq ft

2. Floor at, Elev. 289'-6" D.L. + L.L. = 500 lbs/sq ft
3. Floor at Elev. 271'-0" D.L. + L.L. = 400 lbs/sq ft,
b. Load Combinations For Roof Truss D + L + E = S
2. Building columns are designed by applying lateral load in the mid span of the column eguivalent to (D + 1/2 L) z .20g in addition to vertical dead load and live load carried by the column. The re-sulting allowable stresses from the seismic load are increased by 33 1/3%.
3. Concrete walls are designed by-applying lateral load in the mid span of the wall panel eguivalent to (panel weight) z 0.20g. The design is based on working stress method without increase in allow-able stresses.

E = Load generated by the Safe Shut-down Earthquake (0.20g).

(5) Auxiliar Buildin a ~ Loads

1. Roof Roofing 6 lbs/sq. ft.

Insulation and decking 7 lbs/sq. ft.

Misc. 7 lbs/sg. ft.

Snow loads 40 lbs/sq. ft.

12

Foundation a) Foundation mat for upward water pressure = 1000 psf b) Sump bottom for upward'water pressure = 2250 psf c) Walls below grade (1) Above el. 250'-0" for equivalent fluid pressure

'I 50 4/sq ft/ft of height (2) Below el. 250'-0" for equivalent fluid pressure 80 5/sq ft/ft l of height (3) Intermediate Floor Liveload 220 psf with appropriate D.L.

(4) Operating Floor Live load 200 psf with appropriate D.L.

(5) Crane Loads Lifted load 80 Trolley weight 14 Crane bridge 28.8 Lateral, longitudinal and vertical loads increased by 25% to include effect of impact and braking.

13

b. Load Combinations D+ L = S D + L + W or E = 1.33S (6) Screen House Below Grade The entire screenhouse-service water building is founded in or on bedrock with the exception of the basement of the electric switchgear por-tion which is founded approximately four feet above bedrock. Since the building is founded in bedrock the basement will not. realize any spectral acceleration and the seismic loading is equivalent, to the ground motion of 0.08g and 0.20g.

The basement is designed to be dewatered. The full height, of the wall is designed for an external hydrostatic pressure plus a seismic load equal to a percentage of the dead load of the wall and the hydrostatic pressure. For the portion of the wall below grade and above bed-rock an active earth pressure based on a saturated soil weight is applied.

Internal walls, such as pump baffles and the wing walls between the traveling screens were designed for a full height hydrostatic pressure on either side plus a seismic load due to the water movement during a seismic event.

Above Grade

1) Design loadings:

a) Dead Loads

1) Built-up roof 14 psf
2) Piping hung from roof 10 psf
3) Siding ,5 psf b) Live loads
1) Snow load to roof 40 pfs (New York State Bldg.

i Code Para. C-304-5)

2) Wind load a) Walls (SBC Para.304-4) 20 pfs b) Roof (SBC Para. 304-5)

Down 5 pfs Up 17 pfs

3) Crane loads (inc-live, 20,0005 dead Sc impact) I support points a) Lateral to runway 20% 4,000I b) Longitudinal to runway 10% 2,0008 c) Seismic loadings
1) 0.08g ground motion 5 1.33 working stress 15
2) 0.20g.ground motion I yield stress
2) Design loading combinations for analysis:

a) Dead loads + snow load + crane load I working stress b) Dead load + snow load + crane load + wind load I 1.33 times working stress c) Dead load + snow load + crane load + 0.08g vert. seismic +

0.08g E-W horiz. seismic 9 1.33 working stress d) Dead load + snow load + crane load

+ 0.08g vert. seisic + 0.08g N-S horiz. seismic I 1.33 working stress e) Dead load + snow load + crane load

+ 0.20g vert. seismic + 0.20g E-W horiz. seismic 9 yield stress f) Dead load + snow load + crane load

+ 0.20g vert. seismic + 0.20g N-S I

horizontal seismic yield stress The concrete, reinforcing steel and structural steel requirements are as listed below.

16

0 The minimum ultimate compressive strength used for designing concrete structures is as follows:

1. Containment Shell 5000 psi in 28 days
2. All Other Structures - 3000 psi in 28 days All structural concrete is considered subject to potentially destructive exposure and con-tains air in amounts conforming with Table 304 (b) of ACI 301. An air entraining ad-mixture was used conforming to "Specifications for Air Entraining Admixture for Concrete",

ASTN C 260-63T. A water reducing densifier was added to all structural concrete with a required ultimate compressive strength equal to or greater than 3000 psi at 28 days. (FSAR page 5.1.2-70a)

Reinforcement:

The concrete reinforcement. used is deformed bar of intermediate grade billet-steel con-forming to the requirements of "Specifica-tion for Billet-Steel Bars for Concrete Re-inforcement", ASTN A 15-64, with deformations conforming to "Deformed Bars for Concrete Reinforcement", ASTN A 305-56T. Special large size concrete reinforcing bars are deformed bars of intermediate grade billet-steel con-forming to "Specifications for Special Large 17

M 0

Size Deformed Billet-Steel Bars for Concrete Reinforcement", ASTM A 408-64. Reinforcing steel conforming to these specifications has a tensile strength of 70,000 psi to 90,000 psi and a minimum yield point of 40,000 psi.

The principal mild steel reinforcement used in the vicinity of the large opening (i.e.,

personnel lock and eguipment access hatch) has a 60,000 psi yield stress.

c. Structural Steel:

All structural steel used in the work and not, otherwise designated on the drawing conformed to "Specification for Structural Steel (Tentative)", ASTN A 36-63T, with 36,000 psi minimum yield strength.

The following specifications for structural steel and concrete were used for,construction and are included as Attachment V.

a. Technical Specifications for Furnishing, Fabricating and Erecting Structural Steel, Grating, Stair Treads, and Hand Rail.
b. Technical Specifications for Structural Concrete (includes reinforcement,) with Addendum No. 1 to Addendum No. 9.

The representative stress levels in the containment shell. can, be found in Appendix 5D of the FSAR.

The stresses for the 48 load combinations identified in Table 5.1.2-4I are provided as stress resultants and stress couples in the meridional and the hoop direction, including meridional shear and radial displacement s .

Unit stresses in the different structural com-ponents of the shell are described in the FSAR as shown below:

(1) Stresses in the hinge tension bars are shown on page 5.1.2-37.

(2) Stresses in the liner knuckle plate are described on page=5.1.2-37A.

(3) Stresses in the elastomer bearing pads are described on page 5.1.2-37B through 5.1.2-41.

(4) Radial shear in the shell, see page 5.1.2-42 through 5.1.2-43.

(5) Longitudinal shears in the shell, see page 5.1.2-44.

(6) Horizontal shears in the shell, see page 5.1.2-45 through 5.1.2-46.

(7) Tendon anchorage stresses, see page 5.1.2-46a through 5.1.2-46d.

(8) Liner stresses, see page 5.1.2-46e through 5.1.2-5la.

19

(9) Longitudinal liner shear stresses, see page 5.1.2-51b through 5.1.2-51g.

(10) Stresses in the concrete and reinforcing steel during the pressure test, see Table B on page 5.1.2-51h.

(11) Large openings, see page 5.1.2-62, and the Third Supplement of the FSAR "Design of Large Opening Reinforcement for Containment, Vessel."

20

'I r'

N gQ X~'<< Q<<~+ C. D c.

Structural Requirements C 304-4 Wind Loads (833 4)

Minimum wind loads shall be in conformity with tables C 304-4a and C 304-4b, and shall be applied normal to the surface. These loads are based on a design wind velocity of 75 miles per hour at a height of 30 feet above grade level. Minimum wind loads on signs shall be in conformity with generally ac-cepted standards.

TABLE C 304.4a. (Ill.633) WIND LOADS: WALLS, EAVES< CORNICES< TOWERS< MASTS AND CHlhlNEYS In pounds por srtuaro foot Eaves Towers, At height above grade Wallst 1 and masts and in feet . cornicess chimneyss 501 to 600~ 34 68 60 401 to 500 33 66 58 301 to 400 32 64 56 201 lo 300 30 60 53 101 to 200 28 56 49 61 to 100 24 48 42 41 to 60 21 42 37 26 to 40 18 36 32 0 to 25 15 30 26 1 exterior walls shall bo capabto of withstanding wind load on both the fntcdor and exterior surfaces, acting non.simultaneously.

-"Load acting upward.

3 For heights above grade greater than 600 feet, add 1 psf to load for wane for each interval or part of interval of 200 feet above 600 feet; for eaves snd, cornices. and towers, masts and chimneys, corresponding loads aro in proper lion to those (or walls.

4 Tabular values sre for square snd rectangular structures. For structures hexa.

gonal or octagonal in plan, use prolected aros snd multiply tabufar values by 0.6: for structures round or elnpiicsl in plan. use proiected ares and multiply values by 0.6.

C304-5 Overturning Force and Moment Due to Wind (833.5) a The overturning force shall be the wind load.

The wind load shall be the load set forth in table C 304-4a, and shall be applied only to the windward vertical surface above the horizontal plane under consideration, and to the rise of the roof. The re-sisting force shat( be the dead load of the structure above the horizontal ptane under consideration, plus the strength of material and fastenings estabtishing b

continuity with the structure below.

The moments of stability and overturning shall be computed about the leeward edge of the horizon-tal plane under consideration.

93

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'Aq

Structural Requirements TABLE C 304.4b. (IV.633) VtfMD LOADS: ROOFS ln pounds por square foot Mean elevation of roof above grade level in feet Direction of load>

20'lope 0'o 30'ver from horizontafg 3060'0'o to" 60'01 to 6003 Downward 8 8 8 to 24 24 Upward 29 29 to 24 24 24 401 to 500 Downward 8 8 8 to 23 23 Upward 28 28 to 23 23 23 301 to 400 Downward 7 7 7 to 22 22 Upward 27 27 to 22 22 22 201 to 300 Downward 7 7 7 to 21 21 Upward 25 25 to 21 21 21 101 to 200 Downward 6 6 Gto20 20 Upward 24 24 to 20 20 20 61 to 100 Downward 5 5 5to17 17 Upward 20 20 to 17 17 17 36 to 60 Downward 5 5 5 to 15 15 Upward 19 19 to 15 15 15 21 to 35 Downward 5 5 5 to 14 14 Upward 17 17 to 14 14 14 0 to 20 Downward 5 5 5to11 11 Upward 14 14 to 11 11 11 1 Downward snd upward loads act non slmultsneousfy.

"For sfopes between 20 and 30'llh wind acting upward, snd between 60'ith wind downward, compule loads by straight line Interpo-30'nd lation.

3 For heighls above grade gresler thsri 600 feel, sdd 1 psf to upward load lor 0'o 20'lope for each Interval or pari of Interval of 200 feet above feel; lor upward loads on other slopes, snd downward loads on sll '00 slopes, corresponding loads are in proportion lo those for upward load for 0 to 20'lope.

c The moment of stability of the structure above the horizontal plane under consideration shall be not less than 1'/2 times the overturning moment due to wind.

C 304-6 Sliding Force Due to Vlind (833.6)

The sliding force due to wind load, equal to the overturning force, determined in conformity with section C.304-5, shall be resisted by the dead load of the structure above the horizontal plane under consideration, by anchors, and where applicable, by soil friction, providing a total resisting force equal to not less than 1t/2 times the sliding force. Anchors used to resist overturning may also provide resist-ance to sliding.

94

3. TORNADO EFFECTS ON STRUCTURES 3.1 GENERIC All structures have been designed for wind loads in accordance with the requirements of the State of New York State Building Construction Code. The wind loads tabulated in this code are based on a design wind velocity of 75 miles per hour at a height of 30 feet above grade level. The stresses resulting from these loads were considered on the basis of a working strength design approach.

'For purposes of this study the design of all critical structures has been checked on the basis of a limiting load factor approach wherein the loads utilized to determine the required limiting capacity of any structural element are computed as follows:

C = (1.00 + 0.05)D + 1.0 W + 1.0 P Symbols used in this equation are identified as follows:

C required load capacity of section D dead load of structure wind loads based upon 300 mph tangential wind velocity W

t P pressure load based upon an internal pressure 3 psi higher t than the external pressure.

3.2 REACTOR CONTAINfENT Although tornado loads were not considered in the original design, this structure is capable of resisting the full strength tornado loads.

14A-4

3.3 AUXILIARY BUILDING Although tornado loads were not considered in the original design, this structure up to and including the Operating Floor (elev. 271"-0") is capable of resisting tornado loads. The siding on superstructure would blow outward, thus relieving the pressure and wind load. Components and systems on the operating floor and above are susceptible to impact by falling debris and potential missiles. The equipment, on the auxiliary building operating floor, required to maintain the plant in a hot shutdown condition is as follows:

a) Boric Acid Tanks, Pumps and Filter; and b) 480V Switchgear Bus 14 The equipment in a) is surrounded by a radiological shield wall as shown in Figure 14A-1. This wall offers significant lateral protection against pot;ential missiles. Furthermore, the two tanks and pump are redundant. Hence, there is reasonable assurance that there will be no loss of boration function. More details are given in Section 4.2.1 Boration System.

Damage to Bus 14 will not cause loss of power supply since an independent and redundant bus (Bus 16) is provided on the intermediate floor of the auxiliary building. This floor, as previously mentioned, will not be exposed to the weather. More details are given in Section 4.4.

In addition, the Spent Fuel Pit has been evaluated. Potential missiles may puncture the spent fuel pit liner but will not penetrate through the concrete walls or base causing gross leakage of water.

3.4 INTERMEDIATE BUILDING This structure, as shown in Figure 14A-2, is significantly confined by other buildings, i.e., Service Building, Turbine Building, Reactor Containment and Auxiliary Building. Consequently, a direct exposure 14A-5

to a tornado funnel is extremely remote. Due to the relative vacuum which might be created by a tornado outside of the intermediate building lateral walls may blow outward. This will relieve the pressure differential and prevent gross failure of the structural steel framing, columns and floors. Therefore, the two floors which house critical equipment, i.e., floors at elevations 253'" and 278'",

are afforded significant shielding by the adjoining structures and higher floor/roof elevations.

Th'e critical components in this structure consist of the following:

a) On floor elevation 253'": two motor driven and one turbine driven auxiliary feedwater pumps; and On floor elevation 278'": r the cross connection on main steam and feedwater lines to the two steam generators.

As previously mentioned, no damage is anticipated to the equipment located on these two floors. More details are given in Section 4.1.

3.5 DIESEL GENERATOR ANNEX The availability of on-site diesel power was reviewed on the basis of the assumption that the tornado could cause loss of outside power.

Siding, windows, doors and ventilation openings would blow outward thus relieving the pressure loading. Damage to the roof might result if the differential pressure is not relieved in time. Two redundant diesel generators are provided. No physical damage to the diesels is anticipated. Furthermore, the physical separation between them is such that one missile would not be able to impact against both diesel generators, as shown in Figure 14A-3. More details are given in Section 4.4. The con'elusion has been drawn that emergency power supply is reasonably assured.

14A-6

3.6 SCREENHOUS E Siding, windows, doors and ventilation openings would blow outward, thus relieving the pressure loading. No structure collapse is expected. The critical equipment housed in the screenhouse is represented by:

a) four service water pumps; and b) 480 V Switchgear-Buses 17 and 18.

The four service water pumps are redundant and sufficient physical separation exists between them to make extremely unlikely the failure of all four pumps from the same tornado effect, as shown in Figure 14A-4.

Service water pumps lA and lC are energized from Bus 18 and service water pumps lB and 1D are energized from Bus 17. Cross-tie between the two buses is available.

The two buses are located in the screenhouse and are physically separated. Hence, there is reasonable assurance that at least one service water pump-bus combination will operate properly.

.More details are given in Section 4.4.

3.7 CONTROL ROOM No gross failure of this structure is anticipated. The only wall directly exposed is the East wall.'he siding of this wall would blow outward relieving the pressure differential and leaving the interior exposed to the weather. The same would be true for windows, doors and ventilation openings.

Local controls for the equipment required for maintaining the plant in a hot shutdown condition have been provided as a backup to the controls available in the control room. Therefore, there is reasonable assurance that controls for the critical components will be available.

14A-7

3. 8. SERVICE BUiLDING The status of this building is similar to that of the auxiliary building, i.e., the siding on superstructure above elevation 271'ould blow outward, thus relieving the pressure and wind loads. The components which might be affected by tornado are the two condensate storage tanks. There is reasonable assurance that feedwater supply will be maintained because of the available redundancy and of the fact that 2/3 of the tank volume is below grade.

3.9 CABLE TUNNELS The cable tunnels are located underground and are capable of withstanding tornado loads.

14A-8

4.6 Tornado Loads

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Tornado Design Criteria The Pumphouse will contain safety class equipment (Seismic Class 1)

,,and will therefore be designed to withstand short term tornado loadings, including the impact of. tornado-generated missiles. Tne following tornadc design criteria shall be used:

r

a. %Iaximum rotational wind velocity of 290 mph, together with translational wind velocity of 70 'mph giving total design velocity of 360 mph.

Radius of maximum rotational velocity is cdnsidered to be 150 ft; Pressures and suction forces due to the 360 mph wind and all other design parameters shall be determined in accordance with ANSI-A58.1 1972.

'b. External pressure drop is considered to be 3 psig.

c~ A missile equivalent to a utility pole 35 ft. long, 14 inches in diameter, weighing,50 pcf and traveling at 130 ft./sec. within a height of 17 ft. above ground.

d. A missile equivalent to a two ton automobile traveling at 150 ft./

sec. and impacting within a height of 22 ft. above ground.

e. A 12, ft. long 4" x 12" wooden plank traveling at 260 ft./sec. and impacting end-on at any height.

f.. A missile equivalent to a 3 inch diameter Schedule 40 pipe, 10 ft.

long, traveling at 160 ft./sec. and impacting end-on within a height of 48 ft. above ground.

g. A missile equivalent to a 6 inch diameter Schedule 40 pipe, 15 ft.

long, traveling at 150 ft./sec. and imoacting end-on within a height of'0 ft. above ground.

A missile equivalent to a 12 inch diameter Schedule 40 pipe, 15 ft.

long, traveling at 130 ft./sec. and impacting end-on within a height of 14 ft. above ground.

4.6.2 Tornado Load Combinations Each of the above missile loading cases shall be investigated to determine which one causes the most severe loading of the Pumphouse, or of individual Pumphouse components. The most severe missile load shall be combined with the tornado wind load for the structural design, of the Pumphouse.

clLOVHT ASSOCIATES, liC.

The design, materials, fabrication; inspection, and proof testing of the containment vessel complies with the applicable parts of the following:

ASME Boiler and Pressure Vessel Code, Section III Nuclear Vessels,Section VIII Unfired Pressure Vessels,Section IX Welding Qualifications.

2. Building Code Requirements for Reinforced Concrete (ACI 318-
63) .
3. American Institute of Steel Construction Specifications:

a) "Specifications for the Design, Fabrication and Erection of Structural Steel for Buildings," adopted April 17, 1963.

b) "Code of Standard Practice for Steel Buildings and Bridges,"

revised February 20, 1963.

4. USAS N 6.2 1965, "Safety Standard for Design, Fabrication and Maintenance of Steel Containment Structures for Stationary Nuclear Power Reactors."
5. 'CI 301-66, "Specifications for Structural Concrete for Buildings"
6. ASTM C 150-64, "Specifications for Portland Cement"
7. State of New York Department of Public Works Specification 5.1.1-10
8. ASTM C 260-63T, "Specifications for Air-Entrained Admixtures .for Concrete"
9. ASTM A 15-64T, "Specifications for Billet-Steel Bars for Concrete Reinforcement"
10. ASTM A 305-56T, "Specificat ons for Minimum Requirements for Deformation of Deformed Bars for Concrete Reinforcement" ll. ASTM A408-64T, "Specifications for Special Large Size Deformed Billet-Steel Bars for Concrete Reinforcement"
12. ASTM C 94-65, "Recommended t

Practice for Winter Concreting"

13. ACI 306-66, "Recommended Practice for Winter Concreting"
14. ACI 605-59, "Recommended Practive for 1iot Weather Goner'eting"
15. ASTM A 421-65, "Specifications for Uncoated Stress-Relieved Wire for Prestressed Concrete"
16. ASTM C29-60, "Method of Test for Unit Weight of Aggregate"
17. ASTM C 40-66, "Method of Test for Organic Impurities in Sands for Concrete"
18. ASTM C 127-59, "Method of Test for Specific Gravity and Absorption of Coarse Aggregate"
19. ASTM C 128-59, "Method of Test for Specific Gravity and Absorption of Fine Aggregate"

l I

20. ASTM C 136-63, "Method of Test for Sieve or Screen Analysis of Fine and Coarse Aggregate"
21. ASTM C 39-64, "Method of Test for Compressive Strength of Molded Concrete Cylinders"
22. ASTN C 192-66, "Method of Making and Curing Concrete Compression and Flexure Test Specimens in the Laboratory"
23. ASTM A 15-62T, "Specifications for Billet-Steel Bars for Concrete Reinforcement"
24. ASTM A408-64, "Specifications, for Special Large Sized Deformed Billet-Steel Bars for Concrete Reinforcement"
25. ASTM A 432-64, "Specification for Deformed Billet-Steel Bars for Concrete Reinforcement with 60,000 psi Minimum Yield Strength"
26. ASTM C 31-65, "Method of Making and Curing Concrete Compression and Flexure Test Specimens in the Field",
27. ASTM C33-64, "Specifications for Concrete Aggregates"
28. ASTM C42-64, "Methods of Securing, Preparing, and Testing Specimens from Hardened Concrete for Compressive and Flexural Strengths"
29. ASTM C 131-64T, "Method of Test for Abrasion of Coarse Aggregate by Use of the Los Angeles Machine" 5.1.1-12
30. ASTM C 138-63, "Method of Test for Weight per Cubic Foot, Yield, and Air Content (Gravimetric) of Concrete"
31. ASTM C 143-58, "Method of Test for Slump of Portland Cement Concrete"
32. ASTM C 150-65, "Specifications for Portland Cement"
33. ASTM C 172-54, "Method of Sampling Fresh Concrete"
34. ASTM C 231-62, "Method of Test for Air Content of Freshly Mixed Concrete by the Pressure Method"
35. ASTM C 260-65T, "Specifications for Air-Entrained Admixtures"
36. ASTM C 494-62T, "Specifications for Chemical Admixtures for Concrete"
37. ASTM C 173-58, "Method of Test for Air Content of Freshly Mixed Concrete by the Volumetric Method"
38. ACX 214-57, "Recommended Practice for Evaluation of Compression Test Results of Field Concrete"

~ 39. ACT 315-65, "Manual of Standard Practice for Detailing Reinforced Concrete Structures"

40. ACE 347-63, "Recommended Practice for Concrete Formwork"
41. ASTM D 287-64, "Method of Test for APX Gravity of Crude Petroleum and Petroleum Products (Hydrometer Method) 5.1.1-13
42. ASTH D 97-66, "Hethod of Test for Pour Points"
43. ASTH D 92-66, "Hethod of Test for Flash Point by Cleveland Open Cup"
44. ASTH D 88-56, "Method of Test for Saybolt Viscosity"
45. ASTH D 937-58, "Method of Test for Cone Penetration of Petroleum"
46. ASTH D 512-62T, "Methods of Test for Chloride Ion in Industrial Water and Industrial Waste Water"
47. ASTH D 1255-65T, "Method of Test for Sulfides in Industrial Water and Industrial Waste Water"
48. ASTM D 992-52, "Method of Test for Nitrate Ion in Industrial Water"
49. ASTM A 442-60T, "Tenta'tive Specifications for Carbon Steel Plates with Improved Transition Properties"
50. ASTM A 300-63T, "Specifications for Steel Plates for Pressure Vessels for Service at Low Temperature"

'1.

ASTM A 36-63T, "Specifications for Structural Steel"

52. SSPC-SP6-63, "Commercial Blast Cleaning"
53. SSPC-SP8-63, "Pickling"
54. SSPC-PA1-64, "Shop, Field and Maintenance Painting 5.1.1-14
55. ASTM A 322-64A, "Specification for Hot-Rolled Alloy Steel Bars"
56. ASTM A 29-64, "Specification for General Requirements for Hot-Rolled and Cold-Finished Carbon and Alloy Steel Bars"
57. ASTM D 624-54, "Methods of Test for Tear Resistance of Vulcanized Rubber"
58. ASTM D 676-59T, "Method of Test for Indentation of Rubber by Means of a Durometer"
59. ASTM B 412-66T, "Method of Tension Testing of Vulcanized Rubber"
60. ASTM D 573-53, "Method of Test for Accelerated Aging of Vulcanized Rubber by the Oven Method"
61. ASTM D 395-61, "Method of Test for Compression Set I

of Vulcanized Rubber"

62. ASTM D 746-64T, "Method of Test for Brittleness Temperature of Plastics and Elastomers by Impact"
63. ASTM D 1149-64, "Method of Test for Accelerated Ozone Cracking of Vulcanized Rubber"
64. ASTM D 471-66, "Method of Test for Change in Properties of Elastomeric Vulcanizates Resulting from Immersion in Liquids" 65 'STM A 514-65, "Specification for High-Yield Strength, Quenched and Tempered Alloy Steel Plate, Suitable for Welding"
66. ASTM A 441-66T, "Specification for High-Strength Low Alloy Structural Manganese Vanadium Steel" 5.1.1-15

0

67. ASTH A 53-65, "Specification for Welded and Seamless Steel Pipe"
68. ASTH A 435-65, "Hethod and Specification for Ultrasonic Testing and Inspection of Steel Plates of Firebox and Higher Quality"
69. ASTH C 177-63, "Method of Test for Thermal Conductivity of Materials by Means of the Guarded Hot Plate"
70. ASTH C 165-54, "Method of Test for Compressive Strength of Preformed Block-Type Thermal Insulation"
71. ASTM C 355-64, "Methods of Test for Water Vapor Transmission of Thick Materials" 72.. ASTH C 273-61, "Method of Shear Test in Flatwise Plane of Flat Sandwich Constructions or Sandwich Cores" e 73. ASTM D 1622-63, "Hethod Cellular Plastics" of Test of Apparent Density of Rigid The structural design also meets the requirements established by the "State Building Construction Code," State of New York, 1961.
5. 1. 1-16

i p~i4c Q &<47 r O'KC S/19/66 Hev> X 9/9/66 Ti.CHblICAL SPIC EPIC'ETIO.'t PC:R FUN'IIS~)I>~G PM>UCATZKC AHD i"'iZiCTXhG Si.'hVC'"tH>i3 83."nKL GEE<'ZIi:G~ .11.EXP. 1Pa>!Xi Afto }V;lFQl'CLIL FGPi 'f'i!~

IBBERV Y.""w~'TT QIMl~JA )NCf.C(J? PCX'P"8, STATXGH - UltlT I'JCo 1 GF "'FZ RODENT~, GAS Af!D R~~ECTRJG CORPORP.TIQH RPv'cSS~x'~ iaafU YOiK 1o0 SCOPZ OP '.~'OZC 1 '3. GE'i!"VLL The wn"~ to be f.eri'0m'nder this Subcontract shQ1 inclL:do Cho detailJ"'lpj fLlz'niah~ijg~ fabrication~ dolxvGPJt~ unl c lk~rLn~ Gt orag8 where necoo 'ary> al'n or~ation of aM~: tructLLral staol> gr'.ting>

Otair "eada and hwdraU. xeq~~'d for the Robert 8~i..tt Gin~a I~ucloar Po:mx S~tion - Unit Hoo 3. Yce ~~xh shan. inc3ude but not necessary bo lilJ.ted to the ZO3 Lo:ri~~:

Ge Pro@M;ation of shop d8t'>ils Q'."ad Qr8ction drPrP~goo b, Structural .tool for tho Structures including tha Ccntailuent Vee"el~ Xntezvp;.die<;e Buildinp~ Rector Au:~r3iary Building, 'lie'o3ne f1<m~ Service Bui3ding al'!d FaccdQo Tho structural 8tt381 consists of 5 (1} Cola.n.~

(2) Ba88q ~ip An'3 LGRrxng plat98 (3) ShJ.D'8:,or scttinc, 613. bao8 w:d baal"Mir p"wte5 (4) 23aesia md piL dere (5) TL'uGSe8 (6) Poets, hw~,gers, tioe and ='ag rods

('7) Struts and br~cinrr (8), ~Lrlino and 1 irt;e

()) St'ir "-t" 1 (M) T:olley b;='~

(Wi) L- daces

(>'>) Too lQ"-.tea (X3) Connections alld connoctiol1

{3A) K>>'vota, .~olde and !1iph otx "~~t;h bolto 1)) Crane Haila, clips md atop" l6) Chcckerccl plate

1 a i L I DKC 2>> 9/g/66 Rev. I

c. Steel gratings,- grating with attached. plate, grating stair

.treads, ancl all related'ardware.

d. Handrail for platforms, wall; ways and. stairs.

~

q. Shop paint.

1.2 LfOBK NOT INCLUDED The following items of wor". associated, with the plant structures =

are not included in this Subcontract but will be furnished and erected. by others:

a. Anchor bolts
b. Grouting for colure base plates
c. Field painting d.. Steel plate..liners for Containm nt Vesse3., Sp"nt Fuel Pit, Decontamination Pit and. Refueling Canal end. liner penetration.

2.0 SITE DATA 2.1 LOCATICH

'h site fox the Robert Enua tt Ginna Huclear Power Station Unit Mo. 1 is located on the south shore of Lake Ontario, near Smoky Point, in Wayne County, approximately l8 miles northeast of Rochester, New York.

TRANSPORTATIOlr The site will be graded and. an access road provided to the worl; area. No rail facilities are available at the site. The nearest rail head. is appro imately four miles from the site.

2.3 ACCESS TO MORK A1KA Thc Contractor will be provided all r quired. and. reasonable access to the worl'x+a so ns not to impcdc his operations.

DXC

&3 9/9/66 Rev. I 2.>'ERVICES AIR FACILITIES The availability of services and. facilities for this Subcontractor will be detailed. by the Contractor, Bechtel Corporation. Generally services and. facilities are as follows:

Available Services

1. Power will be available at existing locations at 480 V. in a capacity up to 60 amp . Power reauirements in excess of this amount will require special consideration and. a decision for each contract.
2. Hater still be available at existinp locations.
g. No compressed air will be availablc.

4.- Fo telephone sex'vice will 'be available except at the coin phone in the Pechtel office-

5. Clean up will be the xesponsioility of the sub-contractor and if it ls not properly accomplished. the work will be performed

'nd. a back charge written to cover the cost.

6. The use of job site cranes will be offered. when they are not in use on the base, contract work. This service will be back charged with a percent aided for overhead,.

ifork and Laydorrn Space Adequate work and. laydovn s.oace >rill bc,provided in areas not acgaccnt to the main buildings. Limited work and laydown space tr9.11 be made availablc, dep nding on schedule and. coordination of crafts, in the buildings, and surrounding areas.

Office and Chanrre Areas

.Ho office space or craft change i'acilitics will be provided. Portable toilet fccilitieo srill bc availsblc.

XKC 9/9/66 Rev. I Job Coordination Bechtel will coordinate ih= site work and, direct the subcontractor to promote. harmony and, provid the overall best work sequence. The I

'Bechtel inspecting engineer may req,uest and. shall be permitted. to witness all subcontract work to assuze its continued. quality. The subcontractor's obligation is to provide workmansiaip within the requirem nts of the sp cifications and, to make designated tests to prove quality.

3.0 STRUCTURAL STEEL 3.1 SPZCIFXCATXOHS Am CODES All work under this'ubcontraci shall comply, except as herein- ,

after specified,, with the following Am rican Xnstitute of Steel Construction Specifications:

1. "Specifications f'r the D"-sign, I~'abrication and. Erection of Structural Steel for 33uildings", adopted April 17, 1963.
2. "Code of Standard. Practice for Steel Buildings and. Bridges",

revised, February 20, 1963.

3.2 NATERXALS All structural steel used. in the work and not othentise designated.

shall conform to Specification for Structura3. Steel (Tentative) ",

ASTN A 36-63T.

Rivet steel shall conform 'o "Specification for Structural Rivet Steel" ASTM A l>sl<<'$8.

High strength bolts shall conform to Specification i'or High Strength Bolts for Structu;..al Steel Joints, Xncluding Suitable Huts and Plain Hardened Slashers", ASTbl h 32$ -6'.

r 1 DKC

&5& 9/9/66 Rev. I Melding electrodes shall be suitable for the type of steel tu be welded,.

The Subcontractor shall furnish the EIIGZZER and. the Contractor

/

three copies of all mill test reports and. three copies of the reports of the steel f bricacor's inspectors for the structural steel furnished. by him und r this Subcon'cract.

3 r3 SHOP AbD FIELD CO>HIECTIOHS Shop assembly connections may be either welded. or riveted, Field connections shall be either welded. or made with high strength bolts except for the following items which shall be either welded or bolted. with structural grade bolts r4ith hezagona3. nuts:

1. All beams marked. "Removable" on the Drawings
2. Stairways, landings, ladders, etc.
3. All girts and roof purlins Mhen high strength bo3.ts are used in erection of steel for making permanent field connections the connection shall 'be in accordance with "Specifications

/

or Assembly of Structural Joints Using High Strength Bolts" issued by the Research Council on Riveted and, Bo3.ted Joints of the Engin ering Foundation and dated. khrch 3.962.

All welding shall comply with the requirements of the Specifications of the American Institute of Steel Construction and of the Pwerican Melding Society for the typo of steel to be welded..

3 4 ERHCTIOi3 The Subcontractor shall erect all structural steel furnished by him and required for thc plant 'building except

/

steel which must be left out temporarily for erection purposes. Tais steel shall be stored. by thc Subcontractor ao d.irected by the Contractor and

MC

. 9/9/66 Rev. I erected by Others. This steel vill be designated on the Dravings as being erected. by Others.

Oth r steel >>ill be designated on th Dravings to be left out l

temporarily during the,non'nl course of erection for erection purposes and. to be later erected. by the Subcontractor 'before he leaves thc job site.

The Subcontxactor shall coordinate his flOKC vith that of other contractors and afford. other contractors reasonable opportunity for the introduction of their materials and, the execution of their vora. Legible and. durable erection marlins should. be painted.

on all members.

3.$ TEMPORARY STEEK FOR EHECTIOÃ The Subcontractor shall attach to his Proposal a dravlng shoving any temporary steel for erection vhich the Subcontractor proposes to furnish and, erect. The draving shall shov the arrangement for the temporary steel for erection and. the loading thereon.

This dravring is subject to revie'ir by the EHGXlBEB, out such xeviev does not relieve the Subcontractor of his responsibility to comply vith tnc Specification and, D avings.

The Subcontractor shall, vhen his steel erection NOR!C is completed.,

xemove any temporary steel, including equipment supporting steel, placed. for erection pux'poses. Any holes in building steel, resulting fzum connection of erection stee3. thereto, shall be permanently pit~".cd by the Subcontractor, subject to the. approval of the Contractor.

4.O GRAnxo AHD STAXn TOADS 4.1 SPZCXrZCATXO!iS A!JD CODES All steel grating and gratii>g stair treads shall conform to the folio>>ing )total Gr: ting Institute Specifications:

I DEC

~

7 ~ 9/9/66 Hev. X

1. "Standard Specifications for bhtal Grating and Vital Grating Treads", adopted pctober 8p 1957..
2. "Code of Standard. Practice of th>> ihtal Grating Institute" All steel plate shall conform to thc follorring American Institute of Steel Construction Specifications:
1. "Specifications for the Design, Fabrication and. Erection of Structural Steel for Buildings", adopted. April 17, 1963.
2. "Code of Standard Practice for Sicel Buildings and. Bridges'7 revised. February 20, 1963.

AU. >relding shall comply with the rcouirements of the sp cifications of the American Institute of Steel Construction and of the American Melding Society for AS'36-63T steel.

4. 2 MATERIALS AND IEQUIBELPK'S All materials for grating, plates, grating treads, clip fasteners, and, tread. bolts and. nuts exclusive of hold. down studs and nuts, shall comply with the requirements of "Specifications for Structural Steel", ASTN A 36-63T, except as other>cise noted. on the Drawings.

Studs, to be used. for fastening, shall be 1/4 inch diameter, type'04 stainless steel of'roper length. Nuts to 'be used, for fas>>

tening shall be silicon bron.e nuts-All grating and. grating tr ads shall be of the welded type with Qopths as shoran on the drn~~lngo. All grating and, grating treads unless othemrise noted on t;he Drawings shall be fabricated. from 3/16 inch thiclc bearing bars on 1-3/16 inch centers ttith spiral cross bars welded on 4 inch centers.

All chccliercd steel plate and plain plate, as called for on the drm<ings, shall be shop welded to and, furnished. srith the grating panels.

DKC g/g/66 Rev-All toc plate shown attached. to the grating, shall be furn9.shed.

by th9,s Subcontractor and shall be 'nstallcd in the fabrication shop except where the erection sequence neccss9tatcs field.

installation.

All grating treads shall have 1" x g/16 inch bearing bars, checkered plate nosings, a width of 9-p/4 inches, and, lengths as shown on the drawings. Treads shal3. bc furnished. with 3/8" x 1" cadmium plated, mach9.ne bolts and nuts, four per tread., for fastening treads to stair stringers.

All cutouts required. for pipes, columns, conduits, etc. shown on the drawings shall be prov9ded. for 9n the grating. The dimensions

/

of openings shall be as shown on the Drawings. The 'cutouts and.

openings sm lier than 6 inches sha13. be banded. with bars of the same depth and. thickness as the bearing bars. The cutouts and.

openings 6 inches and. larger shall be banded with 1/LL inch toe plate projecting 6 9nches above the finished, floor.

The Subcontractor shall furnish ade(Luate support angles under the grat9ng at openings, where reauired.

4'$ FXEU3 CO%'1ECT30ÃS TO SUPPOBT STEEL All plain grating panels shall be fastened to the supporting steel with L;wo standard sadd3.e clip., at'ach end, of the panel, and.

with two additional clips to the intermediate beam when the panel

~

is continuous ovex two spans.

All grating with attached. steel plate shall be fastened to the supporting steel with two wclds at each end. of the panel, and.

two additional welds to thc intcxmcc;iatc bean when thc panel is continuous over two spms.

DXC 9>> 9/9/66 Rev. I 4.4 GALVAi~EIKIIlG All steel grating, attached, plate, stair treads and saddle clips shall be hot dipped galvanized in accordance with "Specifications for Hot Galvanized Coatings on Products Fabricated. From Rolled, Pressed. and. Forged Steel Shapes, Plates, Bars and Strip", ASTM A 123-63, All fabrication, including cutouts and, alterations, shall be completed before galvanizing, 5.0 EQ!DHAIL 5 el MATER II' All handrail sha11 be made of 1>>1/4" diameter> schedule 40 standard weight> black and galvanized steel pipe and fittings conforming to "Specification for Black and. Elot-Dipped Zinc Coated. (Galvanized)

Uelded and Seamless Steel Pipe for Ordinary Uses" > ASTM A 120-63T.

All handrail shall have one rail centerline 2'-0" above the finished. floor level and, a second rail center line 3'-6" above the finished floor except where noted othertrise on the Drawings.

The posts shall be spaced, not'more than 8'-0". on centers. All1 handrail shall be in accordance with the typical handrail detail

. shown on the Drawings, All points shall be welded and, ground to a smooth finish. Turns shall be maLe by the use of tube turns or pipe bends and all railing extending beyond. thc posts shall be terminated with drive>>

in plugs.

5.2 FIELD COÃlECTIOi~!S All handrail posts shall be bolted, to the structural steel supporting the floor grating, except where shown othe'>ise on the Drawings. All handrail posts set in concrete shell be set

~ ~

DZC 9/g/66 Rev. I in oleeves pxovided by others with the concrete slabs and. shall be secured. in place with molten 1cad or sulphur.

All bolts, nuts and. clip angles required for fastening the hand-rail posts to the structural steel shall 'be furnished. by this Subcontractor.

All handrail indicated on Drawings ao removable, or fastened. to removable steel framing, shall have Joints at appropriate places and. be bolted. for easy removal of sections so indicated. All handrail running into bracing and. columns will be field.'cut and.

welded to fit,

. All >>elding shall comply with the reouiremento of the American Institute of Steel Construction and, of the American Melding Society.

6.0 PAIi'KING All structural steel and. handrail to be furnished under this Sub-contract, shall be cleaned. of rust or mill scale in accordance with the Steel Structures Painting Council Surface Cleaning Specifications SSPC-SP 2-6g "Hand. Cleanjngi'nd/oi SSPC"SP 3-6g "Power Tool Cleaning",

as required.

Paint shall be omitted. at all areas of field welding and. on all steel surfaces>>hich will be in contact with concrete. All contact surfaces of connections shall be painted., including those for trusses and plate girders.

All structural steel and handrail, to be furnished under this Sub-contract, shall receive one shop coat of paint which ohall be one of the following:

lEC 9/9/66 Hev ~ I

1. Socony-Valdura 13-Y-5 Zinc Chromate Primer
2. Gliddcn HGL 32802 Zinc Chromate Primer
3. Pennsbury Yellow Zinc Chromate Primer Keeler Zo Long Ifo. 4800 Exterior Orange Lead. Primer The shop paint shall be mixed, and. applied in accordance with the Steel Structures Paintinc Council's Paint Sp cification SSPC-PA 1-64. "Shop, Pield and ihintenance Painting".

Shop paint shall have e dry film thickness of 2 mils.

Pield paint will be by Others.

7.0 SHOP Ai~TD EHECTXON DHJGlZi.OS Tne Sub-contractor shall submit to the Engine r, for his approval, one reproducible copy and one print of all shop and. erection drawings, data sheets, etc. reauired for his >lOHK. Two copies of all drawings, etc. shall also 'be submitted. concurrently t,o llestinghouse Atomic Power Division. This shall be done with such promptness as to cause no delay in either his HOK( or that of any oth r contractor. These drawings shall be checked and. certified, prior to submission, and shall contain all required. information. The Subcontractor shall make any corrections required. by the Engineer and. file with thc Engineer and. the Mesting-house Atomic Power Division two copies each of the'corrected. drawings.

Approved, drawings will be so stamped and. dated. and. shall form a part of the Subcontract. One set of the approved drawings will be returned.

to the Subcontxactor. Approval of such drawings shall not relieve the Subcontractor of the responsibility for deviation from the Contract Docum nts, nor from responsibilities for errors in shop-or erection drawings,

DXC 9/9/66 Reve X 8.0 RECORD DBAIGI<GS Upon completion of his work the Subcontractor shall submit to the Engineer a complete set of cQ3. drawings for the work. These drawings shall correctly indicate the work"as built" and shall include all modifications of the work and additions thereto which have been in--

corporated. The drawings shall consist of approved drawings, legibly marked, and submitted one print and. one reproducible each to the Engineer and the Mestinghouse Atomic Power Division.

9.0 XHSTALLATXOI'IADD XIlSPECTXOH PHGCEDUBES The Subcontractor shall submit to the Engineer a written, detailed description of his inspection and/or installation procedures for comm nts and, review. These procedures shall 'be submitted at least e

two weeks prior to actual start of MOHI(. Any comm nts 'by the Engineer shall in no way relieve the Contractor of his responsibility to e.".ecute his NOBK to meet the intent of the Drawings and Specifications.

~ ~

iKC 9/9/66 LIST OF DR/8JIi.GS Thc folio>Iing Gilbert Associatcsp Inc. dra~7ings set forth the location and extent of the WORK to be done and are hereby e::pressly made a part of this Specification:

DRA>1I1',G PO. TITLE Turbine Area>>Steel Framing D-502-0U. Column Schedule 5 Base Plate Dtails D-502-021 kezzmine Floor Elcv. 271'-0" D-502-022 Operating Floor Elev. 2S9'-6" D<<502-023 Control Room << Plans & Elevations D-502-031 Platforms, Landings 5 Stairs D-502-051 Top Chord, Hoof Plan D-502-052 Bottom Chord Roof'lan D-502-061 Longitudinal Section D-502-062 South Elevation D-502-063 East Elevation D-502-064 Nest Elevation D-502-065 Cross Section D-502-066 Cross Bracing Below Operating Floor D-502-071 Girts - Horth Elevation D-502-072 Girts - South Elevation D-502-073 Girls - East Elevation D-502-074 Girts - Hest Elevation Containment Vcsse3. << Steel Framin, D-521-001 Column Schedule D-521-002 Intermediate Floor Elev. 253 I

DKC 9/9/66 DBAWIEG Iip. TITLE D-521-003 Operating Floor Elevations 270'<<4" 8: 274 '-6" D-521<<005 Msc. Platforms Elev. 267'-3", Elev. 300'-4" 8c Stair Details D-521-011 Crane Rumray Elev. 331'-0" Forced. Stxucture - Steel East Elevation - Columns, Girts Bracing Framin'-521-071 Zc D-521"072 West Elevation - Columns, Gix t's,& Bracing D-521-073 North L'lcvation - Columns, Gix'ts & Bracing D-521-074 South Elevation - Colums, Girts & Bracing Reactor Auxiliar BuilcU.ng - Steel Fxamin l

D-522-001 Column Schedule 8: Bracing D<<522-031 llisc. Steel 8: Stair D tails D-522-041 Roof Steel 8; Crane Runsray Elev. 306'-10" D-522-051 Girt Elevations Xntermediate Building - Steel Framing D-523<<011 Column Schedule D-523-021 Platform Elcvations 271'-0" 8: 278'-4 "

D-523-022 Platform Elevations 293'-0" 8: 2g8'-4" D-523-023 Platform Elcvations 315'>>4" L- Roof 317'-6" 3051 Roof Elev. 335'-4" 8: Stair Details Service Building - Steel Framing D-531-001 Col~~ Schedule 8: B"se Plate Details D-531<<002 Ih canine Floor Elev. 262'-2 1/2", Floor Elcv. 271'<<0" 8: Rooi'

'i .:.l:ll!i::0:".t. Sl'l;CI "XC!:.TXOFG I'ox O':.'UHCTUD!'.Ii "Qt!l37~~."1l.

For "'~O Of. J )c l>OCEANS'l'!!A. GAS i>t')l) 'T!'GT~T.: C i".0 ~H)RA'i TOi')

llo<Aa885- l'p ik 8'll .ioi. i.

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8 l'rronf..'t '1 col!O'Gl -. S.n u:]6 con'GGln]"-Gn 6 v88 883]. !'Ii1 ] OG dos:(.(Mt 3d on I'Pa IIX ]g S v I'.P( i j>"'j]G (,',.', tGr:))i".]P'(1 on 0;" '<QG 'Pip')~'> ]c.'"en"z r4<pio t]o I]Qt<9.]1 ~p'.]0 1 Ggu:irGd 8<~rGn,'~tj] sh83.l. i. 8 'Ln I.ccox'do]1QG Ili'~h .G u>'lod 8 vcc(3.0n <<GB {b) Af Lor I!.-:]..':2'":vc: ~ '.".'": ~32)3.ix'j Q. ~8 i 1 r(I p)]:>> c: .; 1's(1 Qn(] "'.".] .

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Or'. "O i,i t:(cool'tf.". Of Gnl y n"-tlz~a<<,! .,'a",1,'~~ s)L"-. l", ()e la~<'(id

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"::-'. 1~.) cs c!. thc .".:. c rose(a eaa!gre pste J. L'e su{).J<.G'G=d Jr, 'aA!1 Tonal.a".,~! <a;{ooret{)r;; for si.ch tests

)'nf.'inaeer !L3'a re.,'.)J.X'(:c f.'io Pf;prof'2GO Baae." nn'i'( be l 4'he

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be Ch;age(i;~i-;ho!it e=ccrt=(i nsci t'le

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>s2 COA)rt5'a'GO!(.'0a '{T" Golazso s)ig.-e;-;"tc shel.'ol)for!  !.0 !'ro-..os"d aa".): ~0:1 "-nd 'x the 5-'3'a,e 0f 4 en'Ql'a( )>eoa'3, GJ!136 r Of 1 UL'1 0 nnorais 5CBC LS~J <<Rtn'..On 3 SPECS V CQ'JTa'n .

>N!JQl)SS Of vhe pro 03'0('. 'a{r,.aregn te '-"-"1nall QQ 8!lbra'itn'red ~a.'he TCS j

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Lebo7'(ltor .";Or Sl!(:h ""OS'vs ."ae talc }nrn$41eer B.-.ay Xec!li:-a Tih? Q~r~Ve~eto am.ar. ~ ~v ilhaell !10'i 0" lL'lK. tQless a.of)1Y .aad !)y Gn e L'1',ineel in nTri vi 1, a i t3" t)e ros;llv'f t.'lo %st have b=en escertearai-:d Tl)e -ource of ta:.

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'Ava. '1eeX'e Sh'-%J l !1ot he Cha"-i)-. Taith OLltr the aak'i Gten BOQrov"-'l QJO I!!ieel aiuJ{l Sir]8 0 f 3-':farci QGS Shall n{)tn be 38r,"rer a'a'!en l/3I 0 j. ta.'!0

)l7a.n." EJ!a! (U.!1"~Slca1 Of v a> ~aeC'b~ar naoi' "r{'87'!1""1 3//1 Of. tC- C OcTa" disa":nca b "'.'::csc: s.cfc:i':i:.>. 'cnPc, Tcs i(sz.:".Lsn S.;:e ci .".."1;e-'i'C v)ho7e concxete i- used For fire')rsnoo(Lin;; of struc'v!L",al steel shell ID Qo G be 1'2'f'er C:1"n Jj g 4:;8 oi 8 G'!Oc" beta"Jecn fo'" a! Qnad st3'GIQocro Ln i i:.",i vion, to G' n bove JJaenticned ll Qit .'v.L{')'."s V1e ~9xi.!

ccrtlaons of astruct!.=e LJQ sisre Of verio)1 shell no 4 JrOX'Lriora Of. aVruo"6!Jro J'Xia7al'9! 5:Li C 0

~A f CO .X'Se a) pr! ro..",e'a:0

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Hcinfcxced fou{ld(ltion TJ)..i.ls, "Coti)...p8) CQ.SSV..O:!nd Subetrf'.CrVuX'e l l/2 il!ch - s 7,'(ll".. S

e l'>I.'>'il< }(1>..UUC.}.}!G iii'ill)C f J::>k

! 4>oy'(:(".}Icl'}j> ( ni}s..::.hg.ey s>l}<<.1 L bo <<I}('ed to ll 1 s>uruc t>}z<<ll conc"" <<

"'5. 7>(> a r("('l'" "C(!. 'll1 I" >ha'>'~ CC ">h:>'>""!<<"I"e '> t ~""i'"<<h} Q'n!<<> l. r<<io OI} Ca+

ti sar' r00 <!<<>l. <<ryt 29 (l<>,IS><<> Tho,> '.lf>) (t>lre (i.'}Gl,.'. bar' r 18 >t>'lK "'>l "u" i <<l OI'o(.! >(' of +I l,'l}('II'! (,(<<1 Cp!!'Qan>,y'~ 'Chn (}u:}r}t>o .'.y 'to be SQQcd tih>(.

COntrol::) >~'~, te.'>k)cra'u})ras and:.h:}:r"=ihed Of;:~)>;in;ha11. COnfer!:.;33 the }ro}1<:,fa(:ti}rcI's r(!Coil,cn(}a>ti.:)ns for:lso nf .~aeiI'rod"cu<

'.lJOCU}:

6.3 C CHL"I~'(.i',I AdM.zt}1I'es co}lac'31}l}1~< calcIum i}loridc sha3.1 r.0ru ".escd, 7,0 ( i! T!."}k ~l'l!L}l':.'(TKO

      -'".3...u!>1       "!atCX'c.'>Cut I'au!.0 fC                                             Var).0}}S StI'C}1gt!1S                      OK       Conor te                Shall be as
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haCL Of Cer...nu 3000 0 0 FO!ki) >OVK hh 0 ol G}'I (ER:l>L

              .41: I:ouy..d                        co}1cr.         t            hall be for!"Qd, including th. Sides of o'..Qr (:.)r-ions of structures foo"'nd b lo: prad", ";rc>'.Ot that roc}- "ul':

Sfl<<'>>.>. bC }}Se(t <<:<<3 for foy'QI'. C(}1 Surf BC- S 83 Si}o>ln On t>ne lE (l JJ,n<<

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           . and/or as (.';recrue(l by                                            tAQ h!:g."'.!}ccx.                     Earth cut,I shall not bo uscdl foI '"s            fo"          voI't>1.ch 1 su!>faces r~lLTi"!!T!}L For I'".;-;h-                 ll       be >vood OI }}stol tl}auu are of.suff3.:icnu stren! th md r3.r'-GI.t>" 0}} l have a u!!f (cc s}!).t<<}olc for t "9:.'C(}l}}.'>red I1}1'!.s!}.

T f lYOOd:l.s I!~ed uo for('! COSCI'e }Ã '>)h>at '>'>!.ll be 'IZp:)S" (~ iD Vlc I 5.'~ Shl>l.} bo. !:K'.d9 Vl>: \">'I 3/!! .n ttl'!.C. ')) '.l.as> Zl:! S. j( ".'.I /for}":};OI'rI iy "e

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of thc Coat'ctor. i o .'.})Op (rr fiel<} d ':-x.'in;; for for!I v(or}< need I)c sub)!. 'I"I'G } v) '<'rho }'n<inoar. 0;.xl"".@in", Z~r bs=..!<IS and gir<}crs 8!1:;13. bo <<c (}<.-~gn d bhiai thay'C."-n b!1 striI)I"=d 'Nit;"o!!t cis ~M'0inr. Ml>> in'UI o:.."t" <U o(s'-"~Ln(< costs>> or c n be restr l.'d I I an accop'}<ibis annero 8.p) 0<0 I! i<.'i>}>R Tl)G,'F'inGGr SIl 1" }I< C n ultr (} r [;'ar(}in" t<ne QIAQarLng Of I)eal:.8 and. 8:abs 'o COI'oansaic for ant;ic::.pa':Gd def.'.Gcuions in th fo).';::-

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                 !~coo'; as                   nomic<'. !!ereinaf':,Gr, fore<<or<<                                   hall be consv('Uc'Gd Ho as 3!ll Urs U'.a'v QG concrcste SI.L~.'! <<cas
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                                                                                                               "'ill      c<nf          I(O>>'()'C to L. "') OS of }'<rogosed ACi >01.                                            o 8'.;(kgb:.ala".e 3inar n };hc con" ain!L)Gn.b -"G"'s.'..L 1!hcn used as ". concrs+G ..or".I sh."11 be brace(l a 1d shor'd to ensur tha('r u'.lelee <<ion Goes no t< e:<<.ceo. 1/4 lnr fo                                                         (':   1 arc leng""a of 10        ft I"Oj<<U. !!1'g01Q<

T lc relic'ial of fora) 0>> } shal L b in -ccor(>>sn~': 7!i 1 < le re<In .F.-nt r of A,"ol'osa \ AC:I. 303. ~ Tne fo31< ".i J)i "'able s))ov:: ." )gyes<<' m.)1i7ux. St<ren.'(t})s ro ILLS"'d Oef<Ira t<hc fC i!"~~ i!re reiTOVG .. 'Llla 1; I.I KLUQ '(<L.'"r) < 3=:)I(L'4're ser." se <;alucs base<i on .0~0 ps. co1cr"... at~~nin-'s stre<)p+h un<'IGr ".OrI<.al'oi) conditicns at a tc)np;rab~":G of 70 de's Gas '". Ti)G ti.)LG I"'1!its::,'=a3.1 b increased for (oncrc~"; h1vin.".; Glov'cr s~'(Gr(: I,ii dovel<II:Lren'".c 'o 3NY81GR':Bl'=" t<uras 01'tn3r co))diticns an<! )I'","1 "G X>>cduCCd fc Ccilor "v"- dc'( .lo ninI< 8 '" Xl!< 4 n gr>>re abaci (o'<> d3 ~t.! a3 1 Su'OJGC to 0:)G aoo'ova3. of the ):Gi leer.

                                                                                                          ~i n. Streng Ih Strl1ct!Ira3                   ('3I.(.ss          .fica I<i cn                           Recvkrcd                          }!<<1.nr   xo .I.od iQ.QGQ            of     foot<in.'~!8! "183.18                                           500     08'!                      1 day S~ <.Gs           oL OG.""0'! "" rac1"8 co                              J.LUiQS          1500        II 3 day, iorfls unde" f.<l)or slabs                                                                                                   7  days Gcn       lzrinIX I).Idex 'Ice-::8, gix(ic).s,                                                                             10 0:."Iys fla'~         L.l.rlbS 0 0 <
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chci:ica3) ro~positicn an(i sp"-c'ica>iion requir(:zc?)ts on !?ochcnic Ll pro f:er <<-es o

         "..'j'i;b ) T.(<E i'P.3)!KC hc3ded ')iro f"brj c                         .".Q" .(:Qncret" rcinfor(:(:):.".nt ."h33.1 conforn to "8",cc!.fj.c." ion3 fox i(- ir)e!                               -irc ~ abric for;.'o?.Crctc jleinforccmsn                                                       '!'

7< )Tk A .6 >".)1I,:a.'.).:0:.:.Qd vlir.: f'oxic is ( o." lan .".'(!. Gs load

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car- 'in'( r(in:;Orcc? 1(:!'~:"'",.(i silali be sp3icc(l i?. accorilcnce vfith S"=ction .'.rJ5 (b) o:; ':;0 .Osc(! i'. 301, 9.3 ThQ col!'>>rL'c 4. ha .1:>I,'),'r.t ". ".<'.i..!r draY!ln;;8> rc j?:Xor

                                                                                                                             ~     n inE bar 0   tel'i)           =',i .i .)i) .'U.;)          is:!.'l    c'1 a '              u()c(.      for ii'.ic;.8 )r..c: Q.on                         c    ld placentas,'- og -i!:c x(.-'.::!:.'0:.'Ocr~=nt i)i. t!!e strhc filL>> e                                               f   x'18 En@i?!""Cr'i aoorov:.!1 (:.".~ t:.!o ("';8::.13 are                                    i    i general co~ip iMCO "lith t.le Cnpin CZin w".".;".ip.r                     ..

Jne Contr."-.c 4:; shall sublii 0 thx'l o. 03,'ilits of a3 1 bsr Fists and plack.:.i", d c'i"'in'~s: cx x si~ c'7 op ij!9 '?)cj n'r ~ .,close dry")ings 3'..~ '-!ll

       ~ oe c'ls fied Gx!<'orti::>c(t priox'o Sub;"'!!.ssion Glad sjiall cont'-'i!1                                    ~

ll 'gl'x'e'l j 1v QrR!9. !Qn fhs 'QA trcc vor s'ia3 1 ?(si;e correc (?icns c g 'ui re@ b$II bhc !'naincsx cs+d Fj ! e .gi. ih thc E'>Bi'-ineer an unFQ3 6'-d rsproducib3." o<.'";ch drain< frol;..".?hich cl."..an Gnd le~'ible grin,s c' be li acc i!j:l'8,"cv('d r- producib3('.3 (i!ill. be ".3 stsQip-d cnd l=-te(j One set of th(i QG)roved dra:tint,s,"ill b" retuxned to the CQ!i>>rac l)gprova3. of such drat'irgs shall not rel ivc t):e Contractor of th(. respo!isibi3i'..y for errors in '(hc bar. lists or pl.acj.ng (bav(i;>(is: 9.Li !Qi."il0".Crl!C STl.,'L 'P),?CL'S Ho sp33cps Qf re info! co!!,ent sha: l. bo made c:(c~ pt as shonn on tr?.'e LPi.'Pl':" n~i(s~ oi, as specified here1ng or as Upc "Qx'ed bp'he 'En~Pi?!e(!ri Lag' t sp3ices in ?!sj.cn shall not be used fo r bar sj )ies larger thl!n:r'll ))herc t);e 'oar si:>c e:;ce'=d3 /rrll, CAj:.!ELD sp3ic"s sl ."-...'.". be used to dcve3og 1255 of the ?)inj.Li:~~ yie3.d <.oint stress of the bar. Yestin!. of C.i))i!LD splice.". '.rill b bacee on a xandc?il s'~p3in!; i gxroccduro ti:G..".inr,." a ., iatis i ic(!1 'ovalu.'ion. Ki.nimu.") la(), sp" ic(<< len~~'.!is si)."11 oo in accox(janco ':.;i t!i .'!C.L 3"..-~"-. jul  ! iip

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JafuCX' 0!!CX'3 ~- lS L)380- d Dj 1 R3Ca.O'" ColYL';-'.I-".'l. bo COStetlI "i'-:. t"7 l .'-'-.i.V7'0 .'".'.ATi:'a J.J: t')I 5 O..i('. ~.. l .."3(:.I !Il .a;Pl 1 be:.'t:..QUx'Ocl bJ YJ33. s!fl'5 'L(fl!"d... "tcx' (t".1't'i Lncl.u~t.TJf','al;!JL" c-."aO c.'!t"j..(017rCS any b;-i J(ePSVZed Ci't'qel by f 0" f V:(?iVh"':s" Vc j." ' 0 73.C ~ Jtae - GXt ';.SI

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coat'pj(atec'. v,j.+2'.i!I 3. 3/2 ilours o). befoL e ~~0 dro:n haQ been I'evolse".

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                      ~L'oo(l k'o .-- beCGecn cr)nero Lie rrrd f~rou't'r can b.. oo gc!3.!1OQr                                                     The corfu'-'ces sba13 hs .'cari fled rouvhenL".d;!nd all lai'ua!ce re!!Ovcd.
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1 Tj..) udL'.."r.!LTV.!rIP.L of:vir "".zclI>.c"-lions ..or

                     ,'L'en@"I s UQcoatr93 8'w 'Gss she'll co!!sist; R=13.ev-'Q t'iiY'e         for    's conforr.='-ng to
                                                                                                    .resru-tensioninr vre"     '-..'. ConcrQYr-.

lysi;oaL es !.ienufacturc'.. p AS>'~t h421-~5 cnd shall be '.he Bb!r" hy Jo.c j~ T. ".Ve so'.x .~ Son, Xn.".. The st, el t,c;!cons for bricatr'0 v~'ii'h ~c folio'A'ln; col!ajity contrro! prest(('ess:.:(.'onc."eve'L"'ll 3' t)roc c'.liras Qei g>~, observed!

                                  ~

a," f"nys.'.cal ".a6 ch r'$.cal test r Ports sha3.1 b: sl!omi.'t d to the i.n(rinoer r for each e3. o" ro.Ye.

                       'o.. The                          !;en(';on fabricator shall cut sanples fr)ln oach cn(! of a
                     ~ reel foll! bLLE'i('ron.lcs(ts a u Jlo Cn( S allot 'ue85 vh 'l SPeol!!Lene Thel O                                                                      ~
                   . tesvs shell ensure thav "vh *Tv'.r(l rup4'>res bsfo..'e ~.":).3"r('f tho bL!rv~vonpead KG '(harv Ul 'I'i re lGe!!trs 'l'he pcs L(!GL ro(!ui.Ã .c'ntrs of PLulai> !~421m j

lH.:;h s+vren>"vi) '-'1."c s v..el bars 't;al3. con for.-;! t,) SL'"'C!..r~L STREGST!'FL

                        <ra'Cion "!ith a'~uarantced
                        ~"~ ni;eau ul"Laatc Gtrenp. b'a O.". JVG,GCO                                                 D."L.o l6    0 i'iK)T'CTTO't                               0"!2"'!

l ock ~zlchors sh'..>.3..oe Pro!'n't(! ii! "0 s l'a~os r 0 6!e r full lens" t l all .' s.'.!o'::L on '" . i'r,":.>>.Lngs. Ti:c r(,cn('on. in

                        .".hall         Ue o;! LYn'c./n(.:e;i construe';ion.                                    ".L'no ton('on         s use'or                            unbonc'.e'a COB.S i:-"u U.O!l Shall "e Contre L L'U.rr!L (rl'O;.SQ "'r!"..                                                    peed      The type Or pl
                                'r'aaRS                       a g Vv'I'(-. lct A

n(r S.?a ' Oe "r t(.'C C).IICa ~pons to f.;c ggs!lcg,

t. -
                                     ."                  ...;)...,.: ".
            '!()  "      "!'L'>.'(~.-!.'0'f                     (>!  '"lI'"~'j'!"'l')T'>6 !'04l'::.

1 3";

                                                                                                 +L r

I 0

i~i.i <<:ol c. ~<. 1c v )1c=" d:.'i ver si !!ll t((c3i vcP. Ulis 1" <:ONE d) vhc Tcs t

                                                                                                          ~                                                    n" L,:UQ?'"v'); y ':8            son))ol av '"hc 3QC()'Cion I!I)erc tile col!CI'. i:) Gc3                                                 7O "cd.

(!hei= 'v'lc fo) ~d ai'inn'.; o" concret(." si'ructu>:.'.".!)rc sho':.'n'n tile w3.'P-'f'.<"'"8 '1" 'Qjzl</ 'o.'aced Qn I'1'QU') .i t!)8 sub 1'a<iQ suDooi"01)1g LP hal'). L'.Q<<.83. ann "r.'.)u..d to th" 3i.ncs cnd f".).'cnsions sho:"n a'nd shal3.!)8 il':;c of (.'Qbr<..".;)nd organic fff;)vcrial. 'I'ne s! bpradc sill<ll oe co:!,!3'c(I by u .'?:P. a )I'< 'Glfbie ccfr'0ac vox'D !! dc)183. vy ox at) Less f p >><G'<ied..'!9(ilO ) a,,'!>u)fl do.')s<<vyo')r~e i).i)tel/ 9'Qx'/- olacin..)

4) c conc).'"'i'8 t'- '3< 3:"""-: s;1 ll -

cond<<. ion" shall co))cr .:" be pl'.Ccc! on fl'ozon::ubgr dc z>awol"i.al. i;<1(3roug)3../ '!Ct veQ . 'ndo" .0 19FF!Cd/ 8 vel I befo.."" an)" ConCPC'te '. S 03.< C d 0 1 O'I ilf(K' ) Ci Tocl(3 . '<. 8 I'ocl. sha'!3. be ca: efu3 <y ('eaned of all dix'~, P".'a<<jw;33 hogdcgs3 scale Loose fra.():,e>>ts a>>d other cb;jectionaolc sul'.".~vw(::s by a<<" and/ol" v'at I'c v~vin," -".'nd orcofr<iF!~ <<nd .).lail t1an c('. thox'Qugh3J<!8 t)uod ZiPplo n(3<<ai3i.c ~viOn l'. aa13. b p" <<joll 'to vha K))ll<<incCl'nd<t O' CS v." nE) i "Cor'tOry r)lio" 'Vo Ol Cing COI)C('8'.8 On nubby<<a<:.8 to imraiv ther~

       /                  io insnec'(. +he subg).'adc.. Jt is 4".;8 intent of he unpin er to maI.<)
  )</I                    .. p'.:Qtogx'af;l c loco'd o eho sub:.-ade.fGl'elc(;tee             lpga                               a"Qas of ti)Q p~

CO'1 ua3.nÃ~on v VOHSC".o 3.2)2 CO lC!RT l~G if'."!2LR II./!'.=E;!

                          <)nd     <<'o          il'Cu'ra'van(les             Shall     COIl   rCM ba              dC DS:.ted     '2:ZQCX'ateI'<<

12.3 .:)i.:Vl )lS'".;9'i V i( CO! 1BX')...0!IS CQn accol'd -lice 7<i l PcT.'ha be Q!/o vcc)vcd "1  !!1 a(9in ~ v c(;o.)l!ficndcd '.~x'8%1.ce a'i .'L'sc Bea').)cx'o)ldll.lions fol'(lint:Ir Conc<<'et" vg 9 3.n rm. AOJ 3O'-.v., ".Itd ".Ce o,"I;!.81)ded, tic for i'o'v 'I ca'.-.her Conc;:(lt:.n/' j!Cl 605-5' czcco! Q)av accolc ito"'s such as c')lc);i.)a ch3ori.de an:l

                          <'ll <)<<    fl CCRC         O<7<.  <<undS Shul         l no              'I<<C, v OS ue(.'C)<,   ~
              'l!)8     .. nisiled        c<o)lc.':-" ';:   Bul I'.:;Ca      ot   83..!. r.!<Qo<<.'."'         Ia.s, i'::%'o 'i  f)on !let'-'3.3;Lc
      .  ',,O Ci;.."1:-.':,:    'I'::f 9-':.0 J'E::7":.I::
                    ~                   A                 ~

l, ~ >>'j 1

                            )  '<,", Q )<!    (;c';;)",     (,   ~  <<I <, >n,il / ~

pl, 'i<) 'I...I.!! E...<< 'I:! .d ':..i<1:!1 it))a'~

yi Tk>8 '.O'A.i::ot')r )nsul'iric:. -0 3:0 'ol,.ced ver';ic .3.lj af :lil>st t 10 fo u'1(iri v'Ci!1

               <<r'l013 G a!1(l corizon v                           .i,<<"      urlder        sl(<<~o. 011 pre!(>e '}1G]., l 0 St:>xofo"",! SB
                                                                      'n.':

0;:,".Wdod 0'.<<; vg->> '. t-Oni OOcrc} aS r~,n>:.f.::;Cl;l)X cd >)!~ v}20 Dov> C}rer.".ic:.:".. Co!r>>):12<<>>'h>'nsu.Li;:i'>.Ox 3;oi'.r i .>2-')3.1 3)e one:322C.! t ic}; "n(c:;}lell 3)c

               .".ns.i<<lied ir! !ccordalice lait!2 ti!0 rr>anufa(:tl>rcr'                                                                                  el~ lit8(}:>.r!Q 'uruC                              t'n 8 l<$ .0 <,lJflL'ETX C(X'3'F"r(OL Tj STS T rr<<>".mc         v'1  r<<ej,Qu<<GG, t/)r,'i c po;;8( 1).                                     /isis                   'c';ill ol: val 0 v,<<n Seri j ces of      .":. Tc"-'vina L<<'.'Cr-torY ':;!r<<.cj2 >0).31,                                                       Dri>ol'4):i!c ~ontrnctor gPF10'L<.">.'.i!i:ttX   Co!l'>riencinri CO "icX" i' 1'iorj( .r 0 8 ')reLirc'Q.POX~'}8Xer> cl!ic.tio 1G Of co!2tro...>cd;i>i':GG                               !;)in')!c                 is~t(:ri",3,". pep"Gec an J consiste;2cice Guitablo                fo'he;icrj( i;1 order                                                "s detorrl>ino the ."ii.z procort:>0>is neccss;:r<< to !m uco                                       concle-'8                 conforr.='22@ to tb: tyoe ar!d stror!give x'0 .l!'>re!'i;n'ts 0:!3.30<<(,. fol" }!Groin or on 'U>8 IJ?"';El.'1f~s,                                                                                     fl+'~reQF'es shP13> be               'teste('n                       ".Ocox'der)('8               "ll     tr"1         i   18     lateutr            od'.ions                   of t!:8 fnl>3@xing PS:>>! ':!)Gcificetions: C20, C40, C127, C3')8 "n('33(:. .                                                                                                                        ~
                          .Corflj)rcsoioll uos'vs .,Gh1=11 con'orLQ tro flS Jfk S})('.Oi..icclt:.0PQ C3) J.> Gn(i Cl+2 iD$ >> LQG Cont>2'Pc uo). G}1G3 }. O'4'or:Q.t to 518 i Qslirlc> LaborBtory
                           ". Guf"".c en% t-:.ri. boxol" conc-"-';=- rorj( v i!)pre.".::.8.lies roquir(>d by u}1- Tesujnj Le)OX" uor<<,'OX'le'0 ill
                                                                                                                                                    ~
                                                                                                                                                       ~

ccrr.'unco all. Concre-0 pre33.0'ests>> F

                       ~:  The        orocortiono for Vle conc).'8t!)                                                       >71(CG              villi         })( dc'vcl"."ii.ned by >c!Oti}206 2   of        S<)c""ion 3w of l'ro!>sed flC.':                                                   303. "Xrc! ".," }!croin'Co>ore Gpacii'iod.

3~8 T}28 .".ngineer G}1 .3.3. 3!nve th8 ).ig}rt z 1 Gj(o e(jJrsiv'!.ents in col!Cxic 'ie pro@Dr"i Oils "f n -CCG >GX'y 'to rlree" t<<'10 ro(,'uireb<<"-Iltrs 0 f tr!1CGN G Oeci fi 0'<<t<<}.0210>> Jn 62 event; 5!c Ccn'vrector x'uxnisrlod reli(l'ol( vest rocords of cotlcr ~'rzde Qui~li Gtrl GOD;,Oc'v or Ci'J3 v<< e!1P';j

                                                 !Oi"8'e'!'io nan>ces (

v>l.th rr.;1'ueli;lG fx(>11 d!e Gcmc so!:loco end of tjlc G.".m i '4GF8

                                                                                         'i ill coMoc'~to!1 J1 cu!'1 0'1'v rror;ip 'Glen ill3. ox'l pcs'tr of t 18 t>cs v<8 r, l)c<< -."ie(j 31,.);1-', ni!Ofol'0 >."[c>y he p.'Gi<<GG Qy Gll)~ ')rc disiorls
                                                                                                                 ~

f~oVel'rli.'1>c',:!Qtr}!OX'i i'n

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tc!c ty~ c-n'h ':1 f

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l 1 lr > ~ ~ % t\F ',',<<d (F(F( >

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C'ice"")E;> '.<".C'r "( lu 'C 01 C "ncc '. ~ 11 <<'. "~ K<<'"0(> 'l( .l. '<< ',} (XC>1'"

                          'F. 11         .>>     !'1:.";.'1   Or           .1   "0(.;p('"<<"..>) '. '<<G ><<'>>l!0>>! )ll                                                             '.1.i'(~O! p3 ':(:C'.
                             !!F(.," r     ~ 1   l,><<1"      ~  l'     >    F OC      <<-'1   <<,1 F>       a'          )     (,'1 ,',         F   il': 'r,l;     '        >

r, (>>>>(>1 r. } i <<';$ 'S 1

end "'r." remxi!)in'v'>.'o cylin<!Crs ab 2!3 d:.!ys. Slunn tc.",;;s;vill L. 8 mode:.v r !!d i. !i".,!) .". minimu)>. of ono tes v for each lO cubic .-"!res Gl'@nore "G pic "..Gd, also s3.))irp t>est". i.ill bo na dc on vhc conc'."'>o ber'ch used fo. ~".s'v cylinders. in '>)he '..venC v>)!L v coRcre be is g3!!red dil:.'1!)~P f:".CGA:>.ng v>SGther o" lj~" Qa'v " frceze is e::o-.cv'd (!ia";:;n,;"Qc rurin; -sriod, "n addi>'io))al

    ~(l  )    +8      cy..iI;d'::    '.)i3.7. 'o.".'>-!ds       for  e,".ch sot end be cur.d und(                           QLA ')J~i 1  G condi t>ion          8 t.>e       3hl'i Of      '3he     ~ 'vru t>i)           "(L>ic:h ).t> l'o "4 Qsen G 19,3 Ti)SV j;il !1,!JATOS(Xf f

T!)e svsluc)tion c ". 3 v '"Gsults ">"'l )o in -"ccord!x)ce .'i'~!) ChQD~v 1'( of ~ropose'.t .-".:T. 331. Guffici nt, i)ss'i)s '. provide an::vel.:..>>"..On of concreve strengti) in accord::,nce )'!ith ill be conducted to this sgccificQt>ion ~ 19.4 -Ear.Cr:t;:T C:":'CJL.:.".'.

                      )ihenever 3.'c ".s".";..':            ~!)e'est, or" t::~e 7x)boretory cilr,".d cylinders feil    co meet        i'>))c   rogvirc>m a bs et fol'h in 5)is speci c:>t>ion. Q!e                 f>

lepineer end for Tosh.ng Ls>borewrg SI)Oil hRvc thc r'.-".)b 8t v))e Conh~'ec vox' ezc>'n>se * ">0 Oraer ch;;,)L!es a 'tho pzopol tions or",. the mix to incrc~se ta>> s Crengt!l o He !U7 x e o'dQ.-' ona" i'est s of sp"ci!Iens cured ea>tirely ))ndex fi cld condi'a.o)>s. Ordex charges to improve procedures for p)'objecting and curin(! v! s cP- concrete. d '7G()uiro eddi vi e n<!1 ice to> 3.n sccordsncc ">it>) '.G%:lods of Obi(ei));.> snG 'Res ti).rig l> ' .Gd Cores:ac o"'>xeQ )."G "Ps of C ')cro'"'! 'i a"..'e. CJ! 2-6)!! (,/If>>:

     ).:5~     yU'Z       Qle c.'.Ors!>>Gn Y>.o). Gc.            tests     f concre'('>o i.> ox 'i2)G spcc3.f3.ed oil!i 5';Tp t>hc
                                                                           >)~ .~.

J.". to pl'ovs tl!",'1 the cu s~.on.".ble the coricl c'ce )orl; -;s'direct,".d., ':.ll ct She Co)3)'ii ec tox' 63>'pBI?SG

ADVEKPi4 HOe TO l TEC!iNICAL SI'LCXFICATXQNS FOR

                            ~  STRUCTUI.W~. CaNCaWE FOIL Tf!E BROOKNOOD PI %MT UNIT NO<

OF TIIE l ROC'rIESTEIK GAS AND FLEC&ilC CORPORATION ROCHES'LYB I EN YORK 4.0 Cl"'ZAT Second line after the words "TyI~~ XI" insert "for @odorate AM@ of hydration" ~ 8,0 FOiBDOi>X Sol GENERAL At the end of this ection add tho fo3>.owing:

           "All ox!closed     edges    shall be chmferedo            Tho size of the ch"mt'er   strip shall        be 3/l. Mches unle.       s  otherwise noted on the Dra'ringso" 30.0  JOIKTS AND QIHEDDED XTI          re~cd for tho placejfent of ccncrete thereon by cleaning thoroughly with t>ire brushes, cantor under pres"ure, or other !>cans to remove al3. coatings~

stains, debris or other foreign n t;eriaD. ~ " lOo4 AIIClIOR BOLTS AI'3) PXPF 81Z~/EQ At tho end of this section M~ d the folios>ings "E>l:bedded items shall bo chccIced for line and grado after concrete is placed " ll oO I!LKIND CQk'CRETE ll 2 TRANSIT I4LXXKG At tho end of this section add tho following:

           "As rccIuirod by AS'Q) C<)4-65            a33. truclcs shall bo   cquiI>pod'ith a revolu,t,ion countor."

\

                                               ~ <<2<<<<

11~6 BATCH RECORD At the end of this sect,ion add the following: uAs roqui ed by ASTk~ C9$ -6g th batch t,ickot sha'U. also include the tin.e loaded, amount or concrete and reading of revolution counter at first addit,ion of.';atero" , 14oO CURIL'Q AND 5'ROTECTIOW Curing v;-thods detailed in ACI 301<<66 shall bo used cvzop5 thaC a method other than using a curing compound shall be used for initial and final curing of concreto in the containnen~ shello 19oO QDALXTX COHTBOL 19<1 PiKLQQHARY TESTS In the sscond paragraph change "Section 309" to "Section 308", 19 2 FIELD TESTS At the end of the third pmag.aoh add the folio:wag.

              "This cylindor sisal be bosomed at'8 days "

Add the following addit;ional section.'~20 oO le% R The chloride content, of ai.ing ~mter shall not exceed 100 p~> and turbid55y shaU. not exceed 2000 cpm."

DYE 10.-17-66 Revised li-3-67 ADDENDUM IIO. TO TECHNICAL SPECIFICATIONS FOR STRUCTURAL CONCRETE FOR THE BR03iY'iOOD PLA NT UIGT I'IO o 1 OF TIIE ROCHESTER GA5 A.'JD ELECTill'C CORPORATION ROCHESTER~ M"U 'lORK Add the folloii~g section:

    "20.0'RGUi'JDXIlO 20ol  CONCRETE     REXI'PORTENT All concreto reinforcerrent embedded in the side wall up to Elevation 252'eet slnll be made eloctrically continuo:is by bonding all such items together by means of the CAD::IELD process       Arc welding concreto reinforcement, for any purpose including Cho achievement of electrical cn>>tinuity shall not be permitted unless not,od otheria.se on Che Drawings. Standard CAD<'IElJ3 porider shall be used to ireld copp..r to stoclo         The, tio3ding material shall consist of a copper thormit mixtur employing tin m tal        in   an amount  to effectively constitute from ~i.5 percent to       5 ~5  percent of t,ho resulting weld metal.

P ior to CADllELDL~IG the su fac of thc roinforcoz nt shall be cleaned free of file rust and rill scale and filed with a coarse or grinding wneelo Every precaution snail be talcon to remove only Che minima~ petal required to obtain a smooth surface. The CAD'v.'ELD process shaU. be performed in accordance irlth the nmufacturer~s printed. instructions. Tho concrete reinforcement shall be >r~ide electrically continuous at a mnimum of th."ee lo ations p r circumferential ring or vertical bar and shall oo bonded to the contairment liner at three location approximately 120'part. The bond, connection to tho roinforcomsnC shall bo staggered in the vertical and horisontal dirccCions Co provide a minimum distance between connoct,ions of five foot . Tho staggered pattern shaU. be repeated no more frequ ntly than for every fifth bar. Thc CADYKLD splice used for 1I,.S and lQS bars will provide electrical continuity. 20o2 Tl<iIISION BARS The tension bars s)iall be bondod togothor by the CADUELD process a>>d a di". 'ct. bond;sado to tho containment li>>or at throe locations ipproximatoly 1"0" apart. Thc connoction to tho Cc>>sion bar shall bo t,o thc outboard faco of th anchor plato GILBERT ASSOCIATE~ INC,

ei.bedded in the side wall Mell away from tho l-3/8 inch diarrater bar. 20+3 LIMITAL CONDUIT Ths metal conduit for the side;;~ll tendons shall be m-de electrically continuou for their full height 'oy tao!c welding at throaded co>plings. The conduit" shall be bonded togefih"r at approximately Elevation 235 feet and a dire b bond rade to the liner at three locations appro::imate+ 120'part,.'XLDEPiT ASSOCIhT""S) ZiXC.

9 ADDZHliUH HO. 3 TO TECH!APICAL SPECIFICATIOi~lS FOR STRUCTURhL CONCRETE FOR THE BROGiiVCOD PLAIV. UillT HO+ 1 OF THE ROCHESTER GAS AND ELECTRIC CORPGRATIObl IKCliIESTER>> IWi'/ YCK< 10,0 JOXilTS Ag) EIQEDDED ITi~~"IS 10,3. COI'ISTRUCTIOil XTEHS At thc end of this seci;ion dd the follosnng:

           "On con  truction joint surface in 'che Containment Vessel including a13. vortical jo5,nts in the cylindrical boll and all joini;s in the dope an epo:qr-resin compound shall be used t,o boind  thc net concrete with the abut~in@ pov~. The
          .epo~-resin compound shall be one of the following:
a. Epo:o;ice field Serviciscd Prcducts Corp.

b, Colma Bonding Compound Silva Chemical Epotox Bonding Compound - Toch Brothers, Inc. Corp'., Concrete rurfaco preparation and ~he mixin;~ and application of the epos-resin shall be in accordance with who manu-facturer"s pr'nted instructions. Ego."g-resin cori'pounds o~h"=r than those listed hcroinboforc shall not be used unloss approved by She Engine r."

I I

DEC 2-13-67 ADDHHDUI4 170. 4 TO TI& TECHHXCAL SPECXFXCATXOHS FOR STRUCTURAL CONCRETE FOR THE ROBERT EiYNETT GXHMA HUCLHAR POz/ER PLANT UHXT mo. 1 OF THE ROCHESTER GAS AKiD ELECTRXC CO'RPORATXOH ROCIIESTER, HEN YORK Add the following additional section: "21.0 NATERPROOFXHG 21.1 General The exterior walls of the Containment Vessel and Auxil-iary Building from the edge of the base mat/ring girder to Elevation 253'-0" shall be waterproofed on the out-side face. The waterproofing material shall be as manufactured by the Plinth':ote Company, llew York, H. Y., or approved equal, applied in accordance with the man-ufacturer's printed instructions. 21.2 Specific Requirements Concrete surfaces shall be dry before applying the water-proofing materials and "hall be free of all zins, ties and similar projections. All holes, voids and honey-combed ar as shall be filled, patched or repaired to produce a smooth surface. The first. application shall consist of a thin pene-trating coat. of Asphalt Primer applied at the rate of one gallon per 100 sc[. ft; Prior to the application of membrane coux es the angles at the intersection of GXLBERT ASSOCXATES, X11C ~

DEC 2-13-67 Page 2 walls and base mat/ring. girder and at corners of any offsets shall be reinxozced with an additional appli-cation of I'.OIifOPOPJ4 compounQ and YELLOW JACYET glass fabric which shall be allowed to tacf" dry prior to the application of the first course. Two plies of membrane waterpz'oofing shall be applied using YELLON SACHET glass fabric embedded in GI1R-100 compound. The Quantities of components and the rate of application shall be in accordance with the manufacturer's printed 'nstructions xor a hydrostatic head ox 20 feet. >%ere bacl:fill is to be placeQ against the waterproofed sux'- faces, panels shall be'urnished and installed to pro-tect the membrane. These panels shall be 1/2." thief Plintfcote asphalt coated insulation panels attached to the membrane arith spots o - asphalt plastic cement. GXLBERT jASSOCXATES, XMC.

V

~ ~                                                                                      DEC
~     ~

3.0-3.t-67 O ADDEi'Kv'!i 'lO. 5 TO

                                       = TECHIiXCP L S~i";CXI 1CAT3 0"S FOR STRUC'TURAX, COZCRVr=

FOR THE BROO'C:.OOD 'KIlT U~IXT I'IO. ROCHE"'STER, Gi.S P.ilD i"'LKTRXC CORPO~d<TXOlJ RQC;l~iv<ig r J,'i:;I 3'Qg' Md tahe folloi'll'p~ sect 1oil:

             "22. 0  Pr".uP'.KT CO<~tCRKT",

e 'Nec caied on the Drair ~a.-s. 'hrv "turn x'equ>.re.".';cps for PRZPA'i(T COil"ZTE sha3.:L be iri accordance;riÃa ~he "Guide SpecJ.- fications for .'".:"'PAiii'Oi<CPU~'Z" as p:.'e"..ared by tne Prepa!N, Concrete Compmry, Cr.evclsad, Oh~ o, a copy of

                     .'.l3 ch 1 s al't L ac'1 - d Rex'etto as pa 4 of tt.'1" s spec" f3.cat1on
                                                                       '. I   a.0.

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ADDENDPi1 NO. TO TECHNICAL SPECIFICATIONS I"OR STRUCTURAL CONCRETE FOR THE BROOlSJOOD PLP~VZ UNIT Iso 1 ROCHESTER GAS AM) ELECTRIC CO~iRATXON ROCHESTER, m: r YORK 10 1 JOINTS QS EllBEDDZD ITEM 10+2 EXP(QJSION JOINTS At the cnd 'of this subsection; insert the fol3.owing:

               "The sealant   for all  expansion joints crithin the Conta~'>ment Vessel shall be   Do:J Corning 780 Builds.ng Se 3~.ant as manufactured by Doe Corning   Corporation."
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4 g, g PiiHLXIQi'JAP.Y ADDEIBUII I'IOo 8 TO TECHNICAL SKCXPICATXOIG POQ STRUCTUML CONCRETE, I"OR 'TI.rS BROG.QSOOD PIAiiIT UIGT MOs 1 ROCIDSlaR GAS APJD EJ~~CTMC COliPOHATZ01I ROCHESlM~ IE'3'I 'XOiHi AS the end of Section 22.0 PMPAKT CONCRETr",'dd 440 folloTAllge "There shal1 be no retemperu~ of Prepakb 4P Concrete."

DEC f s I ef 2-28-69 PHELBIZI8'Z<7 ADDEI DKI KO. 9 TO TECIKZCAL SPECZFZCATZOIIS FOR STRUCTURAL COi'CRETE FOR TIF BROOIG'IGOD PI/ill,'IITT I'!0. 1 ROCh' THP. G IS fiND EL>CTRiC CORPORATZOil ROCHESLM~ iv"8'f YOIIK Deleie Sec'~ion 21.0 VATERPROOFZKG in its entirety and insert the following:

       "m.o iu,r npRoo".xtr/wire piicozxw, 21.1  '"ncral Tne e:c'ccrior wall of the Auxiliar Building from the edge of the base mat to Elevation 25)'-0" and the elherior wall of the Cont~i.n!aent Vessel from the edge of the ring girdor io Elevation 235'-0" shall be waterproofecl on the outside face. The water-proofing material shall be as mmufac~ured by the Flin~kote Compa!Iy, I<a:r YorI<, I'Iew Yor!c, or approved equa1, applied in accordance w:ith the manufacturers printed instructions. The exterior wall of the Cont, inment Ve sel from Elevation 235'-0" to Elevation 253 -0" shall bc dnwpproofed using PZIJ Iiarine lfastic HD as manufactured! by Toch l3ros. Znc., Paterson, New Jersey, or approved equal~ applied in accordance Itri4h the mtu!ufacturer's
                     'printed instruct'rions      ~

21.2 'klaCs~r~rooi'in ~ Rooniromsnss Concrete surfaces sha11 be dry before applying the waterproofi~i materials a!id shall be free of all fins, ties and similar pro-joctions. All holes, voids and. honeycombed areas shall be filled, patched or repaired tn produce a smooth surface. Tho first application shall consist, of a thin penetrating coat of Asphalt, Primer applied at, the xato of ono ga1.1on per 100 sq. ft,. Prior to tho application of membrane course,. tho angles aC tho intersection of walls and base mat/ring girdor and at corners of any offsets;;i!a3.1 be reinforced with an additional application of IIOIIOFORII compound a!!d XELLO'I JACI(ET Glass fab! ic which shall bc allow d to taclc dry prior to thc applicat,ion of the first course. Two p3.ies of mcm'oran,"; wat, rproofir r .,hal3. bc applied using Xx'LLQl JACIG:T glas fabric embedded in Gi".;1-3.00 compound. Tho quantities of components and who rate of app3.ication shall bc in accorclancc with the manufacturcx's pI'intcd instructions for a h~xl::ostatic head of .20 feet.s. Nhere baclcfill is to bo placed against thc watcrproofcd surfaces, panols shall bo furnished and inst;allcd to pro~oct, the membrane. Ti!c e pa!!cia hall bo 1/2" Chic!c Flintlcot,c asphalt coated insul, tion panels aM;ached t,'o thc ll% lbranc Ifitll spot, of asphalt; pla tie ccmenh

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21. g Dooooo~roof i ~Rsqairemont o Concrete .urfaccs hall b. dry bcforc applying the dw~. pproofing TiMterivQQ and sha33. be free of all f'ns tios and sire.lar pro sections. All holes, voids and honeycombed areas shall b filled, patched or rcpaircd to produce a nlooth surface. All suri'aces shall bo free of dirt, dust, ice etc. Apply tlTo spray coats of RBJ 4'arine iAouid DCcD to a total th>>el<ness of l/o inch over thc elltil'e Ms33 area o

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