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{{#Wiki_filter:9203090246 920303PDRADOCK05000387APDR Pl,
{{#Wiki_filter:9203090246 920303 PDR  ADOCK 05000387 A             PDR
~~~4CALC.NO.+-g~-Og CALCULATION COVERSHEETFILENO.gZ-ISUPERSEDED BYQASAFETY-RELATED telASIDEIIIORXI0OTHERQUALITYNONQUALITYPROJECT5~A~g,OeTzc.vioN A.OJecTER/CTNNO.VAJADESIGNACTIVITY/PMR NINBEREWR+H81000PAGEIOF2oTITLE/DESCRIPTION STG1AF4LNAicDate'cTIOAICALC,-RN1CFIlA4PRooAAST:1-SZ-loG3',-i4.X-1O4.UNITIONLY'SYSTEMSAFFECTED5oSAGSo4-0Ra=ca,nPAcE3Ra.Sr~m~auroFPekoe~IRe.-ea.ToArrAcH~oe,sic4lMATps6EM~TEDboa,THis~~Mviod.REF~~PA@K4-FOR-RGPK~~CSS.
RGFRrt-'TO FACIE.IG.FDCL+1IlrtlulAC'TF fCOIJCLUGIOAIS.
CD'CCCD(ETO)BINDERAFFECTED'.
]YES-IfYesenter:Binder0Calc.FileNOVol.Pgs.REV.NO.DATEPREPAREDBYREVIED/CHECKED BYDATEAPPRVEDBYDATE~G~14a9'TILW.'~~4~o'Fmls/frb006i(12)
I=y,1 TABLEOFCONTENTSCalc4M-SLD-003 Page2of201.0PURPOSE~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~32~03.0ASSUMPTIONS
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~5REFERENCES~~~~~~~~~,~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~44'METHODOLOGY
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~65~0RESULTS/CONCLUSIONS
...................................
12ATTACHMENT 1COTTAPOutputforRHRPumpRoom(I-13/I-103) 5GPMLeak(Summer)ATTACHMENT 2COTTAPOutputforRHRPumpRoom(I-13/I-103) 5GPMLeak(Winter)ATTACHMENT 3COTTAPOutputforRHRPumpRoom25GPMLeak(Summer)COTTAPOutputforRHRPumpRoom25GPMLeak(Winter)(I-13/I-103)
(I-13/I-103)
ATTACHMENT 5ATTACHMENT 6ATTACHMENT 7ATTACHMENT 8COTTAPOutputforRHRPumpRoom(I-14/I-104) 5GPMLeak(Summer)COTTAPOutputforRHRPumpRoom(I-14/I-104) 5GPMLeak(Winter)COTTAPOutputforRHRPumpRoom(I-14/I-104) 25GPMLeak(Summer)COTTAPOutputforRHRPumpRoom(Z-14/I-104) 25GPMLeak(Winter)APPENDIXAAPPENDIXBDataInputSection-RHRPumpRoom(I-13/I-103)
DataInputSection<<RHR'umpRoom(I-14/I-104)
Calc0M-SLD-003 Page3of20,1.0PURPOSEThepurposeofthiscalculation istopredicttheroomtemperature profileexpectedwhenasmallwaterleakisintroduced intheUnit1RHRPumpRooms.Theresultsofthiscalculation willbeusedasabasisfordevelopment ofSteamLeakDetection Systemsetpoints.
2'REFERENCES Calc4M-SLD-001 Page4of202~1Calc4M-RAF-024, Rev.0"RBPostDBATransient Temperature Analysis" 2.2'echtelCalcg176-18,Rev.5"RBCoolingModes"2.32~4~2'SEA-EE-129, Rev.0"SSESUnit1andUnit2ReactorBuildingHeatLoads"DravingsIP&IDM-176,Rev.20P&IDM-151Sht3,Rev.2P&IDM-151Sht4,Rev.1V-29-1,Rev.9V-29-2,Rev.12V-29-3,Rev.11V-28-1,Rev.15V-28-2,Rev.14V-28-3,Rev.17C-105,Rev.20C-106,Rev.16C-134,Rev.15C-135,Rev.16C-156,Rev.12C-157,Rev.13C-111,Rev.15C-117,Rev.17HBB-111-1, Rev.6HBB-111-2, Rev.4HBB-110-1, Rev.9GBB-104-1, Rev.7GBB-104-2, Rev.4GBB-105-1, Rev.6GBB-116-1, Rev.6GBB-106-1, Rev.8M-199PipingClassSheets2.6SEISPipelineGeneralIndex2'28CraneTechnical PaperNo.410,23rdPrintingASHRAE1985Fundamentals Handbook2.9FSARTable3.11-62~102~112'2FSARSection5.2.5.1.3 CalcgM-PAF-001, Rev.1"HVACEnvironmental Analysis-ReactorBuildings
&ControlStructure" ICOTTAP-2TheoryandInputDescription Manual(User'sManual),Rev.1,dated1/27/89.
lp~lt0)hl'J1P CalcgM-SLD-003 Page5of203'ASSUMPTIONS 1)2)3)4)5)Plantisoperating undernormalconditions priortointroducing asteam/water leak.Alladjacentroomswillbemaintained attheirdesignmaximumtemperature forsummerconditions andattheaveragetemperature forthe,monthof.January(ifblue-boxdataisavailable) forwinterconditions.
Wherewintertemperature dataisnotavailable, thedesignminimumtemperature of60~Fwillbeused.Theroomunderconsideration willnotbeallowedtopressurize, astheblowoutpanelwillrelieveatapproximately 0.5psid.Therefore, aleakagepathoutoftheroomwillbeusedtomaintainpressureascloseto14.7psiaaspossible.
Thetemperature effectsduetoslightroompressurization areassumedtobenegligeble.
Theeffectsofadjacentroomheatuparenotconsidered inthisanalysis(i.e.adjacentroomtemperatures areheldconstant).
Thisresultsinaconservative temperature profilefortheroomunderconsideration.
Theactualadjacentroomheatupduetothewaterleakisexpectedtobeminimal(whenconsidering conductive heatlosses).TheCOTTAPmodelassumesperfectmixingoftheairandwater/steamintheroomunderconsideration.
Theoriginal'BechtelCalc4176-23usedtheSteamCondensing ModeofRHRasthebasisforthesteamleaktotheRHRPumprooms.Inpreviousoutages,thismodeofRHRwasremoved.Thehighenergypiping(steamlinefromHPCI)associated withthismodeofoperation nolongerexistsintheRHRPumprooms.Therefore, thiscalculation willusetheShutdownCooling(SDC)modeofRHRasthebasisforthewater/steam leakintheRHRPumprooms.TheSDCmodeinitiates onthe98psig(RXPressure) permissive.
At98psig,thelinesarewarmedbyprocedure forapproximately 2hoursbeforeSDCmodeactuallystarts.Duringthistime,theRXisbeingcooleddownat,amaximumallowedrateof90~F/hr.Forconservatism, thiscalculation willusesaturated waterat14.7psiaand212Fasthestartingconditions fortheleak.Theseconditions approximate theminimumrequiiements whichdefinehighenergypiping.RHRSDCisconsidered highenergypipingforaveryshortperiodoftime(i.e.<14ofthetime).
1npA1'l


==4.0 METHODOLOGY==
Pl, CALC. NO.+-g~-Og        SAFETY-RELATED      tel
CalcgM-SLD-003 Page6of20TheCompartment Transient Temperature AnalysisProgram(COTTAP)wasusedtoanalyzetheaffectsofasteam/water leakinvariousroomswithintheplant.Theprogrampredicted temperature profilesfortheroomunderconsideration withthefollowing setofconditions 1)5gpmwaterleak(Summer)2)5gpmwaterleak(Winter)3)25gpmwaterleak(Summer)4)25gpmwaterleak(Winter)Theindividual roommodelsweredeveloped fromvarioussourcesofinformation, asidentified inSection2.0References.
            ~    ~
TheresultswillconsistoftheCOTTAPoutputandtheplotsofvariousprofilesfortheconditions statedabove.Thefollowing discussion isprovidedtooutlinethestepsusedindeveloping theindividual roommodels.4.1GeneralDataForRoomsRoomVolumesInitialPressureInitialTemperature TheroomvolumewastakenfromReference 2.1fortheroomunderconsideration.
4
Adjacentroomvolumesweresettoalargevalue(i.e.1.0EE15cu.ft.)tomaintainconstantproperties suchastemperature, pressureandrelativehumidity.
                    ~
Allroomswereassumedtobeataninitialpressureof14.7psia.Allroomswereassumedtobeattheirmaximumnormaldesigntemperature initially forsummerconditions.
CALCULATION COVER SHEET      FILE NO. gZ-I        ASIDE  III OR  XI 0 OTHER QUALITY SUPERSEDED BY    QA      NON  QUALITY PROJECT      5~A ~g,       OeTzc.vioN A.OJecT                            ER/CTN NO.       VAJA DESIGN ACTIVITY/PMR NINBER      EWR + H81000                                  PAGE  I OF  2o TITLE/DESCRIPTION STG1AF4 LNAic Date'cT IOAI CALC,-             RN1C FIlA4P RooAAS    T: 1-S  Z-loG 3',-i4. X-1O4.
Actualwinterdatawasused,whereavailable, asastartingpointforthewinterruns.Thewinterdatawastakenasthe"blue-box"averagetemperature forJanuary1988.TheJanuarydatawasconsidered tobemoreconservative thanFebruarydata.Whereactualwinterdatawasnotavailable, thedesignminimumroomtemperature of60'wasused.Wherewinterdatawasnotavailable fortheroominquestion, theroomwasstartedatatemperature whichallowsittoreachasteady-statewithitsadjacentrooms.
UNIT    I ONLY
0ip4' Calc0M-SLD-003 Page7of20RelativeHumidityRoomHeightTheoutsideambienttemperature wastakenas'9~F(summer)and264F(winter).
    'SYSTEMS AFFECTED        5o SAG      So4-0 Ra=ca, I
ThesummerambientwastakenfromReference 2.8asthe24hourdailyaveragetemperature, baseduponthe14ASHRAEdesignvalue,,fortheWilkes-Barre/
n    PAcE 3    Ra. Sr~m~aur          oF  Pekoe~
Scrantonarea.ThewintervaluewastakenastheactualmonthlyaverageforJanuaryovertheyears1986thru1989.ThisaveragewasbaseduponSSESMeteorological Datatakenfromtheplantcomputer.
Re.-ea. To  ArrAcH~      oe,sic 4 lMATps      6EM~TED        boa, THis  ~~Mviod.
Acomparison ofFebruarydataoverthissametimeperiodindicated thattheJanuarydatawasmoreconservative.
REF~      ~   PA@K 4- FOR-   RGPK~~CSS.
Therelativehumidityforallroomsconnected byventilation orleakagepathsisbaseduponoutsideairtemperatures of92FDB/78FWB(summer)and-5FDB/-5~FWB(winter).
RGFRrt-'TO FACIE. IG. FDCL +1IlrtlulAC'TF f COIJCLUGIOAIS.
Airatthese"conditions wasthenallowedtoheatuporcooldown(sensible heating/cooling only)totheinitialroomtemperature, andthecorresponding RHvaluecalculated orreadfromthepsychrometric chart.ThisvalueisnolongerusedbyCOTTAP.It'originalpurposewasassociated withthewallcondensation calculation usedwithinCOTTAP.COTTAPhasbeenrevisedandnolongerusesthisinformation.
CD' (ETO) BINDER AFFECTED'.       ] YES-If  Yes  enter:    Binder 0                       Vol.
Therefore, avalueof10.0ftwasinputtedforeachroom.Thisvaluehasnosignificance tothecalculation.
    ~
Notethattheactualroomheightwasusedinthecalculation ofroomvolume.4.2AirflowandLeakagePathDataAirflowDataThedesignairflowisprovidedfortheroomunderconsideration.
Calc. File                    Pgs.
Allflowpathsareidentified (i.e.supply,exhaustandtransferair).ThesourceoftheairflowdataistheP&IDassociated withtheparticular ventilation systemforthatroom.Thedataidentifies theroomfromwhichtheaircomes,andtheroomtowhichtheairgoes.Sinceairflowsarebalancedtog104accuracy, aconservative valueof1760scfmwasusedforroomI-13/I-103 (1600scfmx1.1).Avalueof1210scfmwasusedforroomI-14/I-104 (1100scfmx1.1).
CC                                  NO CD REV. NO.     DATE G~14 a9          '~~
$+k90CrfWXK, Calc4M-SLD-003 Page8of20LeakagePathDataAswiththeairflowdata,allroomsconnected totheleakagepathareidentified.
PREPARED BY
Theleakagepathareaisonlyusedtoscaletheleakage'flowrates fortheentirecompartment underconsideration.
                          'TILW.
Theintentoftheleakagepathistopreventcompartment pressurization.
REVIE    D/CHECKED BY    DATE 4~o'F APPR VED BY          DATE mls/frb006i (12)
Formostrooms(exceptRWCU),onlyoneleakagepathisused,aqdavalueof1.0sq.ft.isinputtedfortheleakagepatharea.When.morethanoneleakagepath'xists, actualleakageareascanbeinputtedtobetterunderstand leakageflowsbetweenadjacentcompartments.
4.3HeatLoadDataHeatLoadTypeThetypeofheatloadwasidentified usingthefollowzng nomenclature Type123458Description LightingElectrical PanelsMotorsUnitCoolersPipingMisc.Mechanical Equipment HeatInputRateTheheatrateinputinBtu/hrfortheassociated heatload.Thevaluesforheatloadtypes1thru3wereobtainedfromReferences 2.2&2.3.Theheatrateinputsfortype4heatloadsareinputtedasnegativevaluessincetheunitcoolersremoveheatfromtheroom.Theheatinputratefortype5heatloadswere'inputas-1.ThisvaluedirectsCOTTAPtoobtainpiping'information necessary tocalculate thepipingheatloads.Theheatinputratefortype8heatloadswasobtainedfromReferences 2.2&2.3,asnecessary fortheappropriate room.Toachieveaninitialsteady-state condition, amiscellaneous heat'load (positive ornegative) wasaddedtothemainroomtobalanceallothertimezeroheatloads.Thisheatloadwasinputtedastype8.
$f>1 Calc4M-SLD-003 Page9of20NotethatCOTTAPneglectscoldpipeandequipment asheatsinks.Thisrepresents non-conservatism inthiscalculation.
Asamplerunmadetodetermine theeffectsoftheseheatsinksindicated thatresultant temperatures wereonlyslightlylowerthanthevaluespredicted whenneglectinq theseheatsinks.Therefore, thiscalculation assumestheeffectsoftheseheatsinksarenegligable.
Forwallsandfloorsincontactwithground,themodelpredictsaconservative valueofheatlosstoground.Theslabsareassumedtobeincontactwithsoilatatemperature of55F.Tomodeltheheatlosstoground,alargevalueofsurfacefilmconvective heattransfercoefficient'(100 Btu/hr-sq ft-F)hasbeenintroduced onthegroundsideofthefloorsandwallstoachieveagroundcontacttemperature of55~F.4.4PipingInputDataOnlypipingwithadesign.temperature greaterthanthatofthenormalroomdesigntemperature wasincluded, sinceCOTTAPignorescoldpipeasaheatsink.Thisgenerally meantthatpipingatorclosetoReactorconditions wasincluded.
Alsonotethatthiscalculation neglectsheatlossfromsmallpipe(i.e.lessthan2"OD).PipeODPipeIDInsulation OD'ipeLengthEmmisivity Insulation kValueTheoutsidediameterofthepipewasobtainedfromReference 2.4ThepipeschedulewasobtainedfromReference 2.5.Knowingtheschedule, theinsidediameterwasobtainedfromReference 2.7Theinsulation ODwasobtainedfromReference F11ThepipelengthwasobtainedfromReference 2.4Theemmisivity wasobtainedfromReference 2'1Theinsulation thermalconductivity (k)wasobtainedfromReference 2.11.PipeFluidTemperature
:Thedesignfluidtemperature wasobtainedfromReference 2.6 Dgt1l('/iV'IUQ Calc&#xb9;M-SLD-003 Page10of20FluidPhaseThestateofthefluidwasdetermined byreviewing thesystemP&ID'sanddesigntemperatures/pressures.
Ifaparticular line-couldcarrysteamorwater,itwasassumedtobeliquidforconservatism.
4.5GeneralDataForThickSlabsRoomID&#xb9;"onSide1RoomID&#xb9;onSide2Thickness HeatTransferAreaTheroomnumberononesideoftheslab.Theroomnumberontheothersideoftheslab.Whenslabisadjacenttoground,aroom&#xb9;of"0"isused.Thethickness oftheslabwasobtainedfromReference 2.4TheareaoftheslabwasobtainedfromReference 2.4.Thedimensions werescaledfromplantventilation drawings.
Theslabareasarecalculated intheDataInputSection(RefertoAppendixA).ThermalConductivity
:Thethermalconductivity oftheconcreteslabswereobtainedfromReference 2.8,Chapter23Table3A.Avalueof1.0Btu/hrsq-ftFwasusedforallconcreteslabs.DensitySpecificHeatThedensityofallconcreteslabsisassumedtobe140ibm/cuft.ThisvaluewasobtainedfromReference 2.8,Chapter23Table3A.Thespecificheatforallconcreteslabswasassumedtobe0.22Btu/ibmFasobtainedfromReference 2.8,Chapter23Table3A.4.6FilmCoefficient DataForThickSlabsTypew/rtoRoomonSide1,ThetypeofslabwithrespecttotheroomonSide1wasdefinedusingthefollowing codesType1Type2Type"3VerticalWallFloorCeiling
.pi0PgJl1CJe CalcfM-SLD-003 Page11of20h1&h2:Allfilmcoefficients (h)forinsidewallswerecalculated byCOTTAP.Thefilmcoefficient forwallsincontactwithoutsideairwereinputtedas4.0Btu/hr-sq ft>>F6.0Btu/hr-sq ft-F(PerReference 2.8,Chapter23,Table1)Avalueof100Btu/hr-sq ft-Fwasinnuttedforvallsincontactwithground.Thisvaluehelpstosimulateavali(orfloor)incontactwithsoilat55~F.Thiswillresultinaground.conservative prediction oftheheatlosstoss04.7PipeBreakDataFluidPressureMassFlovThefluidpressurewithinthepipe(psia).TheRHRPumpRoomsusedsaturared fluidconditions of14.7psia,whichwasconsidered representative ofnormalReactorconditions duringtheShutdoCoolingmodeofRHR.euownThetotalmassflovexitingthepipebreak(ibm/hr)wasinputt'ed asfollowsfor5gpmwater/steam leak:5gal/minx1cuft/7.48galx60min/hr/.016719cuft/ibm2400ibm/hrvf~Q.Q16719cuft/ibm614.7psiaand212F(perASMESteamTables)for25gpmvater/steam leak:5x2400ibm/hr~120QQibm/hrThebreakoccursatt0.5hrs.Thisallowstheroomtoreachequilibrium conditions priortoinitiation ofthebreak.lnallroommodels,linethebreakmassflovisallowedtoincrarly(ramp)from0ibm/hrtoitsmaximumncreasevalueover0.1hrs.
5.0RESULTS/CONCLUSXONS Calc4M-SLD-003 Page12of20Thefollowing pagesprovidethetemperature profilesresulting fromtheRHRPumpRoommodelsfortheconditions statedbelow:1)5gpmwaterleak(Summer)2)5gpmwater.leak(Winter)3)25gpmwaterleak(Summer)~4)25gpmwaterleak(Winter)TheCOTTAPoutputforeachcaseabovecanbefoundasAttachments 1thru8,respectively.
Eachoutputprovidesasummaryofthedatainput,andtheresultsofeachtimestepwithinthe24hourruntime.AttheendofeachCOTTAPoutput,asummarytableofTempvsTimeinformation, isalsoprovided.
RHRQPROOM(I-13,105)HEATUPEVALUATION (5GPMWATERLEAK/SUMMER) 135130AIIAPUIIPAoostl-)3,103)
IIEA)uPEvaLUAIIOR
)5GPIIrAIEALE4RISusREA) 125(3120115CL$10105)IIIE)IIA)0.0000.Ioo0.200a.3oa0.4000.5000.5500,6000.7000.8000.900I.000I5002.0002.5003.0003.5004.0004.5005.0005.5006.0006.5007.0002.5008.0009.00010.000'II.Ooo12.00013.0001400015.00016.00012.000IS.OOO19.00020.00021.00022.00023.00024.000RoarrI104.00104.04104.05104.06104.06104.0)111.59116.81121.86123.24124.4812487125.71126.19126.55126.8912).IS127.43121.6212).88128.09128.2812845128.62I28.79128.94129.23129.51I29.75129.98130.20130.42130.61130.80130.98131.16131.32131,4813I.64131.79131,94132.08RoollrRoolirkuourRuollrRoollrICRVCRAIURE
)OEGf)RoollrRooli~Aoorr10001015TIME(HRS)20 RHRPUMPROOM(I-13,1O3)HEATUPEVALUATION (5GPMWATERLEAKjWINTER)110100AIIRPUIIPAOOIIEI13~103)IIEA'SUPEVALUA)IONESGPIINA)ERLEAK/WIIIIER)
LL(3bJ90Ld800L!3I-70'IIIIE)IIR)0.000O.1000.2000.3000.4000.5000.5500.6000.7000.600O'.Son1.0001.5002.0002.5003.0003.5004.0004.5005,0005.5006.0006.5002.0002.5006.0009.00010.000II.00012.00013.00014.00015.00016.00017.000IS.00010.00020.00021.00022.00023.00024.000RooilrI66.0066.0065.9965.0965.9966.0076.2463.7101.9005.5496.9397.6)00.2290.03100.32100.)210105,101.38101.60101.96102,21102.43102.62102.66103.IO103.29103.65103.06104.29104.56104.0~105.II105.34105.50105.0I105.92106.23106.43I07.I)102.0'IIo).16107.33AooilrROollrRooilr)EIIPERAIUAE IOEGF)AooiirRooiirAooiirAooarAuoii~60010TIME(HRS)2025 RHRPUMPROOM(I-13,103)HEATUPEVALUATION (25GPMWATERLEAK/SUMMER)
\180160RIIRPUIIPROOIIE)13,103)IIEA)UPEVALUAYIOII (25GPIIUAIERLEAILISUIUIER)
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RHRPUMPROOM(I-13;103)HEATUPEVALUATION (25CPMWATERLEAK/WINTER)
)80160RHRPUIIPROOIIT113,103)HEATUPEVALUATION T25CPII14ATERIEAKIHINTER)
LL140~LLJC5-12030080607IIIETHR)0.0000.1000.2000.3000.4000.5000.550o.eoo0.7000.8000.9001.0001.5002.0002.50173.0UO3.500~0004.50O5.0005.5006.0006.5007.0007.5008.0009.00010.00011.00012.00013.00014.00015.00016.00017.00018.00019.00020.0002100022.00023.00024.000RooilaI66.0066.0065.9965.996S.996S.9910$.43130.1$142.93I~4.9214621146.63147.74147.32150.01151.08151.56151.58152$5'152.8~153.19153.81153.$0154.23154.32154,78155.38154,66157.85156.65157.5415$.00157.41158.72159.44159.65159.5$160.12159.52160.39160.36160.54ROOII~TEUPERATURE TOEGF)ROOII~ROORFROORFROOIIFROOICSROOIIFRooilegg~6'pSod010TIME(HRS)2025 c%C.,
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)OEGF)RooiirROORrRooiirRooiirRoollrRoourRooii~Rooilr9PG'QoS)iSIgrI001015TIME(HRS)2025 RHMPROOM(l-14,104)
HEATUPEVALUATION (5CPMWATERLEAK/WINTER)
$)0300RIIRPUIIPROOII(I14~1041IIEAIUPEVALUATION (5GPIIWA?ERLEAK/WIIIIERl (39080CLLd70600)01IWE(CIRl0.000O.1000.2000.3000.4000.5000.550o'.coo0.?000.8000.900I.000I.5002.0002.5003.0003.5004.0004.5005.0005.5006.0OQs.soo?.ooo?.5008.'OOO9.00010.0001100012.000'13.00014,00015.000Ib.ooo17.00018.0001900020.00021.00022.00023.00024.00015ROOWrI66.0066.00$6.0066.0066.0066.0074.3280.7988.4292.0093.6994.5295.889S.SI97.069?.6?98.0498.3?98.6'I98.9599.2299.4699.6999.91100.'14100.33100.7110'1.06101.3910'I.10102.00102.28102.54102.80,103.04103.28103.51103.13103.94Io~.14104.34104,53RoolirRoolirROOWr20?ERPERAIURE (QEOflROUII~RoowrRQQRrRooiirRoolir25CPIrTIME(HRS)
RHRr'OOM(1-14,104)
HEATUPEVALUAION(25GPMWATERLEAK/SUMMER)
-180160RIIRPUSPROOII(I14~104)HBA)UPBVALUAI)OS(25GPIISAIBRLBAAISUSS(K)4(3140I-QCL4J1207188(IIR)0.0000.1000.2000.3000.4000.5000.5500.6000.7000.8000.900I.OOU1.5002.0002.5003.0003.5004.0004.5005.0005.5006.0006.5007.0007.5008.000Q.ooo10.00011.00012.00013.00014.00015.00016.00017.000IB.0001900020.00021.00022.00023.00024.000Roolle'104.00104.0'I104.01104.0O104.00104.02130.13143.4615175153.83154.')915506156.48157.14158.2915$.99159.45'59.68159.59Ieo.97161.47161.$7161.8616248162.79163.13163.0316416164.63164.9916502165.86166.02166.0'I166.56167.35167.ee167.88168'.le168.3$167.$4168.75Roose76SPERA)UR(
(OEGF)RooseRooseRooseRooseRooseRooseRoose10001015TIME(HRS)20 RHRPUMPROOM(I-14,104)HEATUPEVALUATION (25GPMWATERLEAK/WINTER) 160140RNRPUIIPRooll(I14,104)IIEATUPEVALUATION I25CPIIWATERLEAKININTLR)
(3120CLI-100CL80IIIIEINR)0.0000.1000.2000.3000.4000.5000.5500.6000.7000.8000.9001.000I.5002.0002.5003.0003.5004.000,4.5005.0005.5006.0006.5007.0007.5008.0009.00010.000II.OOO12.00013.00014.00015.00016.00017'.OOO18.00019.00020.0002'1.00022.00023.00021.000ROOllr66.0066.0065.9966.0165.9865.60101.4~122:10135.72137.87140.29140.69112.39143,7114153145.12146,23147,79147.27147.IoI~8.41149,05150.56150.0615014150.49151.56151.90152.07152.89153.48153.80ISA.36151.92156.70155.56155,76155.89156.22156.19157.00157.61RoollrTENPERATURE IOECfIR00NrRoollrRoolirRoollrRoolirRooilrRooll~0rP60010152025roODTIME(HRS)  


RHRPUMPROTIMER(HR)0.0000000.1000000.2000000.3000000.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.00QOOO4.5000005.0000005.5000006.0000006.5000007.0000007.5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.00000Q 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000 OM(I-14,104)
I
HEATUPEVALUATION (50GPMWATERLEAK/WINTER)
=y
TEMPERATURE (ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;,ROOM&#xb9;OOM&#xb9;166.,0065.9965.9966.0065.9965.87125.31146.15154.12155.46155.&0156.62158.91160.49161.47161.78163.46163.83165.12165.26165.78166.32167.01166.52167.65167.98168.71170.23170.11170.48170.31171.26172.04171.93172.80173.06173.23173.26173.34174.18174.69174.94SUMMARYOFMAXIMUMCOMPARTMENT TEMPERATURES ANDTIMEOFOCCURRENCE ROOM&#xb9;MAXTIMEOFTEMP(F)OCCURRENCE (HR)1174.9424.0000RHRPUMPROOM(I-14g104)
,1
HEATUPEVALUATION (50GPMWATERLEAK/WINTER)
PRESSURE(PTIMEROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM e(HR)0.0000000.1000000.2000000.3000000.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.0000004.5000005.0000005.5000006.0000006.5000007.0000007.5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.000000 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000
-114.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.717000 14.704000 14.701000 14.700000 14.700000
~14.700000 14.701000 14.699000 14.700000 14.699000 14.700000 14.700000 14.699000 14.700000 14.700000 14.700000 14.700000 14.699000 14.700000 14.700000 14.700000 14.699000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.699000 14.700000 14.701000 14.701000 14.700000 14.700000 14.700000 14.700000 SUMMARYOFMAXIMUMCOMPARTMENT PRESSURES ANDTIMEOFOCCURRENCE ROOMSMAXTIMEOFPRES(PSIA)OCCURRENCE (HR)1RHRPUMPTIME(HR)0.0000.10014.7170.55ROOM(I14rl04)HEATUPEVALUATION (50GPMWATERLEAKtWINTER)
RELATIVEHUMROOMSROOMgROOMgROOMgROOMgROOMgROOMgROO10.1000.099 0.2000.3000.4000.5000.5500.6000.7000.8000.9001.0001.5002.0002.5003.000'.5004.0004.5005.0005.5006.0006.5007.0007.5008.0009.000-10.00011.00012.00013.00014.00015.00016.00017.00018.00019.00020.00021.00022.00023.00024.0000.0970.0960.0950.0940.0150.0090.0070.0070.0070.0060.0060.0060.0050.0050.0050.0050.0050.0050.0050.0050.0050.0050.0050.0040.0040.0040.0040.0040.0040.0040.0040.0040.0040.0040.0040.0040.0040.0,040.0040.004SUMMARYOFMAXIMUMCOMPARTMENT RELATIUEHUMIDITYANDTIMEOFOCCURRENCE ROOM4MAXTIMEOFHUMIDITYOCCURRENCE (HR)0.100.00 RHRPUMPROOM(I-13TIMEROOM&#xb9;R(HR)10.00000066.000.10000065.950.20COOO65.950.30000065.940.40000065.890.50000066.000.550000134.540.600000153.870.700000160.700.800000161.510.900000162.011.000000162.881.500000164.662.000000165.912.500000166.973.000000167.953.500000168.174.000000169.324.500000169.455.000000169.985.500000170.506.000000170.846.500000171.257.000000171.697.500000172.328.000000172.439.000000174.1010.000000 173.4711.000000 174.0712.000000 173.9013.000000 174.5714.000000 175.2015.000000 175.3716.000000 175.9817.000000.
176.0518.000000 176.5219.000000 176.7420.000000 177.0521.000000 177.1022.000000 177.3223.000000 177.9424.000000 179.47,103)HEATUPEVALUATION (50GPMWATERLEAK/WINTER)
TEMPERATURE (OOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;SUMMARYOFMAXIMUMCOMPARTMENT TEMPERATURES ANDTIMEOFOCCURRENCE ROOM&#xb9;MAXTIMEOFTEMP(F)OCCURRENCE (HR)1178.4724.0000RHRPUMPROOM(I-13,103)
HEATUPEVALUATION (50GPMWATERLEAK/WINTER)
PRESSURE(PTIMEROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM (HR)0.0000000.1000000.2000000.3000000.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.0000004.5000005.0000005.5000006.0000006.5000007.0000007.5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.000000 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000 114.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.711000 14.706000 14.700000 14.700000 14.700000 14.701000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.701000 14.700000 14.700000 14.699000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.701000 14.700000 14.699000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 SUMMARYOFMAXIMUMCOMPARTMENT PRESSURES ANDTIMEOFOCCURRENCE ROOMSMAXTIMEOFPRES(PSIA)OCCURRENCE (HR)OMg1RHRPUMPTIME(HR)0.0000.10014.7110.55ROOM(I-13,103)
HEATUPEVALUATION (50GPMWATERLEAK/WINTER)
RELATIVEHUMROOMSROOMSROOMSROOMgROOMgROOMSROOM4ROO10.1000.098 0.2000.3000.4000.5000.5500.6000.7000.8000.9001.0001.5002.0002.5003.aoa3.5004.0004.5005.0005.5006.0006.5007.0007.5QQ8.0009.00010.00011.000=12.00013.00014.00015.00016.00017.00018.00019.00020.00021.00022.00023.00024.0000.0960.0940.0920.0910.0110.0070.0060.0060.0050.0050.0050.0050.005Q.0040.0040.0040.0040.0040.0040.0040.0040.004o.oa40.0040.0040.0040.0040.0040.0040.0040.004o.oa40.0040.0040.0040.0040.004,0.,0040.0040.004SUMMARYOFMAXIMUMCOMPARTMENT RELATIVEHUMIDITYANDTIMEOFOCCURRENCE ROOMN'AXTIMEOFHUMIDITYOCCURRENCE (HR)0.100.00
'M&#xb9;RHRPUMPROOM(I-13,103)TIMEROOM&#xb9;ROOMa(HR)10.000000104.000.100000103.750.20DOOO103.650.300000103.560.400DDO103.600.500000103.570.550000150.530.600000159.520.700000161.800.800000163.180.900000162.821.000000164.711.50DOOO167.092.000000167.722.500DOO169.503.000000170.383.5000DD171.364.000000172.064.500000171.885.000000173.325.500000173.9i6.000000174.126.500000172.937.000000174.407.500000175.748.000000176.049.000000176.2010.000000 178.4011.000000 177.9912.000000 178.3613.000000 178.5514.000000 179.5515.000000
'180.0416.000000 180.'1817.000000 180.7918.000000 180.8319.000000 181.3720.000000 180.9521.000000 182.2122.000000 182.4823.000000 182.4324.000000 182.6350HEATUPEVALUATION
(&GPMWATERLEAK/SUMMER)
TEMPERATURE (OEGF)R00MsRODM>>RDDM&#xb9;RDDM&#xb9;R00M>>RDDMaR00M>>RDDM>>RDDM&#xb9;RDDM>>ROOM&#xb9;RDOM>>OOM>>SUMMARYOFMAXIMUMCOMPARTMENT TEMPERATURES ANDTIMEOFOCCURRENCE ROOM>>MAXTIMEOFTEMP(F)OCCURRENCE (HR)'1182.6324.0000RHRPUMPROOM(I-13.103)HEATUPEVALUATION (25GPMWATERLEAK/SUMMER)
PRESSURE(PSIA)TIMEROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM>ROOM&#xb9;ROOM&#xb9;ROOM>ROOM&#xb9;ROOM>ROOM>ROOM>>ROOM&#xb9;ROOM>>
(HR)0.0000000.1000000.2000000.3000000.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.0000004.5000005.0000005.5000006.0000006.5000007.000000..5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.000000 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000 114.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.706000
'14.702000 14.70100014.700000 14.697000 14.700000 14.700000 14'0100014.700000 14.700000 14.700000 14.700000 14.700000 14,700000 14.700000 14.699000 14.699000 l4.69900(
>4.70000~
14.700000 14.70'l000 14.696000 14.699000 14.700000 14.701000'14.700000 14.700000 14.70100014.700000 14.700000 14.700000 14.699000 14.700000 14.700000 14.700000 14.699000 SUMMARYOFMAXIMUMROOMSMAXPRES(PSIA)COMPARTMENT PRESSURES ANDTIMEOFOCCURRENCE TIMEOFOCCURRENCE (HR)ROOM@1RHRPUMPTIME(HR)0.0000.10014.7060.55ROOM(I-13,103)HEATUPEVALUATION (25GPMWATERLEAK/SUMMER)
RELATIVEHUMIDITYROOMcROOMPROOM/ROOMNROOMA'OOMt ROOMiROOMiROOMSROOMPROOMPROOMSROOMNROOMN10.3800.383


0.2000.3000.4000.5000.5500.6000.7000.8000.9001.000'1.5002.0002.5003.0003.5004.00O4.500S.OOO5.5006.0006.5007.0007.5008.0009.OOr.'10.Ooi11.00C12.00013.00014.00015.00016.00017.00018.00019.00020.00021.00022.00023.00024.0000.3840.3840.3840.3840.1080.0870.0820.0790.0800.0760.0720.0710.06e0.06>0.0660.0640.0650.0630.0620.0620.0630.0610.0590.0590.0590.05:.0.0560.0560.0560.0540.0540.0540.0530.0530.0520.0530.0510.051'.0510.051SUMMARYOFMAXIMUMCOMPARTMENT RELATIVEHUMIDITYANDTIMEOFOCCURRENCE ROOMNMAXTIMEOF.HUMIDITYOCCURRENCE (HR)0.380.50 OM>>RHRPUMPROOM(I14OQM>>R1104.00103.79103.68103.64103.71103.82143.49153.57'157.56158.43'I58.85159.65161.95163.38164.92166.07166.67167.62168.48'168.97169.73170.6"170.71177.56171.79172.30172.90173.82174.12175.45175.56176.20.176.63177.43177.46178.22178.25178.77179.07179.4'I179.76179.96TIMER(HR)0.0000000.1000000.2000000.3000000.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.0000004.5000005.0000005.5000006.oooooe6.5000007.0000007.5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.000000 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000
Calc      4  M-SLD-003 Page 2        of 20 TABLE OF CONTENTS 1 .0 PURPOSE          ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~      ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~  3 2 ~ 0 RE FERENCES    ~ ~ ~ ~ ~ ~ ~ ~ ~  , ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~  ~ ~ ~ ~ ~ ~ ~ ~ ~ ~  4 3.0   ASSUMPTIONS    ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~      5 4 '   METHODOLOGY    ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~      6 5 ~ 0 RESULTS/CONCLUSIONS              ...................................                                     12 ATTACHMENT 1      COTTAP Output                for    RHR Pump Room                  (I-13/I-103) 5 GPM Leak (Summer)
,104)HEATUPEVALUATION (WGPMWATERLEAK/SUMMER)
ATTACHMENT 2      COTTAP Output                for    RHR Pump Room                  (I-13/I-103) 5 GPM Leak (Winter)
TEMPERATURE (OEGF)OOM>>ROOM>>ROOM&#xb9;ROOM>>ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM>>ROOM>>ROOM>>ROOM>>ROOMtROOM>>SUMMARYOFMAXIMUMROOM>>MAXTEMP(F)COMPARTMENT TEMPERATURES ANDTIMEOFOCCURRENCE TIMEOFOCCURRENCE (HR)OQM>>1179.9624.0000RHR'UMPROOM(I-14,104)
ATTACHMENT 3      COTTAP      Output          for    RHR Pump Room                  (I-13/I-103) 25 GPM Leak (Summer)
HEATUPEVALUATION (25GPMWATERLEAK/SUMMER)
COTTAP      Output for RHR                    Pump Room            (I-13/I-103) 25 GPM Leak              (Winter)
PRESSURE(PSIA)TIMEROOM&#xb9;ROOMtRQQM&#xb9;ROOM>>ROOM>>ROOM>>ROQM>>ROQM>>ROOM&#xb9;ROOM>>ROOM>>ROOM>>ROOMtROOMt (HR)'0.00000014.700000 0.10000014.7010000.20000014.700000 0.30000014.700000 0.40000014.700000 0.50000014.700000 0.550000'14.708000 0.60000014.702000 0.70000014.701000 0.80000014.701000 0.900000'14.700000 1:00000014.700000
ATTACHMENT 5      COTTAP      Output for RHR                    Pump Room            (I-14/I-104) 5 GPM Leak (Summer)
-1.500000 14.700000 2.00000014.700000 2.50000014.700000 3.00000014.700000 3.50000014.700000 4.00000014.700000 4.50000014.700000 5.00000014.701000 5.50000014.700000 6.00000014.701000
ATTACHMENT 6     COTTAP Output                for    RHR Pump Room                  (I-14/I-104) 5 GPM Leak (Winter)
-6.50000014.700000 7.00000014.69700C 7.50000014.70000C 8.00000014.700000 9.000000'14.699000 10.000000 14.700000 11.000000 14.700000 12.000000 14.699000 13.000000 14.700000 14.000000 14.700000 15.000000 14.700000 16.000000 14.699000 17.000000 14.700000 18.000000 14.700000 19.000000 14.700000 20.000000 14.700000 21.000000 14.699000 22.000000 14.700000 23.000000 14.700000 24.000000 14.700000 SUMMARYOFMAXIMUMROOMPMAXPRES(PSIA)COMPARTMENT PRESSURES ANDTIMEOFOCCURRENCE TIMEOFOCCURRENCE (HR)ROOM@114.7080.55RHRPUMPROOM(I-14,104)HEATUPEVALUATION (25GPMWATERLEAK/SUMMER)
ATTACHMENT 7      COTTAP      Output          for    RHR Pump Room                  (I-14/I-104) 25 GPM Leak (Summer)
RELATIVEHUMIDITYTIMEROOMiROOMSROOMSROOMPROOMSROOMSROOMS'OOM>>
ATTACHMENT 8      COTTAP      Output for RHR                    Pump Room            (Z-14/I-104) 25 GPM Leak              (Winter)
ROOM4ROOMPROOMPROOMiROOMiROOMi(HR)10.0000.3800.1000.382 0.2000.3000.4000.5000.5500.6000.7000;8000.9001.0001.5002.0002.5003.0003.5004.0004.5005.0005.5006.0006.5007.0007.5008.OOO9.00010.00(11.OOC-12.00013.00014.00015.00016.00017.00018.00019.00020.00021.00022.00023.00024.0000.3830.3840.3830.3820.1290.1000.0910.0890.0860.0860.08"0.0790.0760.0740.0730.0710.0700.0690.0680.0670.0670.0570.065O.O64G.06.C.06.0.06"0.0600.0600.059O.OSe0.0570.0570.0560.0560.0550.055,0.0550.0540.054SUMMARYOFMAXIMUMCOMPARTMENT RELATIVEHUMIDITYANDTIMEOFOCCURRENCE ROOMJI'AX TIMEOFHUMIDITYOCCURRENCE (HR)0.380.30
APPENDIX A        Data Input Section  RHR Pump                                  Room      (I-13/I-103)
APPENDIX B        Data Input Section << RHR'ump                                  Room      (I-14/I-104)


OM>>RHRPUMPROOM(I14m104)ROOM>>TIMEROOM>>(HR)10;00000066.000.10000065.990.20000065.990.30000066.000.40000065.99o.soooooss'.860.550000159.710.600000173.800.700000176.500.800000177.300.900000'77.75 1.000000178.261.500000179.502.000000181.082.500000l81.783.000000182.493.500000182.474.000000183.244.500000184.285.000000184.6&5.500000185.336.000000185.716.500000185.397.000000186.017.500000186.'138.000000186.669.000000187.1910.000000 187.8011.000000 187.8212.000000 188.2513.000000 188.0814.000000 188.8615.000000 189.50'6.000000
Calc  0 M-SLD-003 Page 3  of 20
'I89.7317.000000 190.0418.000000 190.2819.000000
,1.0 PURPOSE The purpose of this calculation is to predict the room temperature profile expected when a small water leak is introduced in the Unit 1 RHR Pump Rooms. The results of this calculation will be used as a basis for development of Steam Leak Detection System setpoints.
'190.0120.000000 190.6821.000000 190.6622.000000 190.6523.000000 19'1.6324.000000 191.30HEATUPEVALUATION (100GPM'WATERLEAK/WINTER)
 
ROOM>>ROOM/ROOM>>ROOM>>ROOM>>RTEMPERATURE (OEGF)>>ROOM>>ROOMsROOM>>ROOM>>ROOM>>ROOM>>ROOM>>OOM>>ROOMSUMMARYOFMAXIMUMPOMPA>>MAXTIMEOFRTMENTTEMPERATURES ANOTIMEOFOCCURRENCE TEMP(F)OCCURRENCE (HR)1191.6323.0000RHRPUMPROOM(I-14104H)EATUPEVAI.UATION (100GPMWATERLEAK/WINTER)
Calc  4  M-SLD-001 Page 4    of 20 2  '    REFERENCES 2~1        Calc  4  M-RAF-024, Rev. 0 "RB Post DBA Transient Temperature Analysis" 2.2    'echtel      Calc  g 176-18, Rev. 5 "RB Cooling Modes" 2.3        SEA-EE-129, Rev. 0 "SSES  Unit 1 and Unit 2 Reactor Building Heat Loads" 2~4  ~
TIMEROOM>>ROOMSROOM>>ROOM>>RoPRESSURE(PSIA)ROOM>>ROOM>>ROOM/ROOM>>ROOM>>ROOMOROOM>>ROOM>>ROOM>>ROOMP
Dravings                                                I P&ID M-176, Rev. 20 P&ID M-151 Sht 3, Rev. 2 P&ID M-151 Sht 4, Rev. 1 V-29-1,  Rev. 9 V-29-2,  Rev. 12 V-29-3,  Rev. 11 V-28-1,  Rev. 15 V-28-2,  Rev. 14 V-28-3,  Rev. 17 C-105, Rev. 20 C-106, Rev. 16 C-134, Rev. 15 C-135, Rev. 16 C-156, Rev. 12 C-157, Rev. 13 C-111, Rev. 15 C-117, Rev. 17 HBB-111-1, Rev. 6 HBB-111-2, Rev. 4 HBB-110-1, Rev. 9 GBB-104-1, Rev. 7 GBB-104-2, Rev. 4 GBB-105-1, Rev. 6 GBB-116-1, Rev. 6 GBB-106-1, Rev. 8 2 '        M-199  Piping Class Sheets 2.6        SEIS Pipeline General Index 2'        Crane Technical Paper No. 410, 23rd Printing 2 8        ASHRAE 1985    Fundamentals  Handbook 2.9        FSAR  Table 3.11-6 2 ~ 10    FSAR  Section 5.2.5.1.3 2 ~  11    Calc g M-PAF-001, Rev. 1 "HVAC Environmental Analysis-Reactor Buildings & Control Structure"                            I 2 '2      COTTAP-2 Theory and Input Description Manual (User's Manual),
;Ppf~rP<'1l,Cl' (HR)0.0000000.1000000.2000000.3000000.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.0000004.5000005.0000005.5000006.0000006.5000007.0000007.5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.000000 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000 114.700000 14.700000 14.700000 14.700000
Rev. 1, dated 1/27/89.
'I4.700000 14.700000 14.716000,14.703000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.699000
 
'I4.700000 14.700000 14.700000 14.700000
lp ~
'14.700000 14.698000 14.70100014.700000 14.699000 14.700000 14.700000 14.700000 14.700000 14.699000 14.699000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.696000 14.700000 SUMMARYOFMAXIMUMROOMOMAXPRES(PSIA)COMPARTMENT PRESSURES ANDTIMEOFOCCURRENCE TIMEOFOCCURRENCE (HR)ROOM$114.7160.55RHRPUMPROOM(I-14,104)HEATUPEVALUATION (100GPMWATERLEAK/WINTER)
lt 0
RELATIVEHUMIDITYTIMEROOMSROOMl'OOMS ROOMSROOMsROOMsROOMiROOMiROOMS(HR)10.0000.1000.1000.099ROOMSROOMtROOMiROOM/ROOMI 0.2000'000.4000.5000.5500.6000.7000.8000.9001.0001.5002.0002.5003.0003.5004.0004.5005.0005.5006.0006.5007.0007.5008.0009.00010.00011.00012.00013.00014.000.15.00016.00017.000'18.000'19.00020.00021.00022.00023.00024.0000.0970.0960.0950.0940.0060.0040.0040.0040.0040.0040.0040.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.003SUMMARYOFMAXIMUMCOMPARTMENT RELATIVEHUMIDITYANDTIMEOFOCCURRENCE ROOMSMAXTIMEOFHUMIDITYOCCURRENCE (HR)0.100.00 OMtRHRPUMPROOM(I-13,103)HEATUPEVALUATION (100GPMWATERLEAK/WINTER)
)h l
TEMPERATURE (OEGF)OOM>>ROOMtROOMtROOM>>ROOM>>ROOM&#xb9;ROOM>>ROOM>>TIMEROOM>>R(HR)10.00000066.000.100000-65.950.20000065.950.30000065.940.40000065.890.50000066.000.550000"'69'10.600000'179.830.700000'181.560.800000182.080.900000182.301.000000183.131.500000184.242.000000184.652.500000185.543.000000186.203.500000186.99'.000000187.214.500000187.405.000000187.865.500000188.336.000000189.476.500000189.007.000000188.977.500000188.708.000000189.579.000000190.1110.000000 190.3211.000000 190.7112.000000 190.64'13.000000 191.0914.000000 191~9815.000000 191.3916.000000 192.0417.000000 192.4118.000000
'J 1
'192.4519.000000 192.66'0.000000 192.7921.000000 193.0522.000000 192.9923.000000 193.1024.000000
P
'192.96ROOM&#xb9;ROOM$ROOM>>ROOM>>ROOMtOOM>>SUMMARYOFMAXIMUMCOMPARTMENT TEMPERATURES ANDTIMEOF,OCCURRENCE ROOM>>MAXTIMEOFTEMP(F)OCCURRENCE (HR)1193.1023.0000RHRPUMPROOM(I-13,103)HEATUPEVALUATION (100GPMWATERLEAK/WINTER)
 
PRESSURE(PSIA)TIMEROOM>>ROOM>>ROOM&#xb9;ROOMtROOM>>ROOM>>ROOM>>ROOMsROOM>>ROOM&#xb9;ROOM>>ROOM>>ROOMtROOM>>
Calc g  M-SLD-003 Page 5  of 20 3 ' ASSUMPTIONS
(HR)0.0000000.1000000.2000000.,300000 0.4000000.5000000.5500000.6000000.7000000.8000000.9000001.0000001.5000002.0000002.5000003.0000003.5000004.0000004.5000005.0000005.5000006.0000006.5000007.0000007.5000008.0000009.00000010.000000 11.000000 12.000000 13.000000 14.000000 15.000000 16.000000 17.000000 18.000000 19.000000 20.000000 21.000000 22.000000 23.000000 24.000000 114.700000 14.700000 I4.700000 14.700000 14.700000 14.700000 14.71000014.700000 14.700000 14.700000 14.70100014.70100014.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.70100014.700000 14.700000 14.699000 I4.699000 14.700000 14.700000 14.700000 14.700000 14.700000 14.697000
: 1)  Plant is operating under normal conditions prior to introducing a steam/water leak.
'I4.70100014'0000014.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 14.700000 SUMMARYOFMAXIMUMROOM&#xb9;MAXPRES(PSIA)COMPARTMENT PRESSURES ANDTIMEOFOCCURRENCE TIMEOFOCCURRENCE (HR)ROOM&#xb9;114.7100.55RHRPUMPROOM(I-13,103)HEATUPEVALUATION (100GPMWATERLEAK/WINTER)
: 2)  All adjacent rooms will be maintained at their design maximum temperature for summer conditions and at the average temperature for the, month of. January (if blue-box data is available) for winter conditions. Where winter temperature data is not available, the design minimum temperature of 60~F will be used.
TIME(HR)0.0000.100RELATIVEHUMIDITYROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOMsROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM&#xb9;ROOM/ROOM&#xb9;ROOM&#xb9;ROOM&#xb9; 0.2000.3000.4000.5000.5500.6000.7000.8000.9001.0001.5002.0002.5003.0003.5004.0004.5005.0005.5006.0006.5007.0007.5008.0009.00010.00011.00012.00013.00014.00015.00016.00017.00018.00019.00020.00021.00022.00023.00024.0000.0960.0940.0920.0910.0050.0040.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030.0030'030.003SUMMARYOFMAXIMUMCOMPARTMENT RELATIVEHUMIDITYANDTIMEOFOCCURRENCE ROOMSMAXTIMEOFHUMIDITYOCCURRENCE (HR)0.100.00 0*J0,I}}
: 3) The room under consideration will not be allowed to pressurize, as the blowout panel will relieve at approximately 0.5 psid. Therefore, a leakage path out of the room will be used to maintain pressure as close to 14.7 psia as possible. The temperature effects due to slight room pressurization are assumed to be negligeble.
: 4) The effects of adjacent room heatup are not considered in this analysis (i.e. adjacent room temperatures are held constant). This results in a conservative temperature profile for the room under consideration. The actual adjacent room heatup due to the water leak is expected to be minimal (when considering conductive heat losses).
: 5) The COTTAP model assumes perfect mixing of the air and water/
steam in the room under consideration.
The original 'Bechtel Calc 4 176-23 used the Steam Condensing Mode of RHR as the basis for the steam leak to the RHR Pump rooms. In previous outages, this mode of RHR was removed.
The high energy piping (steam line from HPCI) associated with this mode of operation no longer exists in the RHR Pump rooms. Therefore, this calculation will use the Shutdown Cooling (SDC) mode of RHR as the basis for the water/steam leak in the  RHR Pump  rooms.
The SDC mode initiates on the 98 psig (RX Pressure) permissive. At 98 psig, the lines are warmed by procedure for approximately 2 hours before SDC mode actually starts.
During this time, the RX is being cooled down at, a maximum allowed rate of 90~F/hr.        conservatism, this calculation will use saturated water atFor14.7 psia and 212 F as the starting conditions for the leak. These conditions approximate the minimum requiiements which define high energy piping. RHR SDC is considered high energy piping for a very short period of time (i.e. < 14 of the time).
 
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Calc  g M-SLD-003 Page 6  of 20 4.0 METHODOLOGY The Compartment Transient Temperature      Analysis Program  (COTTAP) was used to analyze the affects of a    steam/water leak in various rooms within the plant. The program predicted temperature profiles for the room under consideration with the following set of conditions
: 1) 5 gpm water leak (Summer)
: 2) 5 gpm water leak (Winter)
: 3) 25 gpm water leak (Summer)
: 4) 25 gpm water leak (Winter)
The  individual room models were developed from various sources of information, as identified in Section 2.0 References. The results will consist of the COTTAP output and the plots of various profiles for the conditions stated above. The following discussion is provided to outline the steps used in developing the individual room models.
4.1 General Data For  Rooms Room Volumes      The room volume was taken from Reference 2.1 for the room under consideration. Adjacent room volumes were set to a large value (i.e.
1.0 EE15 cu. ft.) to maintain constant properties such as temperature, pressure      and relative humidity.
Initial Pressure          All rooms  were assumed  to  be  at an  initial pressure of 14.7 psia.
Initial Temperature      All rooms  were assumed to be at their maximum normal design temperature initially for summer conditions. Actual winter data was used, where available,   as a starting point for the winter runs. The  winter data  was taken as the "blue-box" average temperature for January 1988.
The January data was considered to be more conservative than February data. Where actual winter data was not available, the design minimum room temperature of 60' was used.
Where winter data was not available for the room in question, the room was started at a temperature which allows    it state with its adjacent rooms.
to reach a steady-
 
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Calc 0  M-SLD-003 Page 7  of 20 The  outside ambient temperature  was taken (summer) and 264F (winter). The summer as'9~F ambient was taken from Reference 2.8 as the 24 hour daily average temperature, based upon the 14 ASHRAE design value,, for the Wilkes-Barre/
Scranton area. The winter value was taken as the actual monthly average for January over the years 1986 thru 1989. This average was based upon SSES Meteorological Data taken from the plant computer. A comparison of February data over this same time period indicated that the January data was more conservative.
Relative Humidity          The  relative humidity for all rooms connected by  ventilation or leakage paths is based upon outside air temperatures of 92 F DB / 78 F WB (summer) and -5 F DB / -5~F WB (winter). Air at these "conditions was then allowed to heat up or cool down (sensible heating/cooling only) to the initial room temperature, and the corresponding RH value calculated or read from the psychrometric chart.
Room Height      This value is no longer used by COTTAP.
original purpose was associated with the wall It' condensation calculation used within COTTAP.
COTTAP has been revised and no longer uses this information. Therefore, a value of 10.0 inputted for each room. This value has no ft      was significance to the calculation. Note that the actual room height was used in the calculation of  room volume.
4.2 Airflow and Leakage Path Data Airflow Data    The design airflow is provided for the room under consideration. All flow paths are identified (i.e. supply, exhaust and transfer air). The source of the airflow data is the P&ID associated with the particular ventilation system for that room. The data identifies the room from which the air comes, and the room to which the air goes.
Since air flows are balanced to g 104 accuracy, a conservative value of 1760 scfm was used for room I-13/I-103 (1600 scfm x 1.1). A value of 1210 scfm was used for room I-14/I-104 (1100 scfm x 1.1).
 
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Calc 4  M-SLD-003 Page 8  of 20 Leakage Path Data        As  with the airflow data, all rooms connected to the leakage path are identified. The leakage path area is only used to scale the leakage 'flowrates for the entire compartment under consideration. The intent of the leakage path is to prevent compartment pressurization.
For most rooms (except RWCU), only one leakage path is used, aqd a value of 1.0 sq. ft. is inputted for the leakage path area. When. more than one leakage path'xists, actual leakage areas can be inputted to better understand leakage flows between adjacent compartments.
4.3 Heat Load Data Heat Load Type            The  type of heat load was identified using the followzng nomenclature Type            Description 1              Lighting 2              Electrical  Panels 3              Motors 4              Unit Coolers 5              Piping 8              Misc. Mechanical Equipment Heat Input Rate            The heat    rate input in Btu/hr for the associated heat load.
The values for heat load types 1 thru 3 were obtained from References 2.2 & 2.3. The heat rate inputs for type 4 heat loads are inputted as negative values since the unit coolers remove heat from the room. The heat input rate for type 5 heat loads were 'input as -1. This value directs COTTAP to obtain piping
                  'information necessary to calculate the piping heat loads. The heat input rate for type 8 heat loads was obtained from References 2.2 &
2.3, as necessary for the appropriate room.
To achieve an initial steady-state condition, a miscellaneous heat'load (positive or negative) was added to the main room to balance all other time zero heat loads. This heat load was inputted as type 8.
 
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Calc  4 M-SLD-003 Page 9  of 20 Note that COTTAP neglects cold pipe and equipment as heat sinks. This represents non-conservatism in this calculation. A sample run made  to determine the effects of these heat sinks indicated that resultant temperatures were only slightly lower than the values predicted when neglectinq these heat sinks.
Therefore, this calculation assumes the effects of these heat sinks are negligable.
For walls and floors in contact with ground, the model predicts a conservative value of heat loss to ground. The slabs are assumed to be in contact with soil at a temperature of 55 F. To model the heat loss to ground, a large value of surface film convective heat transfer coefficient'(100 Btu/hr-sq ft- F) has been introduced on the ground side of the floors and walls to achieve a ground contact temperature of 55~F.
4.4 Piping Input Data Only piping with a design. temperature greater than that of the normal room design temperature was included, since COTTAP ignores cold pipe as a heat sink. This generally meant that piping at or close to Reactor conditions was included. Also note that this calculation neglects heat loss from small pipe (i.e. less than 2" OD).
Pipe OD          The outside diameter of the pipe was obtained from Reference 2.4 Pipe ID          The pipe schedule was obtained from Reference 2.5 . Knowing the schedule, the inside diameter was obtained from Reference 2.7 Insulation The insulation  OD was  obtained from Reference OD'ipe            F 11 Length    The  pipe length  was  obtained from Reference 2.4 obtained from Reference Emmisivity
                        '1 emmisivity was The 2
Insulation k Value          The  insulation thermal conductivity (k) was obtained from Reference 2.11 .
Pipe Fluid Temperature  :  The design  fluid temperature  was  obtained from Reference 2.6
 
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Calc &#xb9; M-SLD-003 Page 10  of  20 Fluid  Phase    The  state of the fluid was determined by reviewing the system P&ID's and design temperatures/pressures.
                    -could carry steam or water, If it a particular line was assumed to be liquid for conservatism.
4.5 General Data For Thick Slabs Room ID &#xb9; The room number on one side of the slab.
on Side 1 Room  ID &#xb9; on Side 2        The room number on    the other side of the slab.
When  slab is adjacent to ground, a room &#xb9; of "0" is used.
Thickness      The thickness of the slab was obtained from Reference 2.4 Heat Transfer Area            The area of the slab was obtained from Reference 2.4 . The dimensions were scaled from plant ventilation drawings. The slab areas are calculated in the Data Input Section (Refer to Appendix A).
Thermal Conductivity  : The thermal    conductivity of the concrete slabs were obtained from Reference 2.8        , Chapter 23 Table 3A.      A value of 1.0 Btu/hr sq-ft F was used  for all concrete slabs.
Density        The density of be 140 ibm/cu all This ft. concrete slabs is assumed to value was obtained from Reference 2.8    ,  Chapter 23 Table 3A.
Specific Heat            The specific heat for      all  concrete slabs was assumed to be 0.22 Btu/ibm F as obtained from Reference 2.8 , Chapter 23 Table 3A.
4.6 Film Coefficient Data For Thick Slabs Type  w/r to Room on Side 1,        The type of slab with respect        to the room on Side 1 was defined using the        following codes Type 1        Vertical Wall Type 2        Floor Type" 3        Ceiling
 
    .pi 0
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Calc  f M-SLD-003 Page 11 of 20 h1  & h2    :  All film coefficients      (h) for inside walls were calculated by COTTAP. The film coefficient for walls in contact with outside air were inputted as 4.0    Btu/hr-sq ft>>    F 6.0    Btu/hr-sq ft-    F (Per Reference 2.8    ,  Chapter 23, Table 1)
A  value of 100 Btu/hr-sq      ft- F  was  innutted for valls in contact with ground. This value helps to simulate a vali (or floor) in contact with soil at 55~F. This will result in a conservative prediction of the heat loss ground.
oss  t0 4.7 Pipe Break Data Fluid Pressure        The  fluid pressure within the pipe (psia). The RHR Pump Rooms  used saturared fluid conditions of 14.7 psia, which was considered representative of normal Reactor conditions during thee Shutdo    u own Cooling mode of RHR.
Mass  Flov      The total mass flov exiting the pipe break (ibm/hr)  was inputt'ed as follows for 5 gpm water/steam leak :
5 gal/min x 1 cu ft/7.48 gal x 60 min/hr
                    .016719 cu ft/ibm 2400 ibm/hr
                                                                      /
vf ~ Q.Q16719 cu ft/ibm 6 14.7 psia and 212 F (per ASME Steam Tables) for 25 gpm vater/steam leak :
5 x 2400 ibm/hr ~ 120QQ ibm/hr The break occurs at      t  0.5 hrs. This allows the room to reach equilibrium conditions prior to initiation of the break. ln all room models, the break mass flov is allowed to incr    ncrease line arly (ramp) from 0 ibm/hr to its maximum value over 0.1 hrs.
 
Calc 4 M-SLD-003 Page 12  of 20 5.0  RESULTS/CONCLUSXONS The  following pages provide the temperature profiles resulting from the  RHR Pump Room models for the conditions stated below:
: 1) 5 gpm  water  leak (Summer)
: 2) 5 gpm  water .leak (Winter)
: 3) 25 gpm  water  leak (Summer)
  ~
: 4) 25 gpm  water leak (Winter)
The COTTAP output for each case above can be found as Attachments 1 thru 8, respectively. Each output provides a summary of the data input, and the results of each time step within the 24 hour run time. At the end of each COTTAP output, a summary table of Temp vs Time information, is also provided.
 
RHR    QP ROOM (I13,105) HEATUP EVALUATION (5 GPM WATER LEAK/SUMMER) 135 130 AIIA PUIIP Aoos      tl-)3,103)  IIEA)uP EvaLUAIIOR )5 GPII rAIEA LE4RISusREA) 125                                    ) IIIE  R oar r      Roollr  Roolir  kuour  Ruollr  Roollr ICRVCRAIURE )OEG Roollr  Rooli ~
f)
Aoorr
                                            )IIA)      I (3                                        0.000
: 0. Ioo 0.200 104.00 104.04 104.05 a.3oa    104.06 0.400    104. 06 0.500    104. 0) 0.550  111.59 120                                    0,600 0.700 116.81 121.86 0.800    123.24 0.900    124. 48 I . 000  124 87 I 500    125. 71 2.000  126. 19 2.500    126.55 3.000    126.89 3.500    12). IS 115                                    4.000    127.43 4.500    121.62 5.000    12).88 5.500    128.09 6.000    128. 28 CL                                        6.500    128 45 7.000   128.62 2.500    I28.79 8.000    128.94 9.000   129.23
    $ 10                                10.000
                                        'I I .Ooo 129.51 I29.75 12.000      129.98 13.000      130. 20 14 000      130. 42
: 15. 000    130.61 16.000    130.80 12.000      130.98 IS.OOO      131.16 19.000      131.32 105                                  20.000 21.000 131,48 13 I . 64 22.000    131.79 23.000      131,94 24.000      132. 08 100 0                    10                  15                          20 TIME (HRS)
 
RHR PUMP ROOM (I13,1O3) HEATUP EVALUATION (5 GPM WATER LEAKjWINTER) 110 100 AIIR PUIIP AOOII      E I 13 ~ 103) IIEA'SUP EVALUA)ION ES GPII NA)ER LEAK/WIIIIER)
                                      'I I IIE                                                            )EIIPERAIUAE IOEG F)
Rooilr    Aooilr    ROollr  Rooilr  Aooiir  Rooiir  Aooiir    Aooar  Auoii~
LL                                  )IIR)        I 0.000      66. 00 O. 100      66. 00 (3                                  0.200 0.300 65.99 65.09 bJ                                  0.400 0.500 65.99 66.00 0.550      76.24 90                              0.600 0.700 63.71 01.90 0.600      05.54 Ld                                  O'.Son 1.000 96.93 97.6) 1.500      00.22 2.000      90.03 2.500      100.32 3.000      100.)2 3.500      101 05 4.000    , 101.38 4.500      101.60 5,000      101.96 5.500      102,21 80                              6.000 6.500 102. 43 102. 62 0                                    2.000 2.500 102.66 103. IO 6.000      103. 29 9.000      103. 65 L!3                                10.000      103.06 I                                I I . 000 12.000
: 13. 000 104.29 104.56 104.0 ~
: 14. 000      105. I I
: 15. 000      105.34 16.000      105.50 17.000      105. 0 I 70                          IS. 000 10.000 105.92 106.23 20.000        106.43 21.000        I07. I )
22.000        102. 0'I 23.000        Io). 16 24.000        107. 33 60 0                10                                                20                      25 TIME (HRS)
 
RHR PUMP ROOM (I13,103) HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)
              \
180 160                              RIIR PUIIP ROOII E)  13, 103) IIEA)UP EVALUAYIOII (25 GPII UAIER LEAILISUIUIER)
La                                                                                                      )EIIPERA)URE (OEG F)
                                          ) lllE  Roolir    ROOUr    Roosr  Rooilr Roollr    Roollr  Rooilr  Roollr  Rooilr
{HR)        I (3                                      0.000 0, 100 104.00 104.05 4J                                      0.200 0.300 103.99 104.07 C)                                      0.400 0.500 104.00 104.02 0.550    135.22 0.600    149.41 0.700    141.89 LLI                                      0.$ 00  15). IQ 0.900    169. 22
                                          'I . 000 161.60 140                                  I . 500 2.000 161. 35 161. 2$
2.500    162.62 3.000    163.28 3.500    163. 84 4.000    164. 27 Q                                        4.500 5.000 164 61 165.04 LJ                                      5.500 6.000 164.0$
165.59 CL                                      6.500 7.000 165.22 165. 21 2.500    165.94
                                          $ .000  166.56 LaJ                                      9.000    168.04 I                                      Io 000 II 000 12.000 16$ .04 167.8 ~
168.54 120                                13.000 14.000 168. 74 16$ .38 15.000    169.04                                                                        gl p 16.000    169.26 17.000    169. 13 18.000    169.$ 3, 19.000    I71.59 20.000    I)0.66                                                                        0
: 21. 000  I)0.43 22.000    I )0.9$                                                                          J 23.000    17).03 24.000    I) 1.49 g 6 0
0 100 0                  10              15                        20                    25 TIME (HRS)
 
RHR PUMP ROOM (I13;103) HEATUP EVALUATION (25 CPM WATER LEAK/WINTER)
        )80 160 RHR PUIIP ROOII    T 1 13, 103) HEATUP EVALUATION T25 CPII  14ATER IEAKIHINTER)
TEUPERATURE TOEG F)
LL                                    7 I IIE Rooila      ROOII ~  ROOII ~ ROORF  ROORF    ROOIIF  ROOICS  ROOIIF  Rooile THR)        I 140                              0.000    66.00
: 0. 100    66.00
~
LLJ                                    0.200    65.99 0.300    65.99 C5                                    0.400    6S.99 0.500    6S.99 0.550  10$  .43 o.eoo  130. 1$
0.700  142.93 0.800  I ~ 4.92 0.900  146 21 1.000  146. 63
      -120                              1.500 2.000 147.74 147.32 2.5017  150. 01 3.0UO  151.08 3.500  151.56
                                          ~ 000  151.58 4.50O  152 $ 5 5.000  '152. 8 ~
5.500  153. 19 6.000  153.81 6.500  153.$ 0 7.000  154.23 300                                7.500  154.32 8.000  154,78 9.000  155.38 10.000  154,66 11.000  157.85 12.000  156.65 13.000  157.54 14.000 15.000 15$ .00 157. 41 g
80 16.000 17.000 18.000 158. 72 159. 44 159.65 g~
19.000    159. 5$
20.000    160. 12 6'
21 000    159.52 22.000    160.39 23.000    160.36 24.000    160.54 p S o d 60 0               10                                          20                      25 TIME (HRS)
 
c%
C.,
 
RHR PUMP ROOM (I14,104) HEATUP EVALUATION (5 GPM WATER LEAK/SUMMER) 130
    )25 RIIR  Pull)'OOII t I 14, 101)  IIEATUP EVALVATIOII Ib  Gf ii wAIER LEAAISululER)
T I IIE  R00IIr    Rooiir                                      TEspERATORE    )OEG  F )
{HR)          I ROORr  Rooiir  Rooiir    Roollr  Roour    Rooii ~    Rooilr La                                    0.000      104.00
: 0. 100      104.0'I 0.200      104.01 120                                0.300      101.02 0.400      103.99 0.500      104.01 0.550      I IO. 21 0.600      111.57 0.700      119.07 0.800      120.95 0.900      121 70 1.000      122.21 I 500      123.0S 2.000      123.53 115                                2.500      123.93 l-                                    3.000 3.500 4.000 4.500 5.000 121. 29 1'65 124.91
                                                    )25. 16 125.30" 5.500      125 60 6.000      125.79 6.500      125.08 7.000      126. 1$
7.500      126.33
                                        $ .000 jjo                                9.000 10.000 II 000 126 4$
126. 81 127.07 127.3 ~
12.000      127.59 13.000      127.84                                                                              9
: 14. 000    128.06                                                                                P 15.000      !2$ .27 16.000      I '2$ . 18                                                                        G' 17.000      12$ . 66                                                                          Q 18.000      128.86 19 000      129.01 20.000      129. 23 105                              21.000      120. 39 22.000 23.000 120.56 129 72                                                                              o SI 24.000      129. 8$                                                                                )iS g  r I
0 100 0                  10                  15                      20                        25 TIME (HRS)
 
RH      MP ROOM (l-14,104) HEATUP EVALUATION (5 CPM WATER LEAK/WINTER)
    $ )0 300 RIIR PUIIP ROOII    (I 14 ~ 1041 IIEAIUP EVALUATION (5  GPII WA?ER LEAK/WIIIIERl 1 I WE  ROOWr      Roolir    Roolir  ROOWr  ROUII ~  Roowr
                                                                                                            ?ERPERAIURE (QEO RQQRr  Rooiir fl Roolir (CIR l    I 0.000    66.00 (3                                        O. 100 0.200 66.00
                                                      $ 6.00 0.300    66.00 0.400    66.00 0.500    66.00 90                                    0.550 o'.coo 74.32 80.79 0.?00    88.42 0.800    92.00 0.900    93.69 I . 000  94.52 I . 500  95.88 2.000    9S.SI 2.500    97.06 3.000    9?.6?
3.500    98.04 4.000    98.3?
4.500    98. 6'I 5.000    98.95 80                                    5.500 6.0OQ 99.22 99.46 CL                                        s.soo    99.69
                                            ?.ooo    99.91
                                            ?.500  100. '14 8.'OOO  100. 33 9.000    100. 71 Ld                                        10.000    10'1.06 11 000    101. 39 12.000    10'I . 10
                                          '13.000  102. 00 14,000    102.28
: 15. 000  102.54 Ib.ooo    102.80, 70                                  17.000 18.000 103. 04 103.28 19 000    103. 51 20.000    103. 13 21.000    103.94 22.000    Io ~ . 14 23.000    104. 34                                                                        CP 24.000    104,53 I
r 60 0                  )0              15                          20                      25 TIME (HRS)
 
RHR    r'OOM (1-14,104) HEATUP EVALUA ION (25 GPM WATER LEAK/SUMMER) 180 160                            RIIR PUSP ROOII ( I 14        ~ 104) HBA)UP BVALUAI)OS (25 GPII SAIBR LBAAISUSS(K) 4                                      7188    Roolle          Roose    Roose  Roose  Roose    Roose 76SPERA)UR(
Roose  Roose (OEG  F )
Roose (IIR )
(3                                    0.000
: 0. 100 0.200
                                                  '104.00 104. 0'I 104.01 0.300    104.0O 0.400    104.00 0.500    104. 02 0.550    130. 13 0.600    143.46 0.700    151  75 0.800    153. 83 0.900    154.')9 I . OOU  155 06 140                                1.500
: 2. 000 156.48 157. 14 I                                    2. 500 3.000 158. 29 15$ .99 3.500    159. 45 4.000              '59.68 Q                                      4.500 5.000 159. 59 Ieo.97 5.500    161. 47 CL                                    6.000    161.$ 7 6.500    161.86 7.000    162 48 7.500    162.79 8.000    163. 13 4J                                    Q.ooo 10.000 163.03 164  16 11.000    164. 63 12.000    164. 99 120                                13.000    165 02 14.000    165. 86 15.000    166. 02
: 16. 000    166. 0'I 17.000    166. 56 IB. 000    167.35 19 000    167.ee 20.000    167.88 21.000    168'. le 22.000    168. 3$
23.000    167.$ 4 24.000    168. 75 100 0                    10                15                              20 TIME (HRS)
 
RHR PUMP ROOM (I14,104) HEATUP EVALUATION (25 GPM WATER LEAK/WINTER) 160 140 RNR PUIIP    Rooll  (I 14, 104) IIEATUP EVALUATION I 25 CPII  WATER LEAKININTLR)
I IIIE  ROOllr    Roollr    R00Nr  Roollr Roolir      Roollr TENPERATURE IOEC Roolir fI INR)                                                                    Rooilr  Rooll ~
0.000      66.00
: 0. 100      66.00 0.200      65.99 (3                                    0.300 0.400 66.01 65.98 0.500      65.60 0.550    101.4 ~
120                                0.600    122: 10 0.700    135. 72 0.800    137. 87 0.900    140.29 1.000    140.69 I . 500  112.39 CL                                    2.000 2.500 143, 71 141 53 3.000    145. 12 I                                  ,
3.500 4.000 4.500 146,23 147,79 147. 27 5.000    147. Io 5.500    I ~ 8.41 100                                6.000    149,05 6.500    150.56 7.000    150.06 CL                                    7.500 8.000 150 14 150. 49 9.000    151.56 10.000    151.90 II.OOO    152.07 12.000    152. 89 13.000    153.48 14.000    153.80 15.000 16.000 ISA. 36 151.92 0
80 17'.OOO 18.000 19.000 156. 70 155.56 155, 76 r
P 20.000      155.89 2'1.000      156. 22 22.000      156. 19 23.000      157.00
: 21. 000      157.61 r
o 60                                                                                                                            O D
0                  10                    15                        20                        25 TIME (HRS)
 
RHR PUMP RO OM  (I-14,104)    HEATUP EVALUATION (50  GPM WATER LEAK/WINTER)
TEMPERATURE (
TIME    R OOM&#xb9;      ROOM&#xb9;    ROOM&#xb9;  ROOM&#xb9;  ROOM&#xb9;    ROOM&#xb9;  ROOM&#xb9;  ,
ROOM&#xb9; (HR)      1 0.000000      66.,00 0.100000      65.99 0.200000      65.99 0.300000      66.00 0.400000      65.99 0.500000      65.87 0.550000    125.31 0.600000    146.15 0.700000    154.12 0.800000    155.46 0.900000    155.&0 1.000000    156.62 1.500000    158.91 2.000000    160.49 2.500000    161.47 3.000000    161.78 3.500000    163.46 4.00QOOO    163.83 4.500000    165.12 5.000000    165.26 5.500000    165.78 6.000000    166.32 6.500000    167.01 7.000000    166.52 7.500000    167.65 8.000000    167.98 9.000000    168.71 10.000000    170.23 11.000000    170.11 12.000000    170.48 13.000000    170.31 14.00000Q    171.26 15.000000    172.04 16.000000    171.93 17.000000    172.80 18.000000    173.06 19.000000    173.23 20.000000    173.26 21.000000    173.34 22.000000    174.18 23.000000    174.69 24.000000    174.94
 
==SUMMARY==
OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF OCCURRENCE ROOM&#xb9;      MAX          TIME OF TEMP (F)      OCCURRENCE (HR) 1    174.94          24.0000 RHR PUMP ROOM (I-14g104) HEATUP EVALUATION      (50 GPM WATER  LEAK/WINTER)
PRESSURE    (P TIME    ROOM&#xb9;      ROOM&#xb9;    ROOM&#xb9;  ROOM&#xb9;  ROOM&#xb9;    ROOM&#xb9;  ROOM&#xb9;    ROOM
 
e    (HR) 0.000000 1
14.700000 0.100000    14.700000 0.200000    14.700000 0.300000    14.700000 0.400000    14.700000 0.500000    14.700000 0.550000    14.717000 0.600000    14.704000 0.700000    14.701000 0.800000    14.700000 0.900000    14.700000 1.000000  ~
14.700000 1.500000    14.701000 2.000000    14.699000 2.500000    14.700000 3.000000    14.699000 3.500000    14.700000 4.000000    14.700000 4.500000    14.699000 5.000000    14.700000 5.500000    14.700000 6.000000    14.700000 6.500000    14.700000 7.000000  14.699000 7.500000    14.700000 8.000000    14.700000 9.000000    14.700000 10.000000  14.699000 11.000000    14.700000 12.000000  14.700000 13.000000  14.700000 14.000000  14.700000 15.000000  14.700000 16.000000  14.700000 17.000000  14.699000 18.000000  14.700000 19.000000  14.701000 20.000000  14.701000 21.000000  14.700000 22.000000  14.700000 23.000000  14.700000 24.000000  14.700000
 
==SUMMARY==
OF MAXIMUM COMPARTMENT          PRESSURES  AND TIME OF OCCURRENCE ROOMS    MAX            TIME OF PRES    (PSIA)  OCCURRENCE  (HR) 1    14.717            0.55 RHR PUMP ROOM      (I 14rl04)  HEATUP EVALUATION  (50 GPM WATER  LEAKtWINTER)
RELATIVE HUM TIME        ROOMS    ROOMg    ROOMg    ROOMg  ROOMg  ROOMg    ROOMg  ROO (HR)            1 0.000    0.100 0.100    0.099
 
0.200        0.097 0.300        0.096 0.400        0.095 0.500        0.094 0.550        0.015 0.600        0.009 0.700        0.007 0.800        0.007 0.900        0.007 1.000        0.006 1.500        0.006 2.000        0.006 2.500        0.005 3.000        0.005
          '.500 0.005 4.000        0.005 4.500        0.005 5.000        0.005 5.500        0.005 6.000        0.005 6.500        0.005 7.000        0.005 7.500        0.005 8.000        0.004 9.000-      0.004 10.000        0.004 11.000        0.004 12.000        0.004 13.000        0.004 14.000        0.004 15.000        0.004 16.000        0.004 17.000        0.004 18.000        0.004 19.000        0.004 20.000        0.004 21.000        0.004 22.000        0. 0,04 23.000        0.004 24.000        0.004
 
==SUMMARY==
OF MAXIMUM COMPARTMENT    RELATIUE HUMIDITY AND TIME OF OCCURRENCE ROOM4    MAX            TIME OF HUMIDITY      OCCURRENCE (HR) 0.10      0.00
 
RHR PUMP ROOM      (I-13 ,103)  HEATUP EVALUATION (50  GPM WATER  LEAK/WINTER)
TEMPERATURE (
TIME    ROOM&#xb9;      R OOM&#xb9;  ROOM&#xb9;  ROOM&#xb9;  ROOM&#xb9;    ROOM&#xb9;    ROOM&#xb9;    ROOM&#xb9; (HR)      1 0.000000      66.00 0.100000      65.95 0.20COOO      65.95 0.300000      65.94 0.400000      65.89 0.500000      66.00 0.550000    134.54 0.600000    153.87 0.700000    160.70 0.800000    161.51 0.900000    162.01 1.000000    162.88 1.500000    164.66 2.000000    165.91 2.500000    166.97 3.000000    167.95 3.500000    168.17 4.000000    169.32 4.500000    169.45 5.000000    169.98 5.500000    170.50 6.000000    170.84 6.500000    171.25 7.000000    171.69 7.500000    172.32 8.000000    172.43 9.000000    174.10 10.000000    173.47 11.000000    174.07 12.000000    173.90 13.000000    174.57 14.000000    175.20 15.000000    175.37 16.000000    175.98 17.000000. 176.05 18.000000    176.52 19.000000      176.74 20.000000    177.05 21.000000    177.10 22.000000    177.32 23.000000    177.94 24.000000    179.47
 
==SUMMARY==
OF MAXIMUM COMPARTMENT TEMPERATURES AND        TIME OF OCCURRENCE ROOM&#xb9;        MAX          TIME OF TEMP (F)      OCCURRENCE (HR) 1    178.47            24.0000 RHR PUMP ROOM      (I-13,103)  HEATUP EVALUATION (50  GPM WATER  LEAK/WINTER)
PRESSURE  (P TIME      ROOM &#xb9;    ROOM &#xb9;    ROOM &#xb9; ROOM &#xb9;  ROOM&#xb9;    ROOM&#xb9;    ROOM&#xb9;    ROOM
 
(HR)      1 0.000000  14.700000 0.100000  14.700000 0.200000  14.700000 0.300000  14.700000 0.400000  14.700000 0.500000  14.700000 0.550000  14.711000 0.600000  14.706000 0.700000  14.700000 0.800000  14.700000 0.900000  14.700000 1.000000  14.701000 1.500000  14.700000 2.000000  14.700000 2.500000  14.700000 3.000000  14.700000 3.500000  14.700000 4.000000  14.700000 4.500000  14.700000 5.000000  14.700000 5.500000  14.700000 6.000000  14.701000 6.500000  14.700000 7.000000  14.700000 7.500000  14.699000 8.000000  14.700000 9.000000  14.700000 10.000000  14.700000 11.000000  14.700000 12.000000  14.700000 13.000000  14.700000 14.000000  14.700000 15.000000  14.701000 16.000000  14.700000 17.000000  14.699000 18.000000  14.700000 19.000000  14.700000 20.000000  14.700000 21.000000  14.700000 22.000000  14.700000 23.000000  14.700000 24.000000  14.700000
 
==SUMMARY==
OF MAXIMUM COMPARTMENT PRESSURES    AND TIME OF OCCURRENCE ROOMS    MAX          TIME OF PRES (PSIA) OCCURRENCE (HR) 1    14.711          0.55 RHR PUMP ROOM (I-13,103) HEATUP EVALUATION (50 GPM WATER  LEAK/WINTER)
RELATIVE HUM OMg    TIME      ROOMS    ROOMS  ROOMS ROOMg  ROOMg  ROOMS    ROOM4  ROO (HR)          1 0.000    0.100 0.100    0.098
 
0.200  0. 096 0.300    0.094 0.400  0.092 0.500  0.091 0.550  0.011 0.600  0.007 0.700  0.006 0.800  0.006 0.900    0.005 1.000  0.005 1.500    0.005 2.000  0.005 2.500  0.005 3.aoa  Q.004 3.500  0.004 4.000  0.004 4.500    0.004 5.000    0.004 5.500  0.004 6.000  0.004 6.500  0.004 7.000    0.004 7.5QQ  o.oa4 8.000  0.004 9.000  0.004 10.000  0.004 11.000=  0.004 12.000  0.004 13.000  0.004 14.000  0.004 15.000  0.004 16.000  o.oa4 17.000  0.004 18.000  0.004 19.000  0.004 20.000  0.004 21.000  0.004, 22.000  0.,004 23.000  0.004 24.000  0.004
 
==SUMMARY==
OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOM N'AX          TIME OF HUMIDITY  OCCURRENCE (HR) 0.10        0.00
 
  'M&#xb9; 50 RHR PUMP ROOM    (I-13, 103) HEATUP EVALUATION  (& GPM  WATER LEAK/SUMMER)
TEMPERATURE (OEG F)
TIME    ROOM&#xb9;    ROOMa  R00Ms    RODM>>  RDDM&#xb9;    RDDM&#xb9;  R00M>>    RDDMa  R00M>>  RDDM>>  RDDM&#xb9;  RDDM>>  ROOM&#xb9;  RDOM>>
(HR)      1 0.000000    104.00
: 0. 100000  103. 75 0.20DOOO    103.65 0.300000    103.56 0.400DDO    103.60 0.500000    103.57 0.550000    150.53 0.600000    159.52
: 0. 700000  161. 80 0.800000    163. 18 0.900000    162.82 1.000000    164.71 1.50DOOO    167.09 2.000000    167.72 2.500DOO    169.50 3.000000    170.38 3.5000DD    171.36 4.000000    172.06 4.500000    171.88 5.000000    173.32 5.500000    173.9i 6.000000    174.12 6.500000    172.93 7.000000    174.40 7.500000    175.74 8.000000    176.04 9.000000    176.20 10.000000    178.40 11.000000    177.99 12.000000    178.36 13.000000    178.55 14.000000    179.55 15.000000    '180.04 16.000000    180.'18 17.000000    180.79 18.000000    180.83 19.000000    181.37 20.000000    180.95 21.000000    182.21 22.000000    182.48 23.000000    182.43 24.000000    182.63
 
==SUMMARY==
OF MAXIMUM COMPARTMENT TEMPERATURES AND      TIME OF OCCURRENCE ROOM>>      MAX        TIME OF TEMP  (F)  OCCURRENCE  (HR)
          '1 182.63        24.0000 RHR PUMP ROOM (  I-13. 103) HEATUP EVALUATION  (25  GPM WATER LEAK/SUMMER)
PRESSURE  (PSIA)
OOM>>      TIME    ROOM&#xb9;    ROOM&#xb9;    ROOM&#xb9;    ROOM&#xb9;  ROOM>    ROOM&#xb9;  ROOM&#xb9;    ROOM>    ROOM&#xb9;  ROOM>  ROOM>  ROOM>>  ROOM&#xb9;  ROOM>>
 
(HR)        1 0.000000    14.700000
: 0. 100000  14.700000 0.200000    14.700000 0.300000    14.700000 0.400000    14.700000 0.500000    14.700000 0.550000    14.706000 0.600000    '14.702000 0.700000    14. 701000 0.800000    14.700000 0.900000    14.697000 1.000000    14.700000 1.500000    14.700000 2.000000    14 '01000 2.500000    14.700000 3.000000    14.700000 3.500000    14.700000 4.000000    14.700000 4.500000    14.700000 5.000000    14,700000 5.500000    14.700000 6.000000    14.699000 6.500000    14.699000 7.000000    l4.69900(
        ..500000    >4.70000~
8.000000    14.700000 9.000000    14.70'l000 10.000000    14.696000 11.000000    14.699000 12.000000    14.700000 13.000000    14. 701000 14.000000    '14.700000 15.000000    14.700000 16.000000    14. 701000 17.000000    14.700000 18.000000    14.700000 19.000000    14.700000 20.000000    14.699000 21.000000    14.700000 22.000000    14.700000 23.000000    14.700000 24.000000    14.699000
 
==SUMMARY==
OF MAXIMUM COMPARTMENT PRESSURES            AND TIME OF OCCURRENCE ROOMS      MAX            TIME OF PRES (PSIA) OCCURRENCE (HR) 1    14.706            0.55 RHR PUMP ROOM      (I-13, 103)  HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)
RELATIVE HUMIDITY ROOM@    TIME        ROOMc      ROOMP    ROOM/  ROOMN  ROOMA'OOMt      ROOMi  ROOMi  ROOMS ROOMP ROOMP ROOMS ROOMN ROOMN (HR)          1 0.000    0.380
: 0. 100    0.383
 
0.200      0.384 0.300      0.384 0.400      0.384 0.500      0.384 0.550      0. 108 0.600      0.087 0.700      0.082 0.800      0.079 0.900      0.080 1.000      0.076
    '1
      . 500    0.072 2.000      0.071 2.500      0.06e 3.000      0.06>
3.500      0.066 4.00O      0.064 4.500      0.065 S.OOO      0.063 5.500      0.062 6.000      0.062 6.500      0.063 7.000      0.061 7.500      0.059 8.000      0.059
: 9. OOr. 0.059
  '10. Ooi      0. 05:.
11.00C        0.056 12.000        0.056 13.000        0.056 14.000        0.054 15.000        0.054 16.000        0.054
: 17. 000      0.053
: 18. 000      0.053 19.000        0.052 20.000        0.053
: 21. 000      0.051 22.000        0. 051 23.000                '.051 24.000        0.051
 
==SUMMARY==
OF MAXIMUM COMPARTMENT          RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMN        MAX              TIME OF.
HUMIDITY        OCCURRENCE (HR) 0.38            0.50
 
RHR PUMP ROOM      (I  14 , 104) HEATUP EVALUATION (W  GPM WATER LEAK/SUMMER)
TEMPERATURE (OEG F)
OM>>    TIME    R OQM>>      R OOM>>    ROOM>>  ROOM&#xb9;  ROOM>>    ROOM&#xb9;  ROOM&#xb9;    ROOM&#xb9;  ROOM>>  ROOM>>  ROOM>>  ROOM>>  ROOMt  ROOM>>
(HR)      1 0.000000    104.00
: 0. 100000    103.79 0.200000    103.68 0.300000    103.64 0.400000    103.71 0.500000    103. 82 0.550000    143.49 0.600000    153.57 0.700000    '157. 56 0.800000    158.43 0.900000    'I 58. 85 1.000000    159.65 1.500000    161.95 2.000000    163. 38 2.500000    164.92 3.000000    166.07 3.500000    166.67 4.000000    167.62 4.500000    168.48 5.000000    '168.97 5.500000    169. 73 6.oooooe    170. 6" 6.500000    170. 71 7.000000    177. 56 7.500000    171. 79 8.000000    172.30 9.000000    172.90 10.000000    173.82 11.000000    174. 12 12.000000    175.45 13.000000    175.56 14.000000    176.20.
15.000000    176.63 16.000000    177.43 17.000000    177.46 18.000000    178. 22 19.000000    178. 25 20.000000    178.77 21.000000    179.07 22.000000    179.4'I 23.000000    179. 76 24.000000    179.96
 
==SUMMARY==
OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF OCCURRENCE ROOM>>      MAX            TIME OF TEMP (F)        OCCURRENCE (HR) 1    179.96            24.0000 RHR'UMP  ROOM    (I-14,104)    HEATUP EVALUATION (25  GPM WATER LEAK/SUMMER)
PRESSURE  (PSIA)
OQM>>    TIME      ROOM&#xb9;        ROOMt    RQQM&#xb9;  ROOM>>  ROOM>>    ROOM>>  ROQM>>    ROQM>>    ROOM&#xb9;  ROOM>>  ROOM>>  ROOM>>  ROOMt  ROOMt
 
(HR)    '
0.000000    14.700000
: 0. 100000  14. 701000 0.200000    14.700000 0.300000    14.700000 0.400000    14.700000 0.500000    14.700000 0.550000    '14.708000 0.600000    14.702000 0.700000    14.701000 0.800000    14.701000 0.900000    '14.700000 1:000000    14.700000
        -1.500000    14.700000 2.000000    14.700000 2.500000    14.700000 3.000000    14.700000 3.500000    14.700000 4.000000    14.700000 4.500000    14.700000 5.000000    14.701000 5.500000    14.700000 6.000000    14.701000
      - 6.500000    14.700000 7.000000    14.69700C 7.500000    14.70000C 8.000000    14.700000 9.000000    '14.699000 10.000000    14.700000 11.000000    14.700000 12.000000    14.699000 13.000000    14.700000 14.000000    14.700000 15.000000    14.700000 16.000000    14.699000 17.000000    14.700000 18.000000    14.700000 19.000000    14.700000 20.000000    14.700000 21.000000    14.699000 22.000000    14.700000 23.000000    14.700000 24.000000    14.700000
 
==SUMMARY==
OF MAXIMUM        COMPARTMENT    PRESSURES  AND TIME OF OCCURRENCE ROOMP      MAX            TIME  OF PRES  (PSIA)  OCCURRENCE  (HR) 1    14.708          0.55 RHR PUMP ROOM      (I-14, 104)  HEATUP EVALUATION  (25 GPM WATER LEAK/SUMMER)
RELATIVE HUMIDITY ROOM@      TIME        ROOMi    ROOMS    ROOMS    ROOMP  ROOMS  ROOMS  ROOMS'OOM>>      ROOM4 ROOMP ROOMP ROOMi ROOMi ROOMi (HR)          1 0.000    0.380
: 0. 100    0. 382
 
0.200    0.383 0.300    0.384 0.400    0.383 0.500    0.382 0.550    0. 129 0.600    0. 100 0.700    0. 091 0;800    0.089 0.900    0.086 1.000    0.086 1.500    0.08" 2.000    0.079 2.500    0.076 3.000    0.074 3.500    0.073 4.000    0.071 4.500    0.070 5.000    0.069 5.500    0.068 6.000    0.067 6.500    0.067 7.000    0.057 7.500    0.065 8.OOO    O.O64 9.000    G. 06.
: 10. 00(    C .06.
1 1. OOC-  0. 06" 12.000      0.060 13.000      0.060
: 14. 000    0.059
: 15. 000    O.OSe 16.000      0.057
: 17. 000    0.057 18.000      0.056 19.000      0.056 20.000      0.055
: 21. 000    0. 055, 22.000      0.055 23.000      0.054 24.000      0.054
 
==SUMMARY==
OF MAXIMUM COMPARTMENT  RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMJI'AX            TIME OF HUMIDITY  OCCURRENCE (HR) 0.38      0.30
 
RHR PUMP ROOM                (I 14m 104) HEATUP EVALUATION (100    GPM 'WATER LEAK/WINTER)
TEMPERATURE (OEG F)
OM>>    TIME    ROOM>>                ROOM>>    ROOM>>    ROOM/  ROOM>>    ROOM>>      >>
ROOM>>    ROOM>>
R        ROOMs  ROOM>>  ROOM>>  ROOM>>  ROOM>>  ROOM>>
(HR)      1 0;000000            66.00
: 0. 100000            65.99 0.200000            65.99 0.300000            66.00 0.400000            65.99 o.sooooo            ss'.86 0.550000    159.71 0.600000    173.80 0.700000    176.50 0.800000    177.30 0.900000'77.75 1.000000    178.26 1.500000    179.50 2.000000    181.08 2.500000    l81.78 3.000000    182.49 3.500000    182.47 4.000000    183.24 4.500000    184.28 5.000000    184.6&
5.500000    185.33 6.000000    185.71 6.500000    185.39 7.000000    186.01 7.500000    186.'13 8.000000    186.66 9.000000    187 . 19 10.000000    187.80 11.000000    187.82 12.000000    188.25 13.000000    188.08 14.000000    188.86 15.000000
                  'I89.73 189.50'6.000000 17.000000    190.04 18.000000    190.28 19.000000    '190.01 20.000000    190.68 21.000000    190.66 22.000000    190.65 23.000000    19'1.63 24.000000    191.30
 
==SUMMARY==
OF MAXIMUM POMPA RTMENT TEMPERATURES ANO                    TIME OF OCCURRENCE ROOM >>      MAX                      TIME OF TEMP (F)                OCCURRENCE (HR) 1    191.63                      23.0000 RHR PUMP ROOM                (I-14  104 ) H EATUP EVAI.UATION (100 GPM WATER LEAK/WINTER)
PRESSURE    (PSIA)
OOM>>    TIME    ROOM>>                  ROOMS    ROOM>>  ROOM>>    Ro ROOM>>    ROOM>>  ROOM/    ROOM>>    ROOM>>  ROOMO  ROOM>>  ROOM>>  ROOM>>  ROOMP
 
;P pf
~ r P<
  '1 l    '
      ,Cl
 
(HR)          1 0.000000    14.700000
: 0. 100000  14.700000 0.200000    14.700000 0.300000    14.700000 0.400000    'I4.700000 0.500000    14.700000 0.550000    14. 716000, 0.600000    14.703000 0.700000    14.700000 0.800000    14.700000 0.900000    14.700000 1.000000    14.700000 1.500000    14.700000 2.000000    14.700000 2.500000    14.700000 3.000000    14.699000 3.500000    'I4.700000 4.000000    14.700000 4.500000    14.700000 5.000000    14.700000 5.500000    '14.700000 6.000000    14.698000 6.500000    14. 701000 7.000000    14.700000 7.500000    14.699000 8.000000    14.700000 9.000000    14.700000 10.000000    14.700000 11.000000    14.700000 12.000000    14.699000 13.000000    14.699000 14.000000    14.700000 15.000000    14.700000 16.000000    14.700000 17.000000    14.700000 18.000000    14.700000 19.000000    14.700000 20.000000    14.700000 21.000000    14.700000 22.000000    14.700000 23.000000    14.696000 24.000000    14.700000
 
==SUMMARY==
OF MAXIMUM COMPARTMENT PRESSURES          AND TIME OF OCCURRENCE ROOMO    MAX            TIME OF PRES (PSIA) OCCURRENCE (HR) 1    14.716            0.55 RHR PUMP ROOM      (I-14, 104) HEATUP EVALUATION ( 100 GPM WATER LEAK/WINTER)
RELATIVE HUMIDITY ROOM$    TIME        ROOMS    ROOMl'OOMS      ROOMS    ROOMs  ROOMs  ROOMi  ROOMi  ROOMS ROOMS ROOMt ROOMi ROOM/ ROOMI (HR)          1
: 0. 000    0. 100 0.100    0.099
 
0.200    0.097 0 '00    0.096 0.400    0.095 0.500    0.094 0.550    0.006 0.600    0.004 0.700    0.004 0.800    0.004 0.900    0.004 1.000    0.004
: 1. 500    0.004 2.000    0.003 2.500    0.003 3.000    0.003 3.500    0.003 4.000    0.003 4.500    0.003 5.000    0.003 5.500      0.003 6.000    0.003 6.500    0.003 7.000    0.003 7.500    0.003 8.000    0.003 9.000    0.003 10.000      0.003 11.000      0.003 12.000      0.003 13.000      0.003 14.000. 0.003 15.000      0.003 16.000      0.003
: 17. 000    0.003
  '18.000    0.003
  '19. 000    0.003 20.000      0.003 21.000      0.003 22.000      0.003 23.000      0.003 24.000      0.003
 
==SUMMARY==
OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMS      MAX      TIME OF HUMIDITY OCCURRENCE (HR)
: 0. 10    0.00
 
RHR PUMP ROOM      (I-13 ,103)            HEATUP EVALUATION (100  GPM WATER  LEAK/WINTER)
TEMPERATURE (OEG F)
OMt      TIME    ROOM>>      R OOM>>            ROOMt  ROOMt  ROOM>>    ROOM>>    ROOM&#xb9;    ROOM>>  ROOM>>  ROOM&#xb9;  ROOM$  ROOM>>  ROOM>>  ROOMt (HR)      1 0.000000      66.00
: 0. 100000 65.95 0.200000      65.95 0.300000      65.94 0.400000      65.89 0.500000      66.00 0.550000  "'69 '1 0.600000    '179.83 0.700000    '181.56 0.800000    182.08 0.900000    182.30 1.000000    183.13 1.500000    184.24 2.000000    184.65 2.500000    185.54 3.000000    186.20 3.500000    186.99 187.21      '.000000 4.500000    187.40 5.000000    187.86 5.500000    188.33 6.000000    189.47 6.500000    189.00 7.000000    188.97 7.500000    188.70 8.000000    189.57 9.000000    190.11 10.000000    190.32 11.000000    190.71 12.000000    190.64
      '13.000000    191.09 14.000000    191 ~ 98 15.000000    191.39 16.000000    192.04 17.000000    192.41 18.000000      '192.45 19.000000    192.66 192.79    '0.000000 21.000000    193.05 22.000000    192.99 23.000000    193.10 24.000000      '192.96
 
==SUMMARY==
OF MAXIMUM COMPARTMENT TEMPERATURES AND                  TIME OF, OCCURRENCE ROOM>>      MAX                      TIME OF TEMP (F) OCCURRENCE (HR) 1    193. 10                    23.0000 RHR PUMP ROOM      (I-13, 103)            HEATUP EVALUATION ( 100 GPM WATER LEAK/WINTER)
PRESSURE  (PSIA)
OOM>>    TIME    ROOM>>            ROOM>>        ROOM&#xb9;  ROOMt  ROOM>>    ROOM>>    ROOM>>    ROOMs    ROOM>>  ROOM&#xb9;  ROOM>>  ROOM>>  ROOMt  ROOM>>
 
(HR)        1 0.000000 14.700000
: 0. 100000 14.700000 0.200000 I4.700000 0.,300000 14.700000 0.400000 14.700000 0.500000 14.700000 0.550000 14. 710000 0.600000 14.700000 0.700000 14.700000 0.800000 14.700000 0.900000 14. 701000 1.000000 14. 701000 1.500000 14.700000 2.000000 14.700000 2.500000 14.700000 3.000000 14.700000 3.500000 14.700000 4.000000 14.700000 4.500000 14.700000 5.000000 14.700000 5.500000 14.700000 6.000000 14. 701000 6.500000 14.700000 7.000000 14.700000 7.500000 14.699000 8.000000 I4.699000 9.000000 14.700000 10.000000 14.700000 11.000000 14.700000 12.000000 14.700000 13.000000 14.700000 14.000000 14.697000 15.000000 'I 4. 701000 16.000000 14 '00000 17.000000 14.700000 18.000000 14.700000 19.000000 14.700000 20.000000 14.700000 21.000000 14.700000 22.000000 14.700000 23.000000 14.700000 24.000000 14.700000
 
==SUMMARY==
OF MAXIMUM COMPARTMENT PRESSURES          AND TIME OF OCCURRENCE ROOM&#xb9;      MAX          TIME OF PRES (PSIA) OCCURRENCE (HR) 1    14.710          0.55 RHR PUMP ROOM    (I-13, 103)  HEATUP EVALUATION ( 100 GPM WATER LEAK/WINTER)
RELATIVE HUMIDITY ROOM&#xb9;    TIME                ROOM&#xb9;    ROOM&#xb9;  ROOM&#xb9;    ROOMs  ROOM&#xb9;  ROOM&#xb9;  ROOM&#xb9;  ROOM&#xb9; ROOM&#xb9; ROOM/ ROOM&#xb9; ROOM&#xb9; ROOM&#xb9; (HR) 0.000
: 0. 100
 
0.200    0. 096 0.300    0. 094 0.400    0.092 0.500    0.091 0.550    0.005 0.600    0.004 0.700    0.003 0.800    0.003 0.900    0.003 1.000    0.003 1.500    0.003 2.000    0.003 2.500    0.003 3.000    0.003 3.500    0.003 4.000    0.003 4.500    0.003 5.000    0.003 5.500    0.003 6.000    0.003 6.500    0.003 7.000    0.003 7.500    0.003 8.000    0.003 9.000    0.003 10.000    0.003 11.000    0.003 12.000    0.003 13.000    0.003 14.000    0.003 15.000    0.003 16.000    0.003 17.000    0.003
: 18. 000    0.003
: 19. 000    0.003 20.000    0.003 21.000    0.003 22.000    0.003 23.000    0 '03 24.000    0.003
 
==SUMMARY==
OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMS    MAX      TIME OF HUMIDITY  OCCURRENCE (HR)
: 0. 10    0.00
 
0
*J 0,
I}}

Latest revision as of 17:29, 4 February 2020

Rev 0 to Calculation M-SLD-003,Steam Leak Detection Calc-RHR Pump Rooms.
ML17157B071
Person / Time
Site: Susquehanna  Talen Energy icon.png
Issue date: 09/27/1989
From:
PENNSYLVANIA POWER & LIGHT CO.
To:
Shared Package
ML17157B072 List:
References
M-SLD-003, M-SLD-003-R00, M-SLD-3, M-SLD-3-R, NUDOCS 9203090246
Download: ML17157B071 (54)


Text

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CALCULATION COVER SHEET FILE NO. gZ-I ASIDE III OR XI 0 OTHER QUALITY SUPERSEDED BY QA NON QUALITY PROJECT 5~A ~g, OeTzc.vioN A.OJecT ER/CTN NO. VAJA DESIGN ACTIVITY/PMR NINBER EWR + H81000 PAGE I OF 2o TITLE/DESCRIPTION STG1AF4 LNAic Date'cT IOAI CALC,- RN1C FIlA4P RooAAS T: 1-S Z-loG 3',-i4. X-1O4.

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Calc 4 M-SLD-003 Page 2 of 20 TABLE OF CONTENTS 1 .0 PURPOSE ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 3 2 ~ 0 RE FERENCES ~ ~ ~ ~ ~ ~ ~ ~ ~ , ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 4 3.0 ASSUMPTIONS ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 5 4 ' METHODOLOGY ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 6 5 ~ 0 RESULTS/CONCLUSIONS ................................... 12 ATTACHMENT 1 COTTAP Output for RHR Pump Room (I-13/I-103) 5 GPM Leak (Summer)

ATTACHMENT 2 COTTAP Output for RHR Pump Room (I-13/I-103) 5 GPM Leak (Winter)

ATTACHMENT 3 COTTAP Output for RHR Pump Room (I-13/I-103) 25 GPM Leak (Summer)

COTTAP Output for RHR Pump Room (I-13/I-103) 25 GPM Leak (Winter)

ATTACHMENT 5 COTTAP Output for RHR Pump Room (I-14/I-104) 5 GPM Leak (Summer)

ATTACHMENT 6 COTTAP Output for RHR Pump Room (I-14/I-104) 5 GPM Leak (Winter)

ATTACHMENT 7 COTTAP Output for RHR Pump Room (I-14/I-104) 25 GPM Leak (Summer)

ATTACHMENT 8 COTTAP Output for RHR Pump Room (Z-14/I-104) 25 GPM Leak (Winter)

APPENDIX A Data Input Section RHR Pump Room (I-13/I-103)

APPENDIX B Data Input Section << RHR'ump Room (I-14/I-104)

Calc 0 M-SLD-003 Page 3 of 20

,1.0 PURPOSE The purpose of this calculation is to predict the room temperature profile expected when a small water leak is introduced in the Unit 1 RHR Pump Rooms. The results of this calculation will be used as a basis for development of Steam Leak Detection System setpoints.

Calc 4 M-SLD-001 Page 4 of 20 2 ' REFERENCES 2~1 Calc 4 M-RAF-024, Rev. 0 "RB Post DBA Transient Temperature Analysis" 2.2 'echtel Calc g 176-18, Rev. 5 "RB Cooling Modes" 2.3 SEA-EE-129, Rev. 0 "SSES Unit 1 and Unit 2 Reactor Building Heat Loads" 2~4 ~

Dravings I P&ID M-176, Rev. 20 P&ID M-151 Sht 3, Rev. 2 P&ID M-151 Sht 4, Rev. 1 V-29-1, Rev. 9 V-29-2, Rev. 12 V-29-3, Rev. 11 V-28-1, Rev. 15 V-28-2, Rev. 14 V-28-3, Rev. 17 C-105, Rev. 20 C-106, Rev. 16 C-134, Rev. 15 C-135, Rev. 16 C-156, Rev. 12 C-157, Rev. 13 C-111, Rev. 15 C-117, Rev. 17 HBB-111-1, Rev. 6 HBB-111-2, Rev. 4 HBB-110-1, Rev. 9 GBB-104-1, Rev. 7 GBB-104-2, Rev. 4 GBB-105-1, Rev. 6 GBB-116-1, Rev. 6 GBB-106-1, Rev. 8 2 ' M-199 Piping Class Sheets 2.6 SEIS Pipeline General Index 2' Crane Technical Paper No. 410, 23rd Printing 2 8 ASHRAE 1985 Fundamentals Handbook 2.9 FSAR Table 3.11-6 2 ~ 10 FSAR Section 5.2.5.1.3 2 ~ 11 Calc g M-PAF-001, Rev. 1 "HVAC Environmental Analysis-Reactor Buildings & Control Structure" I 2 '2 COTTAP-2 Theory and Input Description Manual (User's Manual),

Rev. 1, dated 1/27/89.

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Calc g M-SLD-003 Page 5 of 20 3 ' ASSUMPTIONS

1) Plant is operating under normal conditions prior to introducing a steam/water leak.
2) All adjacent rooms will be maintained at their design maximum temperature for summer conditions and at the average temperature for the, month of. January (if blue-box data is available) for winter conditions. Where winter temperature data is not available, the design minimum temperature of 60~F will be used.
3) The room under consideration will not be allowed to pressurize, as the blowout panel will relieve at approximately 0.5 psid. Therefore, a leakage path out of the room will be used to maintain pressure as close to 14.7 psia as possible. The temperature effects due to slight room pressurization are assumed to be negligeble.
4) The effects of adjacent room heatup are not considered in this analysis (i.e. adjacent room temperatures are held constant). This results in a conservative temperature profile for the room under consideration. The actual adjacent room heatup due to the water leak is expected to be minimal (when considering conductive heat losses).
5) The COTTAP model assumes perfect mixing of the air and water/

steam in the room under consideration.

The original 'Bechtel Calc 4 176-23 used the Steam Condensing Mode of RHR as the basis for the steam leak to the RHR Pump rooms. In previous outages, this mode of RHR was removed.

The high energy piping (steam line from HPCI) associated with this mode of operation no longer exists in the RHR Pump rooms. Therefore, this calculation will use the Shutdown Cooling (SDC) mode of RHR as the basis for the water/steam leak in the RHR Pump rooms.

The SDC mode initiates on the 98 psig (RX Pressure) permissive. At 98 psig, the lines are warmed by procedure for approximately 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> before SDC mode actually starts.

During this time, the RX is being cooled down at, a maximum allowed rate of 90~F/hr. conservatism, this calculation will use saturated water atFor14.7 psia and 212 F as the starting conditions for the leak. These conditions approximate the minimum requiiements which define high energy piping. RHR SDC is considered high energy piping for a very short period of time (i.e. < 14 of the time).

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Calc g M-SLD-003 Page 6 of 20 4.0 METHODOLOGY The Compartment Transient Temperature Analysis Program (COTTAP) was used to analyze the affects of a steam/water leak in various rooms within the plant. The program predicted temperature profiles for the room under consideration with the following set of conditions

1) 5 gpm water leak (Summer)
2) 5 gpm water leak (Winter)
3) 25 gpm water leak (Summer)
4) 25 gpm water leak (Winter)

The individual room models were developed from various sources of information, as identified in Section 2.0 References. The results will consist of the COTTAP output and the plots of various profiles for the conditions stated above. The following discussion is provided to outline the steps used in developing the individual room models.

4.1 General Data For Rooms Room Volumes The room volume was taken from Reference 2.1 for the room under consideration. Adjacent room volumes were set to a large value (i.e.

1.0 EE15 cu. ft.) to maintain constant properties such as temperature, pressure and relative humidity.

Initial Pressure All rooms were assumed to be at an initial pressure of 14.7 psia.

Initial Temperature All rooms were assumed to be at their maximum normal design temperature initially for summer conditions. Actual winter data was used, where available, as a starting point for the winter runs. The winter data was taken as the "blue-box" average temperature for January 1988.

The January data was considered to be more conservative than February data. Where actual winter data was not available, the design minimum room temperature of 60' was used.

Where winter data was not available for the room in question, the room was started at a temperature which allows it state with its adjacent rooms.

to reach a steady-

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Calc 0 M-SLD-003 Page 7 of 20 The outside ambient temperature was taken (summer) and 264F (winter). The summer as'9~F ambient was taken from Reference 2.8 as the 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> daily average temperature, based upon the 14 ASHRAE design value,, for the Wilkes-Barre/

Scranton area. The winter value was taken as the actual monthly average for January over the years 1986 thru 1989. This average was based upon SSES Meteorological Data taken from the plant computer. A comparison of February data over this same time period indicated that the January data was more conservative.

Relative Humidity The relative humidity for all rooms connected by ventilation or leakage paths is based upon outside air temperatures of 92 F DB / 78 F WB (summer) and -5 F DB / -5~F WB (winter). Air at these "conditions was then allowed to heat up or cool down (sensible heating/cooling only) to the initial room temperature, and the corresponding RH value calculated or read from the psychrometric chart.

Room Height This value is no longer used by COTTAP.

original purpose was associated with the wall It' condensation calculation used within COTTAP.

COTTAP has been revised and no longer uses this information. Therefore, a value of 10.0 inputted for each room. This value has no ft was significance to the calculation. Note that the actual room height was used in the calculation of room volume.

4.2 Airflow and Leakage Path Data Airflow Data The design airflow is provided for the room under consideration. All flow paths are identified (i.e. supply, exhaust and transfer air). The source of the airflow data is the P&ID associated with the particular ventilation system for that room. The data identifies the room from which the air comes, and the room to which the air goes.

Since air flows are balanced to g 104 accuracy, a conservative value of 1760 scfm was used for room I-13/I-103 (1600 scfm x 1.1). A value of 1210 scfm was used for room I-14/I-104 (1100 scfm x 1.1).

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Calc 4 M-SLD-003 Page 8 of 20 Leakage Path Data As with the airflow data, all rooms connected to the leakage path are identified. The leakage path area is only used to scale the leakage 'flowrates for the entire compartment under consideration. The intent of the leakage path is to prevent compartment pressurization.

For most rooms (except RWCU), only one leakage path is used, aqd a value of 1.0 sq. ft. is inputted for the leakage path area. When. more than one leakage path'xists, actual leakage areas can be inputted to better understand leakage flows between adjacent compartments.

4.3 Heat Load Data Heat Load Type The type of heat load was identified using the followzng nomenclature Type Description 1 Lighting 2 Electrical Panels 3 Motors 4 Unit Coolers 5 Piping 8 Misc. Mechanical Equipment Heat Input Rate The heat rate input in Btu/hr for the associated heat load.

The values for heat load types 1 thru 3 were obtained from References 2.2 & 2.3. The heat rate inputs for type 4 heat loads are inputted as negative values since the unit coolers remove heat from the room. The heat input rate for type 5 heat loads were 'input as -1. This value directs COTTAP to obtain piping

'information necessary to calculate the piping heat loads. The heat input rate for type 8 heat loads was obtained from References 2.2 &

2.3, as necessary for the appropriate room.

To achieve an initial steady-state condition, a miscellaneous heat'load (positive or negative) was added to the main room to balance all other time zero heat loads. This heat load was inputted as type 8.

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Calc 4 M-SLD-003 Page 9 of 20 Note that COTTAP neglects cold pipe and equipment as heat sinks. This represents non-conservatism in this calculation. A sample run made to determine the effects of these heat sinks indicated that resultant temperatures were only slightly lower than the values predicted when neglectinq these heat sinks.

Therefore, this calculation assumes the effects of these heat sinks are negligable.

For walls and floors in contact with ground, the model predicts a conservative value of heat loss to ground. The slabs are assumed to be in contact with soil at a temperature of 55 F. To model the heat loss to ground, a large value of surface film convective heat transfer coefficient'(100 Btu/hr-sq ft- F) has been introduced on the ground side of the floors and walls to achieve a ground contact temperature of 55~F.

4.4 Piping Input Data Only piping with a design. temperature greater than that of the normal room design temperature was included, since COTTAP ignores cold pipe as a heat sink. This generally meant that piping at or close to Reactor conditions was included. Also note that this calculation neglects heat loss from small pipe (i.e. less than 2" OD).

Pipe OD The outside diameter of the pipe was obtained from Reference 2.4 Pipe ID The pipe schedule was obtained from Reference 2.5 . Knowing the schedule, the inside diameter was obtained from Reference 2.7 Insulation The insulation OD was obtained from Reference OD'ipe F 11 Length The pipe length was obtained from Reference 2.4 obtained from Reference Emmisivity

'1 emmisivity was The 2

Insulation k Value The insulation thermal conductivity (k) was obtained from Reference 2.11 .

Pipe Fluid Temperature  : The design fluid temperature was obtained from Reference 2.6

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Calc ¹ M-SLD-003 Page 10 of 20 Fluid Phase The state of the fluid was determined by reviewing the system P&ID's and design temperatures/pressures.

-could carry steam or water, If it a particular line was assumed to be liquid for conservatism.

4.5 General Data For Thick Slabs Room ID ¹ The room number on one side of the slab.

on Side 1 Room ID ¹ on Side 2 The room number on the other side of the slab.

When slab is adjacent to ground, a room ¹ of "0" is used.

Thickness The thickness of the slab was obtained from Reference 2.4 Heat Transfer Area The area of the slab was obtained from Reference 2.4 . The dimensions were scaled from plant ventilation drawings. The slab areas are calculated in the Data Input Section (Refer to Appendix A).

Thermal Conductivity  : The thermal conductivity of the concrete slabs were obtained from Reference 2.8 , Chapter 23 Table 3A. A value of 1.0 Btu/hr sq-ft F was used for all concrete slabs.

Density The density of be 140 ibm/cu all This ft. concrete slabs is assumed to value was obtained from Reference 2.8 , Chapter 23 Table 3A.

Specific Heat The specific heat for all concrete slabs was assumed to be 0.22 Btu/ibm F as obtained from Reference 2.8 , Chapter 23 Table 3A.

4.6 Film Coefficient Data For Thick Slabs Type w/r to Room on Side 1, The type of slab with respect to the room on Side 1 was defined using the following codes Type 1 Vertical Wall Type 2 Floor Type" 3 Ceiling

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Pg Jl 1

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Calc f M-SLD-003 Page 11 of 20 h1 & h2  : All film coefficients (h) for inside walls were calculated by COTTAP. The film coefficient for walls in contact with outside air were inputted as 4.0 Btu/hr-sq ft>> F 6.0 Btu/hr-sq ft- F (Per Reference 2.8 , Chapter 23, Table 1)

A value of 100 Btu/hr-sq ft- F was innutted for valls in contact with ground. This value helps to simulate a vali (or floor) in contact with soil at 55~F. This will result in a conservative prediction of the heat loss ground.

oss t0 4.7 Pipe Break Data Fluid Pressure The fluid pressure within the pipe (psia). The RHR Pump Rooms used saturared fluid conditions of 14.7 psia, which was considered representative of normal Reactor conditions during thee Shutdo u own Cooling mode of RHR.

Mass Flov The total mass flov exiting the pipe break (ibm/hr) was inputt'ed as follows for 5 gpm water/steam leak :

5 gal/min x 1 cu ft/7.48 gal x 60 min/hr

.016719 cu ft/ibm 2400 ibm/hr

/

vf ~ Q.Q16719 cu ft/ibm 6 14.7 psia and 212 F (per ASME Steam Tables) for 25 gpm vater/steam leak :

5 x 2400 ibm/hr ~ 120QQ ibm/hr The break occurs at t 0.5 hrs. This allows the room to reach equilibrium conditions prior to initiation of the break. ln all room models, the break mass flov is allowed to incr ncrease line arly (ramp) from 0 ibm/hr to its maximum value over 0.1 hrs.

Calc 4 M-SLD-003 Page 12 of 20 5.0 RESULTS/CONCLUSXONS The following pages provide the temperature profiles resulting from the RHR Pump Room models for the conditions stated below:

1) 5 gpm water leak (Summer)
2) 5 gpm water .leak (Winter)
3) 25 gpm water leak (Summer)

~

4) 25 gpm water leak (Winter)

The COTTAP output for each case above can be found as Attachments 1 thru 8, respectively. Each output provides a summary of the data input, and the results of each time step within the 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> run time. At the end of each COTTAP output, a summary table of Temp vs Time information, is also provided.

RHR QP ROOM (I13,105) HEATUP EVALUATION (5 GPM WATER LEAK/SUMMER) 135 130 AIIA PUIIP Aoos tl-)3,103) IIEA)uP EvaLUAIIOR )5 GPII rAIEA LE4RISusREA) 125 ) IIIE R oar r Roollr Roolir kuour Ruollr Roollr ICRVCRAIURE )OEG Roollr Rooli ~

f)

Aoorr

)IIA) I (3 0.000

0. Ioo 0.200 104.00 104.04 104.05 a.3oa 104.06 0.400 104. 06 0.500 104. 0) 0.550 111.59 120 0,600 0.700 116.81 121.86 0.800 123.24 0.900 124. 48 I . 000 124 87 I 500 125. 71 2.000 126. 19 2.500 126.55 3.000 126.89 3.500 12). IS 115 4.000 127.43 4.500 121.62 5.000 12).88 5.500 128.09 6.000 128. 28 CL 6.500 128 45 7.000 128.62 2.500 I28.79 8.000 128.94 9.000 129.23

$ 10 10.000

'I I .Ooo 129.51 I29.75 12.000 129.98 13.000 130. 20 14 000 130. 42

15. 000 130.61 16.000 130.80 12.000 130.98 IS.OOO 131.16 19.000 131.32 105 20.000 21.000 131,48 13 I . 64 22.000 131.79 23.000 131,94 24.000 132. 08 100 0 10 15 20 TIME (HRS)

RHR PUMP ROOM (I13,1O3) HEATUP EVALUATION (5 GPM WATER LEAKjWINTER) 110 100 AIIR PUIIP AOOII E I 13 ~ 103) IIEA'SUP EVALUA)ION ES GPII NA)ER LEAK/WIIIIER)

'I I IIE )EIIPERAIUAE IOEG F)

Rooilr Aooilr ROollr Rooilr Aooiir Rooiir Aooiir Aooar Auoii~

LL )IIR) I 0.000 66. 00 O. 100 66. 00 (3 0.200 0.300 65.99 65.09 bJ 0.400 0.500 65.99 66.00 0.550 76.24 90 0.600 0.700 63.71 01.90 0.600 05.54 Ld O'.Son 1.000 96.93 97.6) 1.500 00.22 2.000 90.03 2.500 100.32 3.000 100.)2 3.500 101 05 4.000 , 101.38 4.500 101.60 5,000 101.96 5.500 102,21 80 6.000 6.500 102. 43 102. 62 0 2.000 2.500 102.66 103. IO 6.000 103. 29 9.000 103. 65 L!3 10.000 103.06 I I I . 000 12.000

13. 000 104.29 104.56 104.0 ~
14. 000 105. I I
15. 000 105.34 16.000 105.50 17.000 105. 0 I 70 IS. 000 10.000 105.92 106.23 20.000 106.43 21.000 I07. I )

22.000 102. 0'I 23.000 Io). 16 24.000 107. 33 60 0 10 20 25 TIME (HRS)

RHR PUMP ROOM (I13,103) HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)

\

180 160 RIIR PUIIP ROOII E) 13, 103) IIEA)UP EVALUAYIOII (25 GPII UAIER LEAILISUIUIER)

La )EIIPERA)URE (OEG F)

) lllE Roolir ROOUr Roosr Rooilr Roollr Roollr Rooilr Roollr Rooilr

{HR) I (3 0.000 0, 100 104.00 104.05 4J 0.200 0.300 103.99 104.07 C) 0.400 0.500 104.00 104.02 0.550 135.22 0.600 149.41 0.700 141.89 LLI 0.$ 00 15). IQ 0.900 169. 22

'I . 000 161.60 140 I . 500 2.000 161. 35 161. 2$

2.500 162.62 3.000 163.28 3.500 163. 84 4.000 164. 27 Q 4.500 5.000 164 61 165.04 LJ 5.500 6.000 164.0$

165.59 CL 6.500 7.000 165.22 165. 21 2.500 165.94

$ .000 166.56 LaJ 9.000 168.04 I Io 000 II 000 12.000 16$ .04 167.8 ~

168.54 120 13.000 14.000 168. 74 16$ .38 15.000 169.04 gl p 16.000 169.26 17.000 169. 13 18.000 169.$ 3, 19.000 I71.59 20.000 I)0.66 0

21. 000 I)0.43 22.000 I )0.9$ J 23.000 17).03 24.000 I) 1.49 g 6 0

0 100 0 10 15 20 25 TIME (HRS)

RHR PUMP ROOM (I13;103) HEATUP EVALUATION (25 CPM WATER LEAK/WINTER)

)80 160 RHR PUIIP ROOII T 1 13, 103) HEATUP EVALUATION T25 CPII 14ATER IEAKIHINTER)

TEUPERATURE TOEG F)

LL 7 I IIE Rooila ROOII ~ ROOII ~ ROORF ROORF ROOIIF ROOICS ROOIIF Rooile THR) I 140 0.000 66.00

0. 100 66.00

~

LLJ 0.200 65.99 0.300 65.99 C5 0.400 6S.99 0.500 6S.99 0.550 10$ .43 o.eoo 130. 1$

0.700 142.93 0.800 I ~ 4.92 0.900 146 21 1.000 146. 63

-120 1.500 2.000 147.74 147.32 2.5017 150. 01 3.0UO 151.08 3.500 151.56

~ 000 151.58 4.50O 152 $ 5 5.000 '152. 8 ~

5.500 153. 19 6.000 153.81 6.500 153.$ 0 7.000 154.23 300 7.500 154.32 8.000 154,78 9.000 155.38 10.000 154,66 11.000 157.85 12.000 156.65 13.000 157.54 14.000 15.000 15$ .00 157. 41 g

80 16.000 17.000 18.000 158. 72 159. 44 159.65 g~

19.000 159. 5$

20.000 160. 12 6'

21 000 159.52 22.000 160.39 23.000 160.36 24.000 160.54 p S o d 60 0 10 20 25 TIME (HRS)

c%

C.,

RHR PUMP ROOM (I14,104) HEATUP EVALUATION (5 GPM WATER LEAK/SUMMER) 130

)25 RIIR Pull)'OOII t I 14, 101) IIEATUP EVALVATIOII Ib Gf ii wAIER LEAAISululER)

T I IIE R00IIr Rooiir TEspERATORE )OEG F )

{HR) I ROORr Rooiir Rooiir Roollr Roour Rooii ~ Rooilr La 0.000 104.00

0. 100 104.0'I 0.200 104.01 120 0.300 101.02 0.400 103.99 0.500 104.01 0.550 I IO. 21 0.600 111.57 0.700 119.07 0.800 120.95 0.900 121 70 1.000 122.21 I 500 123.0S 2.000 123.53 115 2.500 123.93 l- 3.000 3.500 4.000 4.500 5.000 121. 29 1'65 124.91

)25. 16 125.30" 5.500 125 60 6.000 125.79 6.500 125.08 7.000 126. 1$

7.500 126.33

$ .000 jjo 9.000 10.000 II 000 126 4$

126. 81 127.07 127.3 ~

12.000 127.59 13.000 127.84 9

14. 000 128.06 P 15.000 !2$ .27 16.000 I '2$ . 18 G' 17.000 12$ . 66 Q 18.000 128.86 19 000 129.01 20.000 129. 23 105 21.000 120. 39 22.000 23.000 120.56 129 72 o SI 24.000 129. 8$ )iS g r I

0 100 0 10 15 20 25 TIME (HRS)

RH MP ROOM (l-14,104) HEATUP EVALUATION (5 CPM WATER LEAK/WINTER)

$ )0 300 RIIR PUIIP ROOII (I 14 ~ 1041 IIEAIUP EVALUATION (5 GPII WA?ER LEAK/WIIIIERl 1 I WE ROOWr Roolir Roolir ROOWr ROUII ~ Roowr

?ERPERAIURE (QEO RQQRr Rooiir fl Roolir (CIR l I 0.000 66.00 (3 O. 100 0.200 66.00

$ 6.00 0.300 66.00 0.400 66.00 0.500 66.00 90 0.550 o'.coo 74.32 80.79 0.?00 88.42 0.800 92.00 0.900 93.69 I . 000 94.52 I . 500 95.88 2.000 9S.SI 2.500 97.06 3.000 9?.6?

3.500 98.04 4.000 98.3?

4.500 98. 6'I 5.000 98.95 80 5.500 6.0OQ 99.22 99.46 CL s.soo 99.69

?.ooo 99.91

?.500 100. '14 8.'OOO 100. 33 9.000 100. 71 Ld 10.000 10'1.06 11 000 101. 39 12.000 10'I . 10

'13.000 102. 00 14,000 102.28

15. 000 102.54 Ib.ooo 102.80, 70 17.000 18.000 103. 04 103.28 19 000 103. 51 20.000 103. 13 21.000 103.94 22.000 Io ~ . 14 23.000 104. 34 CP 24.000 104,53 I

r 60 0 )0 15 20 25 TIME (HRS)

RHR r'OOM (1-14,104) HEATUP EVALUA ION (25 GPM WATER LEAK/SUMMER) 180 160 RIIR PUSP ROOII ( I 14 ~ 104) HBA)UP BVALUAI)OS (25 GPII SAIBR LBAAISUSS(K) 4 7188 Roolle Roose Roose Roose Roose Roose 76SPERA)UR(

Roose Roose (OEG F )

Roose (IIR )

(3 0.000

0. 100 0.200

'104.00 104. 0'I 104.01 0.300 104.0O 0.400 104.00 0.500 104. 02 0.550 130. 13 0.600 143.46 0.700 151 75 0.800 153. 83 0.900 154.')9 I . OOU 155 06 140 1.500

2. 000 156.48 157. 14 I 2. 500 3.000 158. 29 15$ .99 3.500 159. 45 4.000 '59.68 Q 4.500 5.000 159. 59 Ieo.97 5.500 161. 47 CL 6.000 161.$ 7 6.500 161.86 7.000 162 48 7.500 162.79 8.000 163. 13 4J Q.ooo 10.000 163.03 164 16 11.000 164. 63 12.000 164. 99 120 13.000 165 02 14.000 165. 86 15.000 166. 02
16. 000 166. 0'I 17.000 166. 56 IB. 000 167.35 19 000 167.ee 20.000 167.88 21.000 168'. le 22.000 168. 3$

23.000 167.$ 4 24.000 168. 75 100 0 10 15 20 TIME (HRS)

RHR PUMP ROOM (I14,104) HEATUP EVALUATION (25 GPM WATER LEAK/WINTER) 160 140 RNR PUIIP Rooll (I 14, 104) IIEATUP EVALUATION I 25 CPII WATER LEAKININTLR)

I IIIE ROOllr Roollr R00Nr Roollr Roolir Roollr TENPERATURE IOEC Roolir fI INR) Rooilr Rooll ~

0.000 66.00

0. 100 66.00 0.200 65.99 (3 0.300 0.400 66.01 65.98 0.500 65.60 0.550 101.4 ~

120 0.600 122: 10 0.700 135. 72 0.800 137. 87 0.900 140.29 1.000 140.69 I . 500 112.39 CL 2.000 2.500 143, 71 141 53 3.000 145. 12 I ,

3.500 4.000 4.500 146,23 147,79 147. 27 5.000 147. Io 5.500 I ~ 8.41 100 6.000 149,05 6.500 150.56 7.000 150.06 CL 7.500 8.000 150 14 150. 49 9.000 151.56 10.000 151.90 II.OOO 152.07 12.000 152. 89 13.000 153.48 14.000 153.80 15.000 16.000 ISA. 36 151.92 0

80 17'.OOO 18.000 19.000 156. 70 155.56 155, 76 r

P 20.000 155.89 2'1.000 156. 22 22.000 156. 19 23.000 157.00

21. 000 157.61 r

o 60 O D

0 10 15 20 25 TIME (HRS)

RHR PUMP RO OM (I-14,104) HEATUP EVALUATION (50 GPM WATER LEAK/WINTER)

TEMPERATURE (

TIME R OOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ,

ROOM¹ (HR) 1 0.000000 66.,00 0.100000 65.99 0.200000 65.99 0.300000 66.00 0.400000 65.99 0.500000 65.87 0.550000 125.31 0.600000 146.15 0.700000 154.12 0.800000 155.46 0.900000 155.&0 1.000000 156.62 1.500000 158.91 2.000000 160.49 2.500000 161.47 3.000000 161.78 3.500000 163.46 4.00QOOO 163.83 4.500000 165.12 5.000000 165.26 5.500000 165.78 6.000000 166.32 6.500000 167.01 7.000000 166.52 7.500000 167.65 8.000000 167.98 9.000000 168.71 10.000000 170.23 11.000000 170.11 12.000000 170.48 13.000000 170.31 14.00000Q 171.26 15.000000 172.04 16.000000 171.93 17.000000 172.80 18.000000 173.06 19.000000 173.23 20.000000 173.26 21.000000 173.34 22.000000 174.18 23.000000 174.69 24.000000 174.94

SUMMARY

OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF OCCURRENCE ROOM¹ MAX TIME OF TEMP (F) OCCURRENCE (HR) 1 174.94 24.0000 RHR PUMP ROOM (I-14g104) HEATUP EVALUATION (50 GPM WATER LEAK/WINTER)

PRESSURE (P TIME ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM

e (HR) 0.000000 1

14.700000 0.100000 14.700000 0.200000 14.700000 0.300000 14.700000 0.400000 14.700000 0.500000 14.700000 0.550000 14.717000 0.600000 14.704000 0.700000 14.701000 0.800000 14.700000 0.900000 14.700000 1.000000 ~

14.700000 1.500000 14.701000 2.000000 14.699000 2.500000 14.700000 3.000000 14.699000 3.500000 14.700000 4.000000 14.700000 4.500000 14.699000 5.000000 14.700000 5.500000 14.700000 6.000000 14.700000 6.500000 14.700000 7.000000 14.699000 7.500000 14.700000 8.000000 14.700000 9.000000 14.700000 10.000000 14.699000 11.000000 14.700000 12.000000 14.700000 13.000000 14.700000 14.000000 14.700000 15.000000 14.700000 16.000000 14.700000 17.000000 14.699000 18.000000 14.700000 19.000000 14.701000 20.000000 14.701000 21.000000 14.700000 22.000000 14.700000 23.000000 14.700000 24.000000 14.700000

SUMMARY

OF MAXIMUM COMPARTMENT PRESSURES AND TIME OF OCCURRENCE ROOMS MAX TIME OF PRES (PSIA) OCCURRENCE (HR) 1 14.717 0.55 RHR PUMP ROOM (I 14rl04) HEATUP EVALUATION (50 GPM WATER LEAKtWINTER)

RELATIVE HUM TIME ROOMS ROOMg ROOMg ROOMg ROOMg ROOMg ROOMg ROO (HR) 1 0.000 0.100 0.100 0.099

0.200 0.097 0.300 0.096 0.400 0.095 0.500 0.094 0.550 0.015 0.600 0.009 0.700 0.007 0.800 0.007 0.900 0.007 1.000 0.006 1.500 0.006 2.000 0.006 2.500 0.005 3.000 0.005

'.500 0.005 4.000 0.005 4.500 0.005 5.000 0.005 5.500 0.005 6.000 0.005 6.500 0.005 7.000 0.005 7.500 0.005 8.000 0.004 9.000- 0.004 10.000 0.004 11.000 0.004 12.000 0.004 13.000 0.004 14.000 0.004 15.000 0.004 16.000 0.004 17.000 0.004 18.000 0.004 19.000 0.004 20.000 0.004 21.000 0.004 22.000 0. 0,04 23.000 0.004 24.000 0.004

SUMMARY

OF MAXIMUM COMPARTMENT RELATIUE HUMIDITY AND TIME OF OCCURRENCE ROOM4 MAX TIME OF HUMIDITY OCCURRENCE (HR) 0.10 0.00

RHR PUMP ROOM (I-13 ,103) HEATUP EVALUATION (50 GPM WATER LEAK/WINTER)

TEMPERATURE (

TIME ROOM¹ R OOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ (HR) 1 0.000000 66.00 0.100000 65.95 0.20COOO 65.95 0.300000 65.94 0.400000 65.89 0.500000 66.00 0.550000 134.54 0.600000 153.87 0.700000 160.70 0.800000 161.51 0.900000 162.01 1.000000 162.88 1.500000 164.66 2.000000 165.91 2.500000 166.97 3.000000 167.95 3.500000 168.17 4.000000 169.32 4.500000 169.45 5.000000 169.98 5.500000 170.50 6.000000 170.84 6.500000 171.25 7.000000 171.69 7.500000 172.32 8.000000 172.43 9.000000 174.10 10.000000 173.47 11.000000 174.07 12.000000 173.90 13.000000 174.57 14.000000 175.20 15.000000 175.37 16.000000 175.98 17.000000. 176.05 18.000000 176.52 19.000000 176.74 20.000000 177.05 21.000000 177.10 22.000000 177.32 23.000000 177.94 24.000000 179.47

SUMMARY

OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF OCCURRENCE ROOM¹ MAX TIME OF TEMP (F) OCCURRENCE (HR) 1 178.47 24.0000 RHR PUMP ROOM (I-13,103) HEATUP EVALUATION (50 GPM WATER LEAK/WINTER)

PRESSURE (P TIME ROOM ¹ ROOM ¹ ROOM ¹ ROOM ¹ ROOM¹ ROOM¹ ROOM¹ ROOM

(HR) 1 0.000000 14.700000 0.100000 14.700000 0.200000 14.700000 0.300000 14.700000 0.400000 14.700000 0.500000 14.700000 0.550000 14.711000 0.600000 14.706000 0.700000 14.700000 0.800000 14.700000 0.900000 14.700000 1.000000 14.701000 1.500000 14.700000 2.000000 14.700000 2.500000 14.700000 3.000000 14.700000 3.500000 14.700000 4.000000 14.700000 4.500000 14.700000 5.000000 14.700000 5.500000 14.700000 6.000000 14.701000 6.500000 14.700000 7.000000 14.700000 7.500000 14.699000 8.000000 14.700000 9.000000 14.700000 10.000000 14.700000 11.000000 14.700000 12.000000 14.700000 13.000000 14.700000 14.000000 14.700000 15.000000 14.701000 16.000000 14.700000 17.000000 14.699000 18.000000 14.700000 19.000000 14.700000 20.000000 14.700000 21.000000 14.700000 22.000000 14.700000 23.000000 14.700000 24.000000 14.700000

SUMMARY

OF MAXIMUM COMPARTMENT PRESSURES AND TIME OF OCCURRENCE ROOMS MAX TIME OF PRES (PSIA) OCCURRENCE (HR) 1 14.711 0.55 RHR PUMP ROOM (I-13,103) HEATUP EVALUATION (50 GPM WATER LEAK/WINTER)

RELATIVE HUM OMg TIME ROOMS ROOMS ROOMS ROOMg ROOMg ROOMS ROOM4 ROO (HR) 1 0.000 0.100 0.100 0.098

0.200 0. 096 0.300 0.094 0.400 0.092 0.500 0.091 0.550 0.011 0.600 0.007 0.700 0.006 0.800 0.006 0.900 0.005 1.000 0.005 1.500 0.005 2.000 0.005 2.500 0.005 3.aoa Q.004 3.500 0.004 4.000 0.004 4.500 0.004 5.000 0.004 5.500 0.004 6.000 0.004 6.500 0.004 7.000 0.004 7.5QQ o.oa4 8.000 0.004 9.000 0.004 10.000 0.004 11.000= 0.004 12.000 0.004 13.000 0.004 14.000 0.004 15.000 0.004 16.000 o.oa4 17.000 0.004 18.000 0.004 19.000 0.004 20.000 0.004 21.000 0.004, 22.000 0.,004 23.000 0.004 24.000 0.004

SUMMARY

OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOM N'AX TIME OF HUMIDITY OCCURRENCE (HR) 0.10 0.00

'M¹ 50 RHR PUMP ROOM (I-13, 103) HEATUP EVALUATION (& GPM WATER LEAK/SUMMER)

TEMPERATURE (OEG F)

TIME ROOM¹ ROOMa R00Ms RODM>> RDDM¹ RDDM¹ R00M>> RDDMa R00M>> RDDM>> RDDM¹ RDDM>> ROOM¹ RDOM>>

(HR) 1 0.000000 104.00

0. 100000 103. 75 0.20DOOO 103.65 0.300000 103.56 0.400DDO 103.60 0.500000 103.57 0.550000 150.53 0.600000 159.52
0. 700000 161. 80 0.800000 163. 18 0.900000 162.82 1.000000 164.71 1.50DOOO 167.09 2.000000 167.72 2.500DOO 169.50 3.000000 170.38 3.5000DD 171.36 4.000000 172.06 4.500000 171.88 5.000000 173.32 5.500000 173.9i 6.000000 174.12 6.500000 172.93 7.000000 174.40 7.500000 175.74 8.000000 176.04 9.000000 176.20 10.000000 178.40 11.000000 177.99 12.000000 178.36 13.000000 178.55 14.000000 179.55 15.000000 '180.04 16.000000 180.'18 17.000000 180.79 18.000000 180.83 19.000000 181.37 20.000000 180.95 21.000000 182.21 22.000000 182.48 23.000000 182.43 24.000000 182.63

SUMMARY

OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF OCCURRENCE ROOM>> MAX TIME OF TEMP (F) OCCURRENCE (HR)

'1 182.63 24.0000 RHR PUMP ROOM ( I-13. 103) HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)

PRESSURE (PSIA)

OOM>> TIME ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM> ROOM¹ ROOM¹ ROOM> ROOM¹ ROOM> ROOM> ROOM>> ROOM¹ ROOM>>

(HR) 1 0.000000 14.700000

0. 100000 14.700000 0.200000 14.700000 0.300000 14.700000 0.400000 14.700000 0.500000 14.700000 0.550000 14.706000 0.600000 '14.702000 0.700000 14. 701000 0.800000 14.700000 0.900000 14.697000 1.000000 14.700000 1.500000 14.700000 2.000000 14 '01000 2.500000 14.700000 3.000000 14.700000 3.500000 14.700000 4.000000 14.700000 4.500000 14.700000 5.000000 14,700000 5.500000 14.700000 6.000000 14.699000 6.500000 14.699000 7.000000 l4.69900(

..500000 >4.70000~

8.000000 14.700000 9.000000 14.70'l000 10.000000 14.696000 11.000000 14.699000 12.000000 14.700000 13.000000 14. 701000 14.000000 '14.700000 15.000000 14.700000 16.000000 14. 701000 17.000000 14.700000 18.000000 14.700000 19.000000 14.700000 20.000000 14.699000 21.000000 14.700000 22.000000 14.700000 23.000000 14.700000 24.000000 14.699000

SUMMARY

OF MAXIMUM COMPARTMENT PRESSURES AND TIME OF OCCURRENCE ROOMS MAX TIME OF PRES (PSIA) OCCURRENCE (HR) 1 14.706 0.55 RHR PUMP ROOM (I-13, 103) HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)

RELATIVE HUMIDITY ROOM@ TIME ROOMc ROOMP ROOM/ ROOMN ROOMA'OOMt ROOMi ROOMi ROOMS ROOMP ROOMP ROOMS ROOMN ROOMN (HR) 1 0.000 0.380

0. 100 0.383

0.200 0.384 0.300 0.384 0.400 0.384 0.500 0.384 0.550 0. 108 0.600 0.087 0.700 0.082 0.800 0.079 0.900 0.080 1.000 0.076

'1

. 500 0.072 2.000 0.071 2.500 0.06e 3.000 0.06>

3.500 0.066 4.00O 0.064 4.500 0.065 S.OOO 0.063 5.500 0.062 6.000 0.062 6.500 0.063 7.000 0.061 7.500 0.059 8.000 0.059

9. OOr. 0.059

'10. Ooi 0. 05:.

11.00C 0.056 12.000 0.056 13.000 0.056 14.000 0.054 15.000 0.054 16.000 0.054

17. 000 0.053
18. 000 0.053 19.000 0.052 20.000 0.053
21. 000 0.051 22.000 0. 051 23.000 '.051 24.000 0.051

SUMMARY

OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMN MAX TIME OF.

HUMIDITY OCCURRENCE (HR) 0.38 0.50

RHR PUMP ROOM (I 14 , 104) HEATUP EVALUATION (W GPM WATER LEAK/SUMMER)

TEMPERATURE (OEG F)

OM>> TIME R OQM>> R OOM>> ROOM>> ROOM¹ ROOM>> ROOM¹ ROOM¹ ROOM¹ ROOM>> ROOM>> ROOM>> ROOM>> ROOMt ROOM>>

(HR) 1 0.000000 104.00

0. 100000 103.79 0.200000 103.68 0.300000 103.64 0.400000 103.71 0.500000 103. 82 0.550000 143.49 0.600000 153.57 0.700000 '157. 56 0.800000 158.43 0.900000 'I 58. 85 1.000000 159.65 1.500000 161.95 2.000000 163. 38 2.500000 164.92 3.000000 166.07 3.500000 166.67 4.000000 167.62 4.500000 168.48 5.000000 '168.97 5.500000 169. 73 6.oooooe 170. 6" 6.500000 170. 71 7.000000 177. 56 7.500000 171. 79 8.000000 172.30 9.000000 172.90 10.000000 173.82 11.000000 174. 12 12.000000 175.45 13.000000 175.56 14.000000 176.20.

15.000000 176.63 16.000000 177.43 17.000000 177.46 18.000000 178. 22 19.000000 178. 25 20.000000 178.77 21.000000 179.07 22.000000 179.4'I 23.000000 179. 76 24.000000 179.96

SUMMARY

OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF OCCURRENCE ROOM>> MAX TIME OF TEMP (F) OCCURRENCE (HR) 1 179.96 24.0000 RHR'UMP ROOM (I-14,104) HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)

PRESSURE (PSIA)

OQM>> TIME ROOM¹ ROOMt RQQM¹ ROOM>> ROOM>> ROOM>> ROQM>> ROQM>> ROOM¹ ROOM>> ROOM>> ROOM>> ROOMt ROOMt

(HR) '

0.000000 14.700000

0. 100000 14. 701000 0.200000 14.700000 0.300000 14.700000 0.400000 14.700000 0.500000 14.700000 0.550000 '14.708000 0.600000 14.702000 0.700000 14.701000 0.800000 14.701000 0.900000 '14.700000 1:000000 14.700000

-1.500000 14.700000 2.000000 14.700000 2.500000 14.700000 3.000000 14.700000 3.500000 14.700000 4.000000 14.700000 4.500000 14.700000 5.000000 14.701000 5.500000 14.700000 6.000000 14.701000

- 6.500000 14.700000 7.000000 14.69700C 7.500000 14.70000C 8.000000 14.700000 9.000000 '14.699000 10.000000 14.700000 11.000000 14.700000 12.000000 14.699000 13.000000 14.700000 14.000000 14.700000 15.000000 14.700000 16.000000 14.699000 17.000000 14.700000 18.000000 14.700000 19.000000 14.700000 20.000000 14.700000 21.000000 14.699000 22.000000 14.700000 23.000000 14.700000 24.000000 14.700000

SUMMARY

OF MAXIMUM COMPARTMENT PRESSURES AND TIME OF OCCURRENCE ROOMP MAX TIME OF PRES (PSIA) OCCURRENCE (HR) 1 14.708 0.55 RHR PUMP ROOM (I-14, 104) HEATUP EVALUATION (25 GPM WATER LEAK/SUMMER)

RELATIVE HUMIDITY ROOM@ TIME ROOMi ROOMS ROOMS ROOMP ROOMS ROOMS ROOMS'OOM>> ROOM4 ROOMP ROOMP ROOMi ROOMi ROOMi (HR) 1 0.000 0.380

0. 100 0. 382

0.200 0.383 0.300 0.384 0.400 0.383 0.500 0.382 0.550 0. 129 0.600 0. 100 0.700 0. 091 0;800 0.089 0.900 0.086 1.000 0.086 1.500 0.08" 2.000 0.079 2.500 0.076 3.000 0.074 3.500 0.073 4.000 0.071 4.500 0.070 5.000 0.069 5.500 0.068 6.000 0.067 6.500 0.067 7.000 0.057 7.500 0.065 8.OOO O.O64 9.000 G. 06.

10. 00( C .06.

1 1. OOC- 0. 06" 12.000 0.060 13.000 0.060

14. 000 0.059
15. 000 O.OSe 16.000 0.057
17. 000 0.057 18.000 0.056 19.000 0.056 20.000 0.055
21. 000 0. 055, 22.000 0.055 23.000 0.054 24.000 0.054

SUMMARY

OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMJI'AX TIME OF HUMIDITY OCCURRENCE (HR) 0.38 0.30

RHR PUMP ROOM (I 14m 104) HEATUP EVALUATION (100 GPM 'WATER LEAK/WINTER)

TEMPERATURE (OEG F)

OM>> TIME ROOM>> ROOM>> ROOM>> ROOM/ ROOM>> ROOM>> >>

ROOM>> ROOM>>

R ROOMs ROOM>> ROOM>> ROOM>> ROOM>> ROOM>>

(HR) 1 0;000000 66.00

0. 100000 65.99 0.200000 65.99 0.300000 66.00 0.400000 65.99 o.sooooo ss'.86 0.550000 159.71 0.600000 173.80 0.700000 176.50 0.800000 177.30 0.900000'77.75 1.000000 178.26 1.500000 179.50 2.000000 181.08 2.500000 l81.78 3.000000 182.49 3.500000 182.47 4.000000 183.24 4.500000 184.28 5.000000 184.6&

5.500000 185.33 6.000000 185.71 6.500000 185.39 7.000000 186.01 7.500000 186.'13 8.000000 186.66 9.000000 187 . 19 10.000000 187.80 11.000000 187.82 12.000000 188.25 13.000000 188.08 14.000000 188.86 15.000000

'I89.73 189.50'6.000000 17.000000 190.04 18.000000 190.28 19.000000 '190.01 20.000000 190.68 21.000000 190.66 22.000000 190.65 23.000000 19'1.63 24.000000 191.30

SUMMARY

OF MAXIMUM POMPA RTMENT TEMPERATURES ANO TIME OF OCCURRENCE ROOM >> MAX TIME OF TEMP (F) OCCURRENCE (HR) 1 191.63 23.0000 RHR PUMP ROOM (I-14 104 ) H EATUP EVAI.UATION (100 GPM WATER LEAK/WINTER)

PRESSURE (PSIA)

OOM>> TIME ROOM>> ROOMS ROOM>> ROOM>> Ro ROOM>> ROOM>> ROOM/ ROOM>> ROOM>> ROOMO ROOM>> ROOM>> ROOM>> ROOMP

P pf

~ r P<

'1 l '

,Cl

(HR) 1 0.000000 14.700000

0. 100000 14.700000 0.200000 14.700000 0.300000 14.700000 0.400000 'I4.700000 0.500000 14.700000 0.550000 14. 716000, 0.600000 14.703000 0.700000 14.700000 0.800000 14.700000 0.900000 14.700000 1.000000 14.700000 1.500000 14.700000 2.000000 14.700000 2.500000 14.700000 3.000000 14.699000 3.500000 'I4.700000 4.000000 14.700000 4.500000 14.700000 5.000000 14.700000 5.500000 '14.700000 6.000000 14.698000 6.500000 14. 701000 7.000000 14.700000 7.500000 14.699000 8.000000 14.700000 9.000000 14.700000 10.000000 14.700000 11.000000 14.700000 12.000000 14.699000 13.000000 14.699000 14.000000 14.700000 15.000000 14.700000 16.000000 14.700000 17.000000 14.700000 18.000000 14.700000 19.000000 14.700000 20.000000 14.700000 21.000000 14.700000 22.000000 14.700000 23.000000 14.696000 24.000000 14.700000

SUMMARY

OF MAXIMUM COMPARTMENT PRESSURES AND TIME OF OCCURRENCE ROOMO MAX TIME OF PRES (PSIA) OCCURRENCE (HR) 1 14.716 0.55 RHR PUMP ROOM (I-14, 104) HEATUP EVALUATION ( 100 GPM WATER LEAK/WINTER)

RELATIVE HUMIDITY ROOM$ TIME ROOMS ROOMl'OOMS ROOMS ROOMs ROOMs ROOMi ROOMi ROOMS ROOMS ROOMt ROOMi ROOM/ ROOMI (HR) 1

0. 000 0. 100 0.100 0.099

0.200 0.097 0 '00 0.096 0.400 0.095 0.500 0.094 0.550 0.006 0.600 0.004 0.700 0.004 0.800 0.004 0.900 0.004 1.000 0.004

1. 500 0.004 2.000 0.003 2.500 0.003 3.000 0.003 3.500 0.003 4.000 0.003 4.500 0.003 5.000 0.003 5.500 0.003 6.000 0.003 6.500 0.003 7.000 0.003 7.500 0.003 8.000 0.003 9.000 0.003 10.000 0.003 11.000 0.003 12.000 0.003 13.000 0.003 14.000. 0.003 15.000 0.003 16.000 0.003
17. 000 0.003

'18.000 0.003

'19. 000 0.003 20.000 0.003 21.000 0.003 22.000 0.003 23.000 0.003 24.000 0.003

SUMMARY

OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMS MAX TIME OF HUMIDITY OCCURRENCE (HR)

0. 10 0.00

RHR PUMP ROOM (I-13 ,103) HEATUP EVALUATION (100 GPM WATER LEAK/WINTER)

TEMPERATURE (OEG F)

OMt TIME ROOM>> R OOM>> ROOMt ROOMt ROOM>> ROOM>> ROOM¹ ROOM>> ROOM>> ROOM¹ ROOM$ ROOM>> ROOM>> ROOMt (HR) 1 0.000000 66.00

0. 100000 65.95 0.200000 65.95 0.300000 65.94 0.400000 65.89 0.500000 66.00 0.550000 "'69 '1 0.600000 '179.83 0.700000 '181.56 0.800000 182.08 0.900000 182.30 1.000000 183.13 1.500000 184.24 2.000000 184.65 2.500000 185.54 3.000000 186.20 3.500000 186.99 187.21 '.000000 4.500000 187.40 5.000000 187.86 5.500000 188.33 6.000000 189.47 6.500000 189.00 7.000000 188.97 7.500000 188.70 8.000000 189.57 9.000000 190.11 10.000000 190.32 11.000000 190.71 12.000000 190.64

'13.000000 191.09 14.000000 191 ~ 98 15.000000 191.39 16.000000 192.04 17.000000 192.41 18.000000 '192.45 19.000000 192.66 192.79 '0.000000 21.000000 193.05 22.000000 192.99 23.000000 193.10 24.000000 '192.96

SUMMARY

OF MAXIMUM COMPARTMENT TEMPERATURES AND TIME OF, OCCURRENCE ROOM>> MAX TIME OF TEMP (F) OCCURRENCE (HR) 1 193. 10 23.0000 RHR PUMP ROOM (I-13, 103) HEATUP EVALUATION ( 100 GPM WATER LEAK/WINTER)

PRESSURE (PSIA)

OOM>> TIME ROOM>> ROOM>> ROOM¹ ROOMt ROOM>> ROOM>> ROOM>> ROOMs ROOM>> ROOM¹ ROOM>> ROOM>> ROOMt ROOM>>

(HR) 1 0.000000 14.700000

0. 100000 14.700000 0.200000 I4.700000 0.,300000 14.700000 0.400000 14.700000 0.500000 14.700000 0.550000 14. 710000 0.600000 14.700000 0.700000 14.700000 0.800000 14.700000 0.900000 14. 701000 1.000000 14. 701000 1.500000 14.700000 2.000000 14.700000 2.500000 14.700000 3.000000 14.700000 3.500000 14.700000 4.000000 14.700000 4.500000 14.700000 5.000000 14.700000 5.500000 14.700000 6.000000 14. 701000 6.500000 14.700000 7.000000 14.700000 7.500000 14.699000 8.000000 I4.699000 9.000000 14.700000 10.000000 14.700000 11.000000 14.700000 12.000000 14.700000 13.000000 14.700000 14.000000 14.697000 15.000000 'I 4. 701000 16.000000 14 '00000 17.000000 14.700000 18.000000 14.700000 19.000000 14.700000 20.000000 14.700000 21.000000 14.700000 22.000000 14.700000 23.000000 14.700000 24.000000 14.700000

SUMMARY

OF MAXIMUM COMPARTMENT PRESSURES AND TIME OF OCCURRENCE ROOM¹ MAX TIME OF PRES (PSIA) OCCURRENCE (HR) 1 14.710 0.55 RHR PUMP ROOM (I-13, 103) HEATUP EVALUATION ( 100 GPM WATER LEAK/WINTER)

RELATIVE HUMIDITY ROOM¹ TIME ROOM¹ ROOM¹ ROOM¹ ROOMs ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM¹ ROOM/ ROOM¹ ROOM¹ ROOM¹ (HR) 0.000

0. 100

0.200 0. 096 0.300 0. 094 0.400 0.092 0.500 0.091 0.550 0.005 0.600 0.004 0.700 0.003 0.800 0.003 0.900 0.003 1.000 0.003 1.500 0.003 2.000 0.003 2.500 0.003 3.000 0.003 3.500 0.003 4.000 0.003 4.500 0.003 5.000 0.003 5.500 0.003 6.000 0.003 6.500 0.003 7.000 0.003 7.500 0.003 8.000 0.003 9.000 0.003 10.000 0.003 11.000 0.003 12.000 0.003 13.000 0.003 14.000 0.003 15.000 0.003 16.000 0.003 17.000 0.003

18. 000 0.003
19. 000 0.003 20.000 0.003 21.000 0.003 22.000 0.003 23.000 0 '03 24.000 0.003

SUMMARY

OF MAXIMUM COMPARTMENT RELATIVE HUMIDITY AND TIME OF OCCURRENCE ROOMS MAX TIME OF HUMIDITY OCCURRENCE (HR)

0. 10 0.00

0

  • J 0,

I