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{{#Wiki_filter:ATTACHMENT 2TOAEP:NRC:08940 PROPOSEDREVISEDTECHNICAL SPECIFICATION PAGES90ii020047 90i029'DR ADOCK050003i5PPNU
{{#Wiki_filter:ATTACHMENT 2 TO AEP:NRC:08940 PROPOSED REVISED TECHNICAL SPECIFICATION PAGES 90ii020047 050003i5 90i029'DR ADOCK P                    PNU
.~4 REACTIVITY CONTROLSYSTEMSCHARGINGPUMP-SHUTDOWNLIMITINGCONDITION FOROPERATION 3.1.2.3a.Onechargingpumpintheboroninjection flowpathrequiredbySpecification 3.1.2.1shallbeOPERABLEandcapableofbeingpoweredfromanOPERABLEemergency bus.b.Onechargingflowpathassociated withsupportofUnit2shutdownfunctions shallbeavailable.
APPLICABILITY:
Specification 3.1.2.3.a.
-MODES5and6Specification 3.1.2.3.b.
-AtalltimeswhenUnit2isinMODES1,2,3,or4.ACTION'.WithnochargingpumpOPERABLE, suspendalloperations involving COREALTERATIONS orposi.tive reactivity changes.**
b.WithmorethanonechargingpumpOPERABLEorwithasafetyinjection pump(s)OPERABLEwhenthetemperature ofanyRCScoldlegislessthan0orequalto152F,unlessthereactorvesselheadisremoved,removetheadditional chargingpump(s)andthesafetyinjection pump(s)motorcircuitbreakersfromtheelectrical powercircuitwithinonehour.c.Theprovisions ofSpecification 3.0.3arenotapplicable.
Inadditiontotheabove,whenSpecification 3.1.2.3.b isapplicable andtherequiredflowpathisnotavailable, returntherequiredflowpathtoavailable statuswithin7days,orprovideequivalent shutdowncapability inUnit2andreturntherequiredflowpathtoavailable statuswithinthenext60days,orhaveUnit2inHOTSTANDBYwithinthenext12hoursandHOTSHUTDOWNwithinthefollowing 24hours.e.Therequirements ofSpecification


==3.0. 4arenotapplicable==
. ~ 4 REACTIVITY CONTROL SYSTEMS CHARGING PUMP - SHUTDOWN LIMITING CONDITION    FOR OPERATION 3.1.2.3
whenSpecification 3.1.2.3.b applies.SURVEILLANCE REUIREMENTS 4.1.2.3.1 Theaboverequiredchargingpumpshallbedemonstrated OPERABLEbyverifying, thatonrecirculation flow,thepumpdevelopsadischarge pressureofgreaterthanorequalto2390psigwhentestedpursuanttoSpecification 4.0.5atleastonceper31days.+Amaximumofonecentrifugal chargingpumpshallbeOPERABLEwheneverthe0temperature ofoneormoreoftheRCScoldlegsislessthanorequalto152F.~~Forpurposesofthisspecifi,cation, additionofwaterfromtheRWSTdoesnotconstitute apositivereactivity additionprovidedtheboronconcentration intheRWSTisgreaterthantheminimumrequiredbySpecification 3.1.2.7.b.2.
: a. One  charging pump in the boron injection flow path required by Specification 3.1.2.1 shall be OPERABLE and capable of being powered from an  OPERABLE  emergency bus.
COOKNUCLEARPLANT-UNIT13/41-11AMENDMENT NO.
: b. One charging flowpath associated with support of Unit    2  shutdown functions shall be available.
REACTIVITY CONTROLSYSTEMSCHARGINGPUMP-SHUTDOWNLIMITINGCONDITION FOROPERATION 4.1.2.3.2 Allchargingpumpsandsafetyinjection pumps,excluding theaboverequiredOPERABLEchargingpump,shallbedemonstrated inoperable byverifying thatthemotorcircuitbreakershavebeenremovedfrom'heir electrical powersupplycircuitsatleastonceper12hours,exceptwhen:a.Thereactorvesselheadisremoved,or0b.Thetemperature ofallRCScoldlegsisgreaterthan152F4.1.2.3.3 Charginglinecross-tie valvestoUnit2willbecycledfulltravelatleastonceper18months.Following cycling,thevalveswillbeverifiedtobeintheirclosedpositions.
APPLICABILITY:    Specification 3.1.2.3.a.   - MODES 5 and 6 Specification 3.1.2.3.b.  - At all times when  Unit 2 is in MODES  1, 2, 3, or 4.
COOKNUCLEARPLANT-UNIT13/41-llaAMENDMENT NO.
ACTION'.
REACTORCOOLANTSYSTEMSHUTDOWNLIMITINGCONDITION FOROPERATION 3.4.1.3a.ThecoolantloopslistedbelowshallbeOPERABLEandinoperation asrequiredbyitemsbandc:1.ReactorCoolantLoop1anditsassociated steamgenerator andreactorcoolantpump,~2.ReactorCoolantLoop2anditsassociated steamgenerator andreactorcoolantpump,*3.ReactorCoolantLoop3anditsassociated steamgenerator andreactorcoolantpump,*4.ReactorCoolantLoop4anditsassociated steamgenerator andreactorcoolantpump,*5.ResidualHeatRemoval-East,~~6.ResidualHeatRemoval-West,*~b.AtleasttwooftheabovecoolantloopsshallbeOPERABLEandatleastoneloopinoperation ifthereactortripbreakersareintheopenposition, orthecontrolroddrivesystemisnotcapableofrodwithdrawal.~**
With no charging    pump OPERABLE, suspend  all operations involving CORE ALTERATIONS  or posi.tive reactivity changes.**
c.AtleastthreeoftheabovereactorcoolantloopsshallbeOPERABLEandinoperation whenthereactortripsystembreakersareintheclosedpositionandthecontrolroddrivesystemiscapableofrodwithdrawal.
: b. With more than one charging pump OPERABLE or with a safety injection pump(s) OPERABLE0 when the temperature of any RCS cold leg is less than or equal to 152 F, unless the reactor vessel head is removed, remove the additional charging pump(s) and the safety injection pump(s) motor circuit breakers from the electrical power circuit within one hour.
APPLICABILITY:
: c. The  provisions of Specification 3.0.3 are not applicable.
MODES4and5+AreactorcoolantpumpshallnotbestartedwithoneormoreoftheRCScoldlegtemperatures lessthanorequalto152Funless1)thepressurizer
In addition to the above, when Specification 3.1.2.3.b is applicable and the  required flow path is not available, return the required flow path  to available status within 7 days, or provide equivalent shutdown capability in Unit 2 and return the required flow path to available status within the next 60 days, or have Unit 2 in HOT STANDBY within the next 12 hours and HOT SHUTDOWN within the following 24 hours.
!0watervolumeislessthan62%ofspanor2)thesecondary water0temperature ofeachsteamgenerator islessthan50FaboveeachoftheRCScoldlegtemperatures.
: e. The requirements    of Specification 3.0.4 are not applicable  when Specification 3.1.2.3.b applies.
Operability ofareactorcoolantloop(s)doesnotrequireanOPERABLEauxiliary feedwater system.**Thenormaloremergency powersourcemaybeinoperable inMODE5.>*>Allreactorcoolantpumpsandresidualheatremovalpumpsmaybede-energized forupto1hourprovided1)nooperations arepermitted thatwouldcausedilutionofthereactorcoolantsystemboronconcentration+~**,
SURVEILLANCE RE UIREMENTS 4.1.2.3.1    The above required charging pump shall be demonstrated OPERABLE by verifying, that  on recirculation flow, the pump develops a discharge pressure of greater  than or equal to 2390 psig when tested pursuant to Specification 4.0.5 at least once per  31 days.
and2)coreoutlettemperature ismaintained atleast010Fbelowsaturation temperature.
+A maximum  of one centrifugal charging pump shall be OPERABLE whenever the temperature of one or more of the RCS cold legs is less than or equal to 152 0 F.
****Forpurposesofthisspecification, additionofwaterfromtheRWSTdoesnotconstitute adilutionactivityprovidedtheboronconcentration intheRWSTisgreaterthanorequaltotheminimumrequiredbyspecification 3.1.2.8.b.2 (MODE4)or3.1.2.7.b.2 (MODE5).D.C.COOK-UNIT13/44-3AMENDMENT NO.
~~For purposes  of this specifi,cation, addition of water from the RWST does not constitute a positive reactivity addition provided the boron concentration in the RWST is greater than the minimum required by Specification 3.1.2.7.b.2.
REACTORCOOLANTSYSTEM34.4.9PRESSURETEMPERATURE LIMITSREACTORCOOLANTSYSTEMLIMITINGCONDITION FOROPERATION 3.4.9.1TheReactorCoolantSystem(exceptthepressurizer) temperature andpressureshallbelimitedinaccordance withthelimitlinesshownonFigures3.4-2and3.4-3duringheatup,cooldown, criticality, andinservice leakandhydrostatic testingwith:a.Amaximumheatupof60Finanyonehourperiod,0b.Amaximumcooldownof100Finanyonehourperiod,and0c.Amaximumtemperature changeof<5Finanyonehourperiod,0duringhydrostatic testingoperations abovesystemdesignpressure.
COOK NUCLEAR PLANT -   UNIT 1            3/4 1-11          AMENDMENT NO.
APPLICABILITY:
 
Atalltimes'ACTION:Withanyoftheabovelimitsexceeded, restorethetemperature and/orpressuretowithinthelimitwithin30minutes;performananalysistodetermine theeffectsoftheout-of-limit condition onthefracturetoughness properties oftheReactorCoolantSystem;determine thattheReactorCoolantSystemremainsacceptable forcontinued operations orbeinatleastHOTSTANDBYwithinthenext6hoursandreducetheRCSTavgandpressuretolessthan200Fand500psig,respectively, withinthefollowing 30hours.*SeeSpecialTextException 3.10.3.COOKNUCLEARPLANT-UNIT13/44-25 onooIC:KM260024002200"REACTORCOOLANTSYSTEMHEATUPLIMITATIONS APPLICABLE FORFIRST32EFFECTIVE FULLPOWERYEARS(MARGINSOF60PSIGAND10FAREINCLUDED'ORPOSSIBLEINSTRUMENT ERROR.)MCOCI.IIICCDCIIIIICCCLCllX6IJJI-CoIIVCOI-XooOoIotljCC200018001600140012001000800600LEAKTESTLIMIT-UNACCEPTABLE OPERATION PRESSURE-TEMPERATURE LIMITFORHEATUPRATESUPTO600F/HR--------CRITICALITY LIMITACCEPTABLE OPERATION IllXoIll'zXo4002000L50100MATERIALPROPERTYBASISINTERMEDIATE PLATE,B4406-3Cu~.15Y,Ni~.49IINITIALRT400F.32EFPYRT1/4T~171F3/4T1360FL.I4004501502002503003500AVERAGEREACTORCOOLANTSYSTEMTEMPERATURE (F)FIGURE3.4-2REACTORCOOLANTSYSTEMPRESSURE-TEMPERATURE LIMITSVERSUS6dF/HRRATECRITICALITY LIMITANDHYDROSTATIC TESTLIMIT OoAooXIM260024002200REACTORCOOLANTSYSTEMCOOLDOWNLIHITATIONS APPLICABLE FORFIRST32EFFECTIVE FULLPOWERYEARS(MARGINS OF60PSIGAND10FAREINCLUDEDFORPOSSIBLEINSTRUMENT ERROR.)200018001600(g)1400I0-z1200o1000oI-oPRESSURE-TEMPERATURE LIMITSUNACCEPTABLE OPERATION ACCEPTABLE OPERATION 600400200COOLDOWNRATEDF/HR%860100HATERIALPROPERTYBASISINTERMEDIATE PLATE,B4406-3Cu.15X,Ni.49%INITIALRT40F32EFPYRT1/4T~171F3/4T~138DFITlKoPl'zI50100150200250300350AVERAGEREACTORCOOLANTSYSTEMTEHPERATURE (F)0FIGURE3.4-3400450KoREACTORCOOLANTSYSTEHPRESSURE-TEMPERATURE LIHITSVERSUSCOOLDOWHRATES REACTORCOOLANTSYSTEMOVERPRESSURE PROTECTION SYSTEMSLIMITINGCONDITION FOROPERATION 3.4.9.3Atleastoneofthefollowing overpressure protection systemsshallbeOPERABLE:
REACTIVITY CONTROL SYSTEMS CHARGING PUMP - SHUTDOWN LIMITING CONDITION    FOR OPERATION 4.1.2.3.2 All charging pumps and safety injection pumps, excluding the above required OPERABLE charging pump, shall be demonstrated inoperable by verifying that the motor circuit breakers have been removed from'heir electrical power supply circuits at least once per 12 hours, except when:
a.Twopoweroperatedreliefvalves(PORVs)withaliftsettingoflessthanor'qualto435psig,orb.Onepoweroperatedreliefvalve(PORV)withaliftsettingoflessthanorequalto435psigandtheRHRsafetyvalvewithaliftsettingoflessthanorequalto450psig,orc.Areactorcoolantsystemventofgreaterthanorequalto2squareinches.APPLICABILITY:
: a. The reactor vessel head is removed, or 0
Whenthetemperature ofoneormoreoftheRCScoldlegsis0lessthanorequalto152F,exceptwhenthereactorvesselheadisremoved.ACTION'ith twoPORV'sinoperable orwithonePORVinoperable andtheRHRsafetyvalveinoperable, eitherrestoretheinoperable PORV(s)orRHRsafetyvalvetoOPERABLEstatuswithin7daysordepressurize andventtheRCSthroughanatleast2squareinchvent(s)withinthenext8hours;maintaintheRCSinaventedcondition untiltheinoperable PORVorRHRsafetyvalvehasbeenrestoredtoOPERABLEstatus.b.WithbothPORVsinoperable, depressurize andventtheRCSthroughanatleast2squareinchvent(s)within8hours;maintaintheRCSinaventedcondition untilbothPORVsoronePORVandtheRHRsafetyvalvehavebeenrestoredtoOPERABLEstatus.IntheeventeitherthePORVs,theRHRsafetyvalveortheRCSvent(s)areusedtomitigateaRCSpressuretransient, aSpecialReportshallbepreparedandsubmitted totheCommission pursuanttoSpecification 6.9.2within30days.Thereportshalldescribethecircumstances initiating thetransient, theeffectofthePORVsorvent(s)onthetransient andanycorrective actionnecessary topreventrecurrence.
: b. The temperature  of all RCS  cold legs is greater than 152 F 4.1.2.3.3 Charging line cross-tie valves to Unit 2 will be cycled      full travel at least once per 18 months. Following cycling, the valves      will be verified to be in their closed positions.
d.Theprovisions ofSpecification 3.0.4arenotapplicable.
COOK NUCLEAR PLANT -   UNIT 1              3/4 1-lla          AMENDMENT NO.
COOKNUCLEARPLANT-UNIT13/44-31AMENDMENT NO.
 
EMERGENCY CORECOOLINGSYSTEMSECCSSUBSYSTEMS
REACTOR COOLANT SYSTEM SHUTDOWN LIMITING CONDITION    FOR OPERATION 3.4.1.3    a. The  coolant loops listed below shall be        OPERABLE and  in operation as required by items b and c:
-Tav(350FLIMITINGCONDITION FOROPERATION 3.5.3Asaminimum,oneECCSsubsystem comprised ofthefollowing shallbeOPERABLE:
: 1. Reactor Coolant Loop    1 and    its associated steam generator and  reactor coolant  pump,~
a.OneOPERABLEcentrifugal chargingpump,&#xb9;b.OneOPERABLEresidualheatremovalheatexchanger, c.OneOPERABLEresidualheatremovalpump,andd.AnOPERABLEflowpathcapableoftakingsuctionfromtherefueling waterstoragetankuponbeingmanuallyrealigned andtransferring suctiontothecontainment sumpduringtherecirculation phaseofoperation.
: 2. Reactor Coolant Loop    2  and  its associated steam generator and  reactor coolant pump,*
APPLICABILITY:
: 3. Reactor Coolant Loop    3  and  its  associated steam generator and  reactor coolant pump,*
MODE4.ACTION:a~WithnoECCSsubsystem OPERABLEbecauseoftheinoperability ofeitherthecentrifugal chargingpumportheflowpathfromtherefueling waterstoragetank,restoreatleastoneECCSsubsystem toOPERABLEstatuswithin1hourorbeinCOLDSHUTDOWNwithinthenext20hours.b.WithnoECCSsubsystem OPERABLEbecauseoftheinoperability ofeithertheresidualheatremovalheatexchanger orresidualheatremovalpump,restoreatleastoneECCSsubsystem toOPERABLE0statusormaintaintheReactorCoolantSystemTavglessthan350Fbyuseofalternate heatremovalmethods.WithmorethanonechargingpumpOPERABLEorwithasafetyinjection pump(s)OPERABLEwhenthetemperature ofanyRCScoldlegislessthanorequalto152F,removetheadditional chargingpump(s)andthesafetyinjection pump(s)motorcircuitbreakersfromtheelectrical powercircuitwithin1hour.d.IntheeventtheECCSisactuatedandinjectswaterintotheReactorCoolantSystem,aSpecialReportshallbepreparedandsubmitted totheCommission pursuanttoSpecification 6.9.2within90daysdescribing thecircumstances oftheactuation andthetotalaccumulated actuation cyclestodate.&#xb9;Amaximumofonecentrifugal chargingpumpshallbeOPERABLEandbothsafetyinjection pumpsshallbeinoperable wheneverthetemperature ofoneormoreoftheRCScoldlegsislessthanorequalto152F.COOKNUCLEARPLANT-UNIT13/45-7AMENDMENT NO.
: 4. Reactor Coolant Loop 4 and      its  associated steam generator and  reactor coolant pump,*
EMERGENCY CORECOOLINGSYSTEMSSURVEILLANCE REUIREMENTS 4.5'.1TheECCSsubsystem shallbedemonstrated OPERABLEpertheapplicable Surveillance Requirements of4.5.2.*4.5.3.2Allchargingpumpsandsafetyinjection pumps,excepttheaboverequiredOPERABLEchargingpump,shallbedemonstrated inoperable, byverifying thatthemotorcircuitbreakershavebeenremovedfromtheirelectrical powersupplycircuits, atleastonceper12hourswheneverthetemgerature ofoneormoreoftheRCScoldlegsislessthanorequalto152Fasdetermined atleastonceperhourwhenanyRCScoldlegtemperature isbetween152Fand200F.*Theprovisions ofSpecification 4.0.6areapplicable.
: 5. Residual Heat Removal    -  East,~~
COOKNUCLEARPLANT-UNIT13/45-8AMENDMENT NO.
: 6. Residual Heat Removal    -  West,*~
34.1REACTIVITY CONTROLSYSTEMSBASES34.1.1.4MODERATOR TEMPERATURE COEFFICIENT MTCContinued concentration associated withfuelburnup.Theconfirmation thatthemeasuredandappropriately compensated MTCvalueiswithintheallowable tolerance ofthepredicted valueprovidesadditional assurances thatthecoefficient willbemaintained withinitslimitsduringintervals betweenmeasurement.
: b. At least two of the above coolant loops shall be OPERABLE and at least one loop in operation      if  the reactor trip breakers are in the open position, or the control rod drive system is not capable of rod withdrawal.~**
34.1.1.5MINIMUMTEMPERATURE FORCRITICALITY Thisspecification ensuresthatthereactorwillnotbemadecritical0withtheReactorCoolantSystemaveragetemperature lessthan541F.Thislimitation isrequiredtoensure1)themoderator temperature coefficient iswithinitsanalyzedtemperature range,2)theprotective instrumentation iswithinitsnormaloperating range,and3)thepressurizer iscapableofbeinginanOPERABLEstatuswithasteambubble,and4)thereactorpressurevesselisaboveitsminimumRTtemperature.
: c. At least three of the above reactor coolant loops shall be OPERABLE and in operation when the reactor trip system breakers are in the closed position and the control rod drive system is capable of rod withdrawal.
Administrative procedures willbeestablished toensuret5eP-12blockedfunctions areunblocked beforetakingthereactorcritical.
APPLICABILITY:     MODES  4 and 5
34.1.2BORATIONSYSTEMSTheboroninjection systemensuresthatnegativereactivity controlisavailable duringeachmodeoffacilityoperation.
+ A reactor coolant pump shall not be started0 with one or more of the RCS cold leg temperatures less than or equal to 152 F unless 1) the pressurizer                !
Thecomponents requiredtoperformthisfunctioninclude1)boratedwatersources,2)chargingpumps,3)separateflowpaths,4)boricacidtransferpumps,5)associated heattracingsystems,and6)anemergency powersupplyfromOPERABLEdieselgenerators.
water volume is less than 62% of span or 2) the secondary            water temperature of each steam generator is less than 50 0 F above each of the RCS cold leg temperatures.       Operability of a reactor coolant loop(s) does not require an OPERABLE auxiliary feedwater system.
WiththeRCSaveragetemperature above200F,aminimumoftwoseparate0andredundant boroninjection systemsareprovidedtoensuresinglefunctional capability intheeventanassumedfailurerendersoneofthesystemsinoperable.
** The  normal or emergency power source      may be    inoperable in  MODE 5.
Allowable out-of-service periodsensurethatminorcomponent repairorcorrective actionmaybecompleted withoutunduerisktooverallfacilitysafetyfrominjection systemfailuresduringtherepairperiod.Thelimitation foramaximumofonecentrifugal chargingpumptobeOPERABLEandtheSurveillance Requirement toverifyallchargingpumpsandsafetyinjection pumgs,excepttherequiredOPERABLEchargingpump,tobeinoperable below152F,unlessthereactorvesselheadisremoved,providesassurance thatamassadditionpressuretransient canberelievedbytheoperation ofasinglePORV.Theborationcapability ofeithersystemissufficient toprovidetherequiredSHUTDOWNMARGINfromalloperating conditions afterxenondecayandcooldownto200F.Themaximumexpectedborationcapability, usablevolume0requirement, is5641gallonsof20,000ppmboratedwaterfromtheboricacid.storagetanksor99,598gallonsof2400ppmboratedwaterfromtherefueling waterstoragetank.Theminimumcontained RWSTvolumeisbasedonECCSconsiderations.
>*> All reactor coolant      pumps and  residual heat removal pumps may be de-energized for up to      1  hour provided 1) no operations are permitted that would cause dilution of the reactor coolant system boron concentration+~**,      and 2) core outlet temperature is maintained at least 0
SeeSectionB3/4.5.5.COOKNUCLEARPLANT-UNIT1B3/41-2AMENDMENT NO.
10 F below saturation temperature.
34.4REACTORCOOLANTSYSTEMBASES34.4.1REACTORCOOLANTLOOPSTheplantisdesignedtooperatewithallreactorcoolantloopsinoperation, andmaintainDNBRabove1.69duringallnormaloperations andanticipated transients.
****For    purposes  of this specification, addition of water from the RWST does  not constitute a dilution activity provided the boron concentration in the RWST is greater than or equal to the minimum required by specification 3.1.2.8.b.2 (MODE 4) or 3.1.2.7.b.2 (MODE 5).
Alossofflowintwoloopswillcauseareactortripifoperating aboveP-7(11percentofRATEDTHERMALPOWER)whilealossoflowinoneloopwillcauseareactortripifoperating aboveP-8(31percentofRATEDTHERMALPOWER).InMODE3,asinglereactorcoolantloopprovidessufficient heatremovalcapability forremovingdecayheat;however,singlefailureconsiderations requirethattwoloopsbeOPERABLE.
D. C. COOK - UNIT 1                      3/4 4-3                        AMENDMENT NO.
ThreeloopsarerequiredtobeOPERABLEandtooperateifthecontrolrodsarecapableofwithdrawal andthereactortripbreakersareclosed.Therequirement assuresadequateDNBRmarginintheeventofanuncontrolled rodwithdrawal inthismode.InMODES4and5,asinglereactorcoolantlooporRHRloopprovidessufficient heatremovalcapabi.lity forremovingdecayheat;butsinglefailureconsiderations requirethatatleasttwoloopsbeOPERABLE.
 
Thus,ifthereactorcoolantloopsarenotOPERABLE, thisspecification requirestwoRHRloopstobeOPERABLE.
REACTOR COOLANT SYSTEM 3  4.4.9  PRESSURE  TEMPERATURE    LIMITS REACTOR COOLANT SYSTEM LIMITING CONDITION    FOR OPERATION 3.4.9.1 The Reactor Coolant System (except the pressurizer) temperature and pressure shall be limited in accordance with the limit lines shown on Figures 3.4-2 and 3.4-3 during heatup, cooldown, criticality, and inservice leak and hydrostatic testing with:
Theoperation ofoneReactorCoolantPumporoneRHRpumpprovidesadequateflowtoensuremixing,preventstratification andproducegradualreactivity changesduringboronconcentration reductions intheReactorCoolantSystem.Thereactivity changerateassociated withboronreduction will,therefore, bewithinthecapability ofoperatorrecognition andcontrol.Therestrictions onstartingaReactorCoolantPumpbelowP-7withoneormoreRCScoldlegslessthanorequalto152FareprovidedtopreventRCSpressuretransients, causedbyenergyadditions fromthesecondary system,whichcouldexceedthelimitsofAppendixGto10CFRPart50.TheRCSwillbeprotected againstoverpressure transients andwillnotexceedthelimitsofAppendixGbyeither(1)restricting thewatervolumeinthepressurizer andtherebyproviding avolumefortheprimarycoolanttoexpandintoor(2)byrestricting startingoftheRCP'stowhenthesecondary watertemperature ofeachsteamgenerator islessthan50FaboveeachoftheRCScoldleg0temperatures.
0
COOKNUCLEARPLANT-UNIT1B3/44-1AMENDMENT NO.
: a. A maximum  heatup  of  60 F in any one hour  period, 0
REACTORCOOLANTSYSTEMBASES34.4.9PRESSURETEMPERATURE LIMITSAllcomponents intheReactorCoolantSystemaredesignedtowithstand theeffectsofcyclicloadsduetosystemtemperature andpressurechanges.Thesecyclicloadsareintroduced bynormalloadtransients, reactortrips,andstartupandshutdownoperations.
: b. A maximum  cooldown  of  100 F in  any one hour period, and
Thevariouscategories ofloadcyclesusedfordesignpurposesareprovidedinSection4.1.4oftheFSAR.Duringstartupandshutdown, theratesoftemperature andpressurechangesarelimitedsothatthemaximumspecified heatupandcooldownratesareconsistent withthedesignassumptions andsatisfythestresslimitsforcyclicoperation.
: c. A maximum  temperature change of < 5 0 F in any one hour period, during hydrostatic testing operations above system design pressure.
AnIDorODone-quarter thickness surfaceflawispostulated atthelocationinthevesselwhichisfoundtobethelimitingcase.Thereareseveralfactorswhichinfluence thepostulated location.
APPLICABILITY:        At all  times' ACTION:
Thethermalinducedbendingstressduringheatupiscompressive ontheinnersurfacewhiletensileontheoutersurfaceofthevesselwall.Duringcooldownthebendingstressprofileisreversed.
With any of the above limits exceeded, restore the temperature and/or pressure to within the limit within 30 minutes; perform an analysis to determine the effects of the out-of-limit condition on the fracture toughness properties of the Reactor Coolant System; determine that the Reactor Coolant System remains acceptable for continued operations or be in at least HOT STANDBY within the next 6 hours and reduce the RCS Tavg and pressure to less than 200 F and 500 psig, respectively, within the following 30 hours.
Inaddition, thematerialtoughness isdependent uponirradiation andtemperature andtherefore thefluenceprofilethroughthereactorvesselwall,therateofheatupandalsotherateofcooldowninfluence thepostulated flawlocation.
* See  Special Text Exception 3.10.3.
Theheatuplimitcurve,Figure3.4-2,isacomposite curvewhichwaspreparedbydetermining themostconservative case,witheithertheinside0oroutsidewallcontrolling, foranyheatuprateupto60Fperhour.ThecooldownlimitcurvesofFigure3.4-3arecomposite curveswhichwerepreparedbaseduponthesametypeanalysiswiththeexception thatthecontrolling locationisalwaystheinsidewallwherethecooldownthermalgradients tendtoproducetensilestresseswhile,producing compressive stressesattheoutsidewall.Theheatupandcooldowncurveswerepreparedbaseduponthemostlimitingvalueofthepredicted adjustedreference temperature attheendof32EFPY.Reactoroperation andresultant fastneutron(E)1Mev)irradiation willcauseanincreaseintheRTN.Therefore, anadjustedreference temperature, baseduponthefluence,andPhecopperandnickelcontentofthematerialmustbepredicted.
COOK NUCLEAR PLANT -    UNIT 1              3/4 4-25
TheheatupandcooldownlimitcurvesofFigures3.4-2and3.4-3includetheadjustedRTattheendof32EFPY,aswellasadjustments forpossibleerrorsinthepressureandtemperature sensinginstruments.
 
COOKNUCLEARPLANT-UNIT1B3/44-6AMENDMENT NO.
o 2600    "
REACTORCOOLANTSYSTEMBASESThe32EFPYheatupandcooldowncurvesweredeveloped basedonthefollowing:
REACTOR COOLANT SYSTEM HEATUP  LIMITATIONS n
1.Theintermediate shellplate,B4406-3,beingthelimitingmaterial'ithacopperandnickelcontentof.15%and.49%respectively.
o o                  APPLICABLE FOR FIRST 32 EFFECTIVE FULL POWER I
2.Thefluencevaluescontained inTable6-14ofWestinghouse's WCAP-12483 report,"Analysis ofCapsuleUFromtheAmericanElectricPowerCompanyD.C.CookUnit1ReactorVesselRadiation Surveillance Program,"
2400      YEARS (MARGINS OF 60 PSIG AND 10 F ARE INCLUDED C:
datedJanuary1990.3.Figure1,NRCRegulatory Guide1.99,Revision2TheshiftinRTNofthereactorvesselmaterialhasbeenestablished byremovingandevaluating thematerialsurveillance capsulesinstalled neartheinsidewallofthereactorvesselinaccordance withtheremovalscheduleinTable4.4-5.Perthisschedule, CapsuleUisthelastcapsuletoberemoveduntilCapsuleSistoberemovedafter32EFPY(EOL).CapsuleV,W,andZwillremaininthereactorvessel,andwillberemovedtoaddressindustryreactorembrittlement
K M                'OR    POSSIBLE INSTRUMENT ERROR.)
: concerns, ifrequired.
2200 M
Thepressure-temperature limitlinesshownonFigure3.4-2forreactorcriticality andforinservice leakandhydrostatic testinghavebeenprovidedtoassurecompliance withtheminimumtemperature requirements ofAppendixGto10CFR50.Thenumberofreactorvesselirradiation surveillance specimens andthefrequencies forremovingandtestingthesespecimens areprovidedinTable4.4-5toassurecompliance withtherequirements ofAppendixHto10CFRPart50.Thelimitations imposedonpressurizer heatupandcooldownandspraywatertemperature differential areprovidedtoassurethatthepressurizer isoperatedwithinthedesigncriteriaassumedforthefatigueanalysisperformed inaccordance withtheASMECoderequirements.
CO CI. 2000 III LEAK TEST LIMIT CC D  1800 CII III CC CL  1600 Cll                                        UNACCEPTABLE X                                                                                              ACCEPTABLE 6    IJJ I-                                    OPERATION                                              OPERATION I
TheOPERABILITY oftwoPORVs,onePORVandtheRHRsafetyvalve,oranRCSventopeningofgreaterthanorequalto2squareinchesensuresthattheRCSwillbeprotected frompressuretransients whichcouldexceedthelimitsofAppendixGto10CFRPart50whenoneormoreoftheRCScoldlegsarelessthanorequalto152F.EitherPORVorRHRsafetyvalvehasadequate0relieving capability toprotecttheRCSfromoverpressurization whenthetransient islimitedtoeither(1)thestartofanidleRCPwiththesecondary 0watertemperature ofthesteamgenerator lessthanorequalto50FabovetheRCScoldlegtemperatures or(2)thestartofachargingpumpanditsinjection intoawatersolidRCS.COOKNUCLEARPLANT-UNIT1B3/44-7AMENDMENT NO.
Co  1400 IV  CO I-X    1200 o
EMERGENCY CORECOOLINGSYSTEMBASESWiththeRCStemperature below350F,oneOPERABLEECCSsubsystem isacceptable withoutsinglefailureconsideration onthebasis6fthestablereactivity condition ofthereactorandthelimitedcorecoolingrequirements.
oO            PRESSURE-TEMPERATURE 1000      LIMIT FOR HEATUP RATES                                    -CRITICALITY I
Thelimitation foramaximumofonecentri.fugal chargingpumptobeOPERABLEandtheSurveillance Requirement toverifyallchargingpumpsandsafetyinjection pumps,excepttherequiredOPERABLEchargingpump,tobeinoperable below152Fprovidesassurance thatamassadditionpressuretransient canberelievedbytheoperation ofasinglePORV.TheSurveillance Requirements providedtoensureOPERABILITY ofeachcomponent ensuresthatataminimum,theassumptions usedinthesafetyanalysesaremetandthatsubsystem OPERABILITY ismaintained.
o            UP TO  600F/HR -                                        LIMIT o    800 tlj CC 600 MATERIAL PROPERTY BASIS INTERMEDIATE PLATE, B4406-3 400                                                                    Cu ~ .15 Y, Ni ~ .49    I INITIAL RT        400F Ill        200                                                                  . 32 EFPY RT      1/4T ~171 F X                                                                                                  3/4T 1360F o
Surveillance requirements forthrottlevalvepositionstopsandflowbalancetestingprovideassurance thatproperECCSflowswillbemaintained intheeventofaLOCA.Maintenance ofproperflowresistance andpressuredropinthepipingsystemtoeachinjection pointisnecessary to:(1)preventtotalpumpflowfromexceeding runoutconditions whenthesystemisinitsminimumresistance configuration, (2)providetheproperflowsplitbetweeninjection pointsinaccordance withtheassumptions usedintheECCS-LOCA
Ill
: analyses, and(3)provideanacceptable leveloftotalECCSflowtoallinjection pointsequaltoorabovethatassumedintheECCS-LOCA analyses.
'z          0 L                                                                        L        .I 50          100        150        200        250        300        350        400        450 X
34.5.4BORONINJECTION SYSTEMTheOPERABILITY oftheboroninjection systemaspartoftheECCSensuresthatsufficient negativereactivity isinjectedintothecoretocounteract anypositiveincreaseinreactivity causedbyRCSsystemcooldown.
o                                                                                    0 AVERAGE REACTOR COOLANT SYSTEM TEMPERATURE  ( F)
RCScooldowncanbecausedbyinadvertent depressurization, aloss-of-coolant accidentorasteamlinerupture.Thelimitsoninjection tankminimumcontained volumeandboronconcentration ensurethattheassumptions usedinthesteamlinebreakanalysisaremet.~TheOPERABILITY oftheredundant heattracingchannelsassociated withtheboroninjection systemensurethatthesolubility oftheboronsolutionwillbemaintained abovethesolubility limitof135Fat21000ppmboron.COOKNUCLEARPLANT-UNIT1B3/45-2AMENDMENT NO.}}
FIGURE 3.4-2 REACTOR COOLANT SYSTEM PRESSURE    TEMPERATURE LIMITS VERSUS 6d F/HR RATE CRITICALITY LIMIT AND HYDROSTATIC TEST LIMIT
 
O o        2600 A                  REACTOR COOLANT SYSTEM COOLDOWN  LIHITATIONS oo                  APPLICABLE FOR FIRST 32 EFFECTIVE FULL POWER X          2400 I                  YEARS(MARGINS OF 60 PSIG AND 10 F ARE INCLUDED M                  FOR POSSIBLE INSTRUMENT ERROR.)
2200 2000 1800 UNACCEPTABLE OPERATION 1600 ACCEPTABLE OPERATION (g) 0-1400 I                PRESSURE-TEMPERATURE LIMITS z  1200 o
1000 o
I-o 600    COOLDOWN RATE DF/HR                                                  HATERIAL PROPERTY BASIS INTERMEDIATE PLATE, B4406-3 400      %8                                                        Cu      .15 X, Ni    .49 %
60                                                        INITIAL RT          40 F 100 200                                                                32 EFPY RT        1/4T ~171 F 3/4T ~138DF ITl 50        100        150        200        250        300          350          400        450 K                                                                                0 o                                AVERAGE REACTOR COOLANT SYSTEM TEHPERATURE  (    F)
Pl
  'z I
FIGURE 3.4-3 K                                                      TEMPERATURE o                    REACTOR COOLANT SYSTEH PRESSURE                LIHITS VERSUS COOLDOWH RATES
 
REACTOR COOLANT SYSTEM OVERPRESSURE  PROTECTION SYSTEMS LIMITING CONDITION  FOR OPERATION 3.4.9.3  At least  one  of the following overpressure protection systems shall be OPERABLE:
: a. Two power    operated  relief valves (PORVs) with a  lift setting  of less than  or'qual to 435 psig, or
: b. One power    operated relief valve (PORV) with a  lift settinga lift of less than or equal to 435 psig and the RHR safety valve with setting of less than or equal to 450 psig, or
: c. A  reactor coolant system vent of greater than or equal to    2  square inches.
APPLICABILITY:       When the temperature of one or more of the RCS cold legs is less than or equal to 152 0 F, except when the reactor vessel head is removed.
ACTION'ith two PORV's inoperable or with one PORV inoperable and the RHR safety valve inoperable, either restore the inoperable PORV(s) or RHR safety valve to OPERABLE status within 7 days or depressurize and vent the RCS through an at least 2 square inch vent(s) within the next 8 hours; maintain the RCS in a vented condition until the inoperable PORV or RHR safety valve has been restored to OPERABLE status.
: b. With both    PORVs inoperable, depressurize and vent the RCS through an  at least  2 square inch vent(s) within 8 hours; maintain the RCS in  a vented condition  until both PORVs or one PORV and the RHR safety valve have been restored to OPERABLE status.
In the event either the PORVs, the RHR safety valve or the RCS vent(s) are used to mitigate a RCS pressure transient, a Special Report shall be prepared and submitted to the Commission pursuant to Specification 6.9.2 within 30 days. The report shall describe the circumstances initiating the transient, the effect of the PORVs or vent(s) on the transient and any corrective action necessary to prevent recurrence.
: d. The  provisions of Specification 3.0.4 are not applicable.
COOK NUCLEAR PLANT    - UNIT 1           3/4 4-31          AMENDMENT NO.
 
EMERGENCY CORE COOLING SYSTEMS ECCS  SUBSYSTEMS    - Tav    ( 350 F LIMITING CONDITION      FOR OPERATION 3.5.3  As a minimum, one ECCS subsystem      comprised  of the following shall  be OPERABLE:
: a. One OPERABLE      centrifugal charging pump,&#xb9;
: b. One OPERABLE      residual heat removal heat exchanger,
: c. One OPERABLE      residual heat removal  pump, and
: d. An OPERABLE    flow path capable of taking suction from the refueling water storage tank upon being manually realigned and transferring suction to the containment sump during the recirculation phase of operation.
APPLICABILITY:      MODE  4.
ACTION:
a  ~  With no    ECCS subsystem OPERABLE because of the inoperability of either the centrifugal charging pump or the flow path from the refueling water storage tank, restore at least one ECCS subsystem to OPERABLE status within 1 hour or be in COLD SHUTDOWN within the next  20  hours.
: b. With no    ECCS subsystem OPERABLE because of the inoperability of either the residual heat removal heat exchanger or residual heat removal pump, restore at least one ECCS subsystem to OPERABLE 0
status or maintain the Reactor Coolant System Tavg less than        350 F by use    of alternate heat removal methods.
With more than one charging      pump OPERABLE  or with a safety injection pump(s) OPERABLE when the temperature of any RCS cold leg is less than or equal to 152 F, remove the additional charging pump(s) and the safety injection pump(s) motor circuit breakers from the electrical power circuit within 1 hour.
: d. In the event the ECCS is actuated and injects water into the Reactor Coolant System, a Special Report shall be prepared and submitted to the Commission pursuant to Specification 6.9.2 within 90 days describing the circumstances of the actuation and the total accumulated actuation cycles to date.
&#xb9;A  maximum  of  one  centrifugal charging  pump  shall be OPERABLE and both safety injection pumps shall be inoperable whenever the temperature of          one or more of the RCS cold legs is less than or equal to 152 F.
COOK NUCLEAR PLANT -       UNIT 1            3/4 5-7            AMENDMENT NO.
 
EMERGENCY CORE COOLING SYSTEMS SURVEILLANCE RE UIREMENTS 4.5 '.1  The ECCS subsystem  shall be demonstrated OPERABLE per the applicable Surveillance Requirements of 4.5.2.*
4.5.3.2 All charging pumps and safety injection pumps, except the above required OPERABLE charging pump, shall be demonstrated inoperable, by verifying that the motor circuit breakers have been removed from their electrical power supply circuits, at least once per 12 hours whenever the temgerature of one or more of the RCS cold legs is less than or equal to 152 F as determined at least once per hour when any RCS cold leg temperature is  between 152 F and 200 F.
* The provisions of Specification 4.0.6 are applicable.
COOK NUCLEAR PLANT -  UNIT 1          3/4 5-8          AMENDMENT NO.
 
3 4.1 REACTIVITY CONTROL    SYSTEMS BASES 3 4.1.1.4  MODERATOR TEMPERATURE COEFFICIENT    MTC  Continued concentration associated with fuel burnup. The confirmation that the measured    and appropriately compensated MTC value is within the allowable tolerance of the predicted value provides additional assurances that the coefficient will be maintained within its limits during intervals between measurement.
3 4.1.1.5  MINIMUM TEMPERATURE FOR CRITICALITY This specification ensures that the reactor will not be made critical with the Reactor Coolant System average temperature less than 541 0 F. This limitation is required to ensure 1) the moderator temperature coefficient is within its analyzed temperature range, 2) the protective instrumentation is within its normal operating range, and 3) the pressurizer is capable of being in an OPERABLE status with a steam bubble, and 4) the reactor pressure vessel is above its minimum RT      temperature. Administrative procedures will be established to ensure t5e P-12 blocked functions are unblocked before taking the reactor critical.
3 4.1.2  BORATION SYSTEMS The boron injection system ensures that negative reactivity control is available during each mode of facility operation. The components required to perform this function include 1) borated water sources,
: 2) charging pumps, 3) separate flow paths, 4) boric acid transfer pumps,
: 5) associated heat tracing systems, and 6) an emergency power supply from OPERABLE diesel generators.
With the RCS average temperature above 200 0 F, a minimum of two separate and redundant boron injection systems are provided to ensure single functional capability in the event an assumed failure renders one of the systems inoperable. Allowable out-of-service periods ensure that minor component repair or corrective action may be completed without undue risk to overall facility safety from injection system failures during the repair period.
The  limitation for a maximum of one centrifugal charging pump to be OPERABLE  and the  Surveillance Requirement to verify all charging pumps and safety injection pumgs, except the required OPERABLE charging pump, to be inoperable below 152 F, unless the reactor vessel head is removed, provides assurance    that a mass addition pressure transient can be relieved by the operation of a single PORV.
The  boration capability of either system is sufficient to provide the required  SHUTDOWN MARGIN from all operating conditions after xenon decay and cooldown to 200 0 F. The maximum expected boration capability, usable volume requirement, is 5641 gallons of 20,000 ppm borated water from the boric acid
.storage tanks or 99,598 gallons of 2400 ppm borated water from the refueling water storage tank. The minimum  contained  RWST volume  is based on ECCS considerations. See Section  B 3/4.5.5.
COOK NUCLEAR PLANT -    UNIT 1            B 3/4 1-2          AMENDMENT NO.
 
3  4.4  REACTOR COOLANT SYSTEM BASES 3  4.4.1    REACTOR COOLANT LOOPS The  plant is designed to operate with    all  reactor coolant loops in operation, and maintain      DNBR  above 1.69 during all normal operations and anticipated transients. A loss of flow in two loops will cause a reactor            trip if  operating above P-7 (11 percent of RATED THERMAL POWER) while a loss          of low in one loop    will  cause a reactor trip    if operating above P-8 (31 percent  of RATED THERMAL POWER).
In  MODE  3, a single reactor coolant loop provides sufficient heat removal    capability for removing decay heat; however, single failure considerations require that two loops be OPERABLE. Three loops are required to be OPERABLE and to operate if the control rods are capable of withdrawal and the    reactor  trip  breakers are closed. The  requirement assures adequate DNBR  margin  in the event of  an uncontrolled rod withdrawal in this  mode.
In  MODES  4 and 5, a  single reactor coolant loop or    RHR loop provides sufficient heat removal capabi.lity for removing decay heat; but single failure considerations require that at least two loops be OPERABLE. Thus, if the reactor coolant loops are not OPERABLE, this specification requires two  RHR  loops to be  OPERABLE.
The  operation of one Reactor Coolant Pump or one RHR pump provides adequate    flow to ensure mixing, prevent stratification and produce gradual reactivity changes during boron concentration reductions in the Reactor Coolant System. The reactivity change rate associated with boron reduction will, therefore, be within the capability of operator recognition and control.
The restrictions on starting a Reactor Coolant Pump below P-7 with one or more RCS cold legs less than or equal to 152 F are provided to prevent RCS pressure transients, caused by energy additions from the secondary system, which could exceed the limits of Appendix G to 10 CFR Part 50. The RCS will be protected against overpressure transients and will not exceed the limits of Appendix G by either (1) restricting the water volume in the pressurizer and thereby providing a volume for the primary coolant to expand into or (2) by restricting starting of the RCP's to 0 when the secondary water temperature of each steam generator is less than 50 F above each of the RCS cold leg temperatures.
COOK NUCLEAR PLANT -    UNIT 1            B  3/4 4-1          AMENDMENT NO.
 
REACTOR COOLANT SYSTEM BASES 3  4.4.9 PRESSURE TEMPERATURE  LIMITS All components in the Reactor Coolant System are designed to withstand the effects of cyclic loads due to system temperature and pressure changes.
These cyclic loads are introduced by normal load transients, reactor trips, and startup and shutdown operations.      The various categories of load cycles used for design purposes are provided in Section 4.1.4 of the FSAR. During startup and shutdown, the rates of temperature and pressure changes are limited so that the maximum specified heatup and cooldown rates are consistent with the design assumptions and satisfy the stress limits for cyclic operation.
An ID or OD one-quarter thickness surface flaw is postulated at the location in the vessel which is found to be the limiting case. There are several factors which influence the postulated location. The thermal induced bending stress during heatup is compressive on the inner surface while tensile on the outer surface of the vessel wall. During cooldown the bending stress profile is reversed. In addition, the material toughness is dependent upon irradiation and temperature and therefore the fluence profile through the reactor vessel wall, the rate of heatup and also the rate of cooldown influence the postulated flaw location.
The heatup limit curve, Figure 3.4-2, is a composite curve which was prepared by determining the most conservative case, with either      the inside or outside wall controlling, for any heatup rate up to 60 0 F per hour. The cooldown limit curves of Figure 3.4-3 are composite curves which were prepared based upon the same type analysis with the exception that the controlling location is always the inside wall where the cooldown thermal gradients tend to produce tensile stresses while, producing compressive stresses at the outside wall. The heatup and cooldown curves were prepared based upon the most limiting value of the predicted adjusted reference temperature at the end of 32 EFPY.
Reactor operation and resultant fast neutron (E    ) 1 Mev) irradiation will cause an increase in the RTN . Therefore, an adjusted reference temperature, based upon the fluence, and Phe copper and nickel content of the material must be predicted. The heatup and cooldown limit curves of Figures 3.4-2 and 3.4-3 include the adjusted RT      at the end of 32 EFPY, as well as adjustments for possible errors in the pressure and temperature sensing instruments.
COOK NUCLEAR PLANT  - UNIT 1          B  3/4 4-6          AMENDMENT NO.
 
REACTOR COOLANT SYSTEM BASES The 32 EFPY heatup and cooldown curves were developed based on the following:
: 1. The intermediate shell plate, B4406-3,    being the  limiting material
          'ith  a  copper and nickel content of  .15% and .49%  respectively.
: 2. The fluence values contained in Table 6-14 of Westinghouse's WCAP-12483 report, "Analysis of Capsule U From the American      Electric Power Company D. C. Cook Unit 1 Reactor Vessel Radiation Surveillance Program," dated January 1990.
: 3. Figure 1,  NRC Regulatory Guide 1.99, Revision  2 The shift in RTN    of the reactor vessel material has been established by removing and evaluating the material surveillance capsules installed near the inside wall of the reactor vessel in accordance with the removal schedule in Table 4.4-5. Per this schedule, Capsule U is the last capsule to be removed until Capsule S is to be removed after 32 EFPY (EOL). Capsule V, W, and Z will remain in the reactor vessel, and will be removed to address industry reactor embrittlement concerns,    if  required.
The pressure-temperature  limit lines shown on Figure 3.4-2 for reactor criticality and for    inservice leak and hydrostatic testing have been provided to assure compliance with the minimum temperature requirements of Appendix G to 10 CFR 50.
The number of reactor vessel irradiation surveillance specimens and the frequencies for removing and testing these specimens are provided in Table 4.4-5 to assure compliance with the requirements of Appendix H to 10 CFR Part 50.
The limitations imposed on pressurizer heatup and cooldown and spray water temperature differential are provided to assure that the pressurizer is operated within the design criteria assumed for the fatigue analysis performed in accordance with the ASME Code requirements.
The OPERABILITY of two PORVs, one PORV and the RHR safety valve, or an RCS  vent opening of greater than or equal to 2 square inches ensures that the RCS will be protected from pressure transients which could exceed the limits of Appendix G to 10 CFR0 Part 50 when one or more of the RCS cold legs are less than or equal to 152 F. Either PORV or RHR safety valve has adequate relieving capability to protect the RCS from overpressurization when the transient is limited to either (1) the start of an idle RCP with the secondary water temperature of the steam generator less than or equal to 50 0 F above the RCS cold leg temperatures    or (2) the start of a charging pump and its injection into a water solid RCS.
COOK NUCLEAR PLANT    - UNIT 1          B 3/4 4-7            AMENDMENT NO.
 
EMERGENCY CORE COOLING SYSTEM BASES With the RCS temperature below 350 F, one OPERABLE ECCS subsystem is acceptable without single failure consideration on the basis 6f the stable reactivity condition of the reactor and the limited core cooling requirements.
The limitation for a maximum of one centri.fugal charging pump to be OPERABLE and the Surveillance Requirement to verify          all  charging pumps and safety injection pumps, except    the  required  OPERABLE  charging    pump, to be inoperable below 152 F    provides  assurance  that  a  mass  addition pressure transient can be    relieved  by  the  operation  of  a  single  PORV.
The Surveillance Requirements provided to ensure OPERABILITY of each component ensures that at a minimum, the assumptions used in the safety analyses are met and that subsystem OPERABILITY is maintained. Surveillance requirements for throttle valve position stops and flow balance testing provide assurance that proper ECCS flows          will  be maintained in the event of a LOCA. Maintenance  of proper  flow  resistance    and pressure drop in the piping system to each injection point is necessary to: (1) prevent total pump flow from exceeding runout conditions when the system is in its minimum resistance configuration, (2) provide the proper flow split between injection points in accordance with the assumptions used in the ECCS-LOCA analyses, and (3) provide an acceptable level of total ECCS flow to all injection points equal to or above that assumed in the ECCS-LOCA analyses.
3 4.5.4 BORON  INJECTION SYSTEM The OPERABILITY    of the boron injection system as part of the ECCS ensures that sufficient negative reactivity is injected into the core to counteract any positive increase in reactivity caused by RCS system cooldown. RCS cooldown can be caused by inadvertent depressurization, a loss-of-coolant accident or a steam line rupture.
The  limits on  injection tank minimum contained volume          and boron concentration ensure that the assumptions used in the            steam line break analysis are met.
The OPERABILITY  of the redundant heat tracing channels associated with the boron injection system ensure that the solubility of the boron solution will
~
be maintained above the solubility limit of 135 F at 21000 ppm boron.
COOK NUCLEAR PLANT    - UNIT 1              B 3/4 5-2              AMENDMENT NO.}}

Latest revision as of 06:03, 29 October 2019

Proposed Tech Specs Re Limiting Condition for Operation & Surveillance Requirements Re Charging Pump - Shutdown & Pressure/Temp Limits for RCS
ML17328A753
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Site: Cook American Electric Power icon.png
Issue date: 10/29/1990
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INDIANA MICHIGAN POWER CO. (FORMERLY INDIANA & MICHIG
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ATTACHMENT 2 TO AEP:NRC:08940 PROPOSED REVISED TECHNICAL SPECIFICATION PAGES 90ii020047 050003i5 90i029'DR ADOCK P PNU

. ~ 4 REACTIVITY CONTROL SYSTEMS CHARGING PUMP - SHUTDOWN LIMITING CONDITION FOR OPERATION 3.1.2.3

a. One charging pump in the boron injection flow path required by Specification 3.1.2.1 shall be OPERABLE and capable of being powered from an OPERABLE emergency bus.
b. One charging flowpath associated with support of Unit 2 shutdown functions shall be available.

APPLICABILITY: Specification 3.1.2.3.a. - MODES 5 and 6 Specification 3.1.2.3.b. - At all times when Unit 2 is in MODES 1, 2, 3, or 4.

ACTION'.

With no charging pump OPERABLE, suspend all operations involving CORE ALTERATIONS or posi.tive reactivity changes.**

b. With more than one charging pump OPERABLE or with a safety injection pump(s) OPERABLE0 when the temperature of any RCS cold leg is less than or equal to 152 F, unless the reactor vessel head is removed, remove the additional charging pump(s) and the safety injection pump(s) motor circuit breakers from the electrical power circuit within one hour.
c. The provisions of Specification 3.0.3 are not applicable.

In addition to the above, when Specification 3.1.2.3.b is applicable and the required flow path is not available, return the required flow path to available status within 7 days, or provide equivalent shutdown capability in Unit 2 and return the required flow path to available status within the next 60 days, or have Unit 2 in HOT STANDBY within the next 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> and HOT SHUTDOWN within the following 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />.

e. The requirements of Specification 3.0.4 are not applicable when Specification 3.1.2.3.b applies.

SURVEILLANCE RE UIREMENTS 4.1.2.3.1 The above required charging pump shall be demonstrated OPERABLE by verifying, that on recirculation flow, the pump develops a discharge pressure of greater than or equal to 2390 psig when tested pursuant to Specification 4.0.5 at least once per 31 days.

+A maximum of one centrifugal charging pump shall be OPERABLE whenever the temperature of one or more of the RCS cold legs is less than or equal to 152 0 F.

~~For purposes of this specifi,cation, addition of water from the RWST does not constitute a positive reactivity addition provided the boron concentration in the RWST is greater than the minimum required by Specification 3.1.2.7.b.2.

COOK NUCLEAR PLANT - UNIT 1 3/4 1-11 AMENDMENT NO.

REACTIVITY CONTROL SYSTEMS CHARGING PUMP - SHUTDOWN LIMITING CONDITION FOR OPERATION 4.1.2.3.2 All charging pumps and safety injection pumps, excluding the above required OPERABLE charging pump, shall be demonstrated inoperable by verifying that the motor circuit breakers have been removed from'heir electrical power supply circuits at least once per 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />, except when:

a. The reactor vessel head is removed, or 0
b. The temperature of all RCS cold legs is greater than 152 F 4.1.2.3.3 Charging line cross-tie valves to Unit 2 will be cycled full travel at least once per 18 months. Following cycling, the valves will be verified to be in their closed positions.

COOK NUCLEAR PLANT - UNIT 1 3/4 1-lla AMENDMENT NO.

REACTOR COOLANT SYSTEM SHUTDOWN LIMITING CONDITION FOR OPERATION 3.4.1.3 a. The coolant loops listed below shall be OPERABLE and in operation as required by items b and c:

1. Reactor Coolant Loop 1 and its associated steam generator and reactor coolant pump,~
2. Reactor Coolant Loop 2 and its associated steam generator and reactor coolant pump,*
3. Reactor Coolant Loop 3 and its associated steam generator and reactor coolant pump,*
4. Reactor Coolant Loop 4 and its associated steam generator and reactor coolant pump,*
5. Residual Heat Removal - East,~~
6. Residual Heat Removal - West,*~
b. At least two of the above coolant loops shall be OPERABLE and at least one loop in operation if the reactor trip breakers are in the open position, or the control rod drive system is not capable of rod withdrawal.~**
c. At least three of the above reactor coolant loops shall be OPERABLE and in operation when the reactor trip system breakers are in the closed position and the control rod drive system is capable of rod withdrawal.

APPLICABILITY: MODES 4 and 5

+ A reactor coolant pump shall not be started0 with one or more of the RCS cold leg temperatures less than or equal to 152 F unless 1) the pressurizer  !

water volume is less than 62% of span or 2) the secondary water temperature of each steam generator is less than 50 0 F above each of the RCS cold leg temperatures. Operability of a reactor coolant loop(s) does not require an OPERABLE auxiliary feedwater system.

    • The normal or emergency power source may be inoperable in MODE 5.

>*> All reactor coolant pumps and residual heat removal pumps may be de-energized for up to 1 hour provided 1) no operations are permitted that would cause dilution of the reactor coolant system boron concentration+~**, and 2) core outlet temperature is maintained at least 0

10 F below saturation temperature.

        • For purposes of this specification, addition of water from the RWST does not constitute a dilution activity provided the boron concentration in the RWST is greater than or equal to the minimum required by specification 3.1.2.8.b.2 (MODE 4) or 3.1.2.7.b.2 (MODE 5).

D. C. COOK - UNIT 1 3/4 4-3 AMENDMENT NO.

REACTOR COOLANT SYSTEM 3 4.4.9 PRESSURE TEMPERATURE LIMITS REACTOR COOLANT SYSTEM LIMITING CONDITION FOR OPERATION 3.4.9.1 The Reactor Coolant System (except the pressurizer) temperature and pressure shall be limited in accordance with the limit lines shown on Figures 3.4-2 and 3.4-3 during heatup, cooldown, criticality, and inservice leak and hydrostatic testing with:

0

a. A maximum heatup of 60 F in any one hour period, 0
b. A maximum cooldown of 100 F in any one hour period, and
c. A maximum temperature change of < 5 0 F in any one hour period, during hydrostatic testing operations above system design pressure.

APPLICABILITY: At all times' ACTION:

With any of the above limits exceeded, restore the temperature and/or pressure to within the limit within 30 minutes; perform an analysis to determine the effects of the out-of-limit condition on the fracture toughness properties of the Reactor Coolant System; determine that the Reactor Coolant System remains acceptable for continued operations or be in at least HOT STANDBY within the next 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and reduce the RCS Tavg and pressure to less than 200 F and 500 psig, respectively, within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />.

  • See Special Text Exception 3.10.3.

COOK NUCLEAR PLANT - UNIT 1 3/4 4-25

o 2600 "

REACTOR COOLANT SYSTEM HEATUP LIMITATIONS n

o o APPLICABLE FOR FIRST 32 EFFECTIVE FULL POWER I

2400 YEARS (MARGINS OF 60 PSIG AND 10 F ARE INCLUDED C:

K M 'OR POSSIBLE INSTRUMENT ERROR.)

2200 M

CO CI. 2000 III LEAK TEST LIMIT CC D 1800 CII III CC CL 1600 Cll UNACCEPTABLE X ACCEPTABLE 6 IJJ I- OPERATION OPERATION I

Co 1400 IV CO I-X 1200 o

oO PRESSURE-TEMPERATURE 1000 LIMIT FOR HEATUP RATES -CRITICALITY I

o UP TO 600F/HR - LIMIT o 800 tlj CC 600 MATERIAL PROPERTY BASIS INTERMEDIATE PLATE, B4406-3 400 Cu ~ .15 Y, Ni ~ .49 I INITIAL RT 400F Ill 200 . 32 EFPY RT 1/4T ~171 F X 3/4T 1360F o

Ill

'z 0 L L .I 50 100 150 200 250 300 350 400 450 X

o 0 AVERAGE REACTOR COOLANT SYSTEM TEMPERATURE ( F)

FIGURE 3.4-2 REACTOR COOLANT SYSTEM PRESSURE TEMPERATURE LIMITS VERSUS 6d F/HR RATE CRITICALITY LIMIT AND HYDROSTATIC TEST LIMIT

O o 2600 A REACTOR COOLANT SYSTEM COOLDOWN LIHITATIONS oo APPLICABLE FOR FIRST 32 EFFECTIVE FULL POWER X 2400 I YEARS(MARGINS OF 60 PSIG AND 10 F ARE INCLUDED M FOR POSSIBLE INSTRUMENT ERROR.)

2200 2000 1800 UNACCEPTABLE OPERATION 1600 ACCEPTABLE OPERATION (g) 0-1400 I PRESSURE-TEMPERATURE LIMITS z 1200 o

1000 o

I-o 600 COOLDOWN RATE DF/HR HATERIAL PROPERTY BASIS INTERMEDIATE PLATE, B4406-3 400 %8 Cu .15 X, Ni .49 %

60 INITIAL RT 40 F 100 200 32 EFPY RT 1/4T ~171 F 3/4T ~138DF ITl 50 100 150 200 250 300 350 400 450 K 0 o AVERAGE REACTOR COOLANT SYSTEM TEHPERATURE ( F)

Pl

'z I

FIGURE 3.4-3 K TEMPERATURE o REACTOR COOLANT SYSTEH PRESSURE LIHITS VERSUS COOLDOWH RATES

REACTOR COOLANT SYSTEM OVERPRESSURE PROTECTION SYSTEMS LIMITING CONDITION FOR OPERATION 3.4.9.3 At least one of the following overpressure protection systems shall be OPERABLE:

a. Two power operated relief valves (PORVs) with a lift setting of less than or'qual to 435 psig, or
b. One power operated relief valve (PORV) with a lift settinga lift of less than or equal to 435 psig and the RHR safety valve with setting of less than or equal to 450 psig, or
c. A reactor coolant system vent of greater than or equal to 2 square inches.

APPLICABILITY: When the temperature of one or more of the RCS cold legs is less than or equal to 152 0 F, except when the reactor vessel head is removed.

ACTION'ith two PORV's inoperable or with one PORV inoperable and the RHR safety valve inoperable, either restore the inoperable PORV(s) or RHR safety valve to OPERABLE status within 7 days or depressurize and vent the RCS through an at least 2 square inch vent(s) within the next 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br />; maintain the RCS in a vented condition until the inoperable PORV or RHR safety valve has been restored to OPERABLE status.

b. With both PORVs inoperable, depressurize and vent the RCS through an at least 2 square inch vent(s) within 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br />; maintain the RCS in a vented condition until both PORVs or one PORV and the RHR safety valve have been restored to OPERABLE status.

In the event either the PORVs, the RHR safety valve or the RCS vent(s) are used to mitigate a RCS pressure transient, a Special Report shall be prepared and submitted to the Commission pursuant to Specification 6.9.2 within 30 days. The report shall describe the circumstances initiating the transient, the effect of the PORVs or vent(s) on the transient and any corrective action necessary to prevent recurrence.

d. The provisions of Specification 3.0.4 are not applicable.

COOK NUCLEAR PLANT - UNIT 1 3/4 4-31 AMENDMENT NO.

EMERGENCY CORE COOLING SYSTEMS ECCS SUBSYSTEMS - Tav ( 350 F LIMITING CONDITION FOR OPERATION 3.5.3 As a minimum, one ECCS subsystem comprised of the following shall be OPERABLE:

a. One OPERABLE centrifugal charging pump,¹
b. One OPERABLE residual heat removal heat exchanger,
c. One OPERABLE residual heat removal pump, and
d. An OPERABLE flow path capable of taking suction from the refueling water storage tank upon being manually realigned and transferring suction to the containment sump during the recirculation phase of operation.

APPLICABILITY: MODE 4.

ACTION:

a ~ With no ECCS subsystem OPERABLE because of the inoperability of either the centrifugal charging pump or the flow path from the refueling water storage tank, restore at least one ECCS subsystem to OPERABLE status within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> or be in COLD SHUTDOWN within the next 20 hours.

b. With no ECCS subsystem OPERABLE because of the inoperability of either the residual heat removal heat exchanger or residual heat removal pump, restore at least one ECCS subsystem to OPERABLE 0

status or maintain the Reactor Coolant System Tavg less than 350 F by use of alternate heat removal methods.

With more than one charging pump OPERABLE or with a safety injection pump(s) OPERABLE when the temperature of any RCS cold leg is less than or equal to 152 F, remove the additional charging pump(s) and the safety injection pump(s) motor circuit breakers from the electrical power circuit within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />.

d. In the event the ECCS is actuated and injects water into the Reactor Coolant System, a Special Report shall be prepared and submitted to the Commission pursuant to Specification 6.9.2 within 90 days describing the circumstances of the actuation and the total accumulated actuation cycles to date.

¹A maximum of one centrifugal charging pump shall be OPERABLE and both safety injection pumps shall be inoperable whenever the temperature of one or more of the RCS cold legs is less than or equal to 152 F.

COOK NUCLEAR PLANT - UNIT 1 3/4 5-7 AMENDMENT NO.

EMERGENCY CORE COOLING SYSTEMS SURVEILLANCE RE UIREMENTS 4.5 '.1 The ECCS subsystem shall be demonstrated OPERABLE per the applicable Surveillance Requirements of 4.5.2.*

4.5.3.2 All charging pumps and safety injection pumps, except the above required OPERABLE charging pump, shall be demonstrated inoperable, by verifying that the motor circuit breakers have been removed from their electrical power supply circuits, at least once per 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> whenever the temgerature of one or more of the RCS cold legs is less than or equal to 152 F as determined at least once per hour when any RCS cold leg temperature is between 152 F and 200 F.

  • The provisions of Specification 4.0.6 are applicable.

COOK NUCLEAR PLANT - UNIT 1 3/4 5-8 AMENDMENT NO.

3 4.1 REACTIVITY CONTROL SYSTEMS BASES 3 4.1.1.4 MODERATOR TEMPERATURE COEFFICIENT MTC Continued concentration associated with fuel burnup. The confirmation that the measured and appropriately compensated MTC value is within the allowable tolerance of the predicted value provides additional assurances that the coefficient will be maintained within its limits during intervals between measurement.

3 4.1.1.5 MINIMUM TEMPERATURE FOR CRITICALITY This specification ensures that the reactor will not be made critical with the Reactor Coolant System average temperature less than 541 0 F. This limitation is required to ensure 1) the moderator temperature coefficient is within its analyzed temperature range, 2) the protective instrumentation is within its normal operating range, and 3) the pressurizer is capable of being in an OPERABLE status with a steam bubble, and 4) the reactor pressure vessel is above its minimum RT temperature. Administrative procedures will be established to ensure t5e P-12 blocked functions are unblocked before taking the reactor critical.

3 4.1.2 BORATION SYSTEMS The boron injection system ensures that negative reactivity control is available during each mode of facility operation. The components required to perform this function include 1) borated water sources,

2) charging pumps, 3) separate flow paths, 4) boric acid transfer pumps,
5) associated heat tracing systems, and 6) an emergency power supply from OPERABLE diesel generators.

With the RCS average temperature above 200 0 F, a minimum of two separate and redundant boron injection systems are provided to ensure single functional capability in the event an assumed failure renders one of the systems inoperable. Allowable out-of-service periods ensure that minor component repair or corrective action may be completed without undue risk to overall facility safety from injection system failures during the repair period.

The limitation for a maximum of one centrifugal charging pump to be OPERABLE and the Surveillance Requirement to verify all charging pumps and safety injection pumgs, except the required OPERABLE charging pump, to be inoperable below 152 F, unless the reactor vessel head is removed, provides assurance that a mass addition pressure transient can be relieved by the operation of a single PORV.

The boration capability of either system is sufficient to provide the required SHUTDOWN MARGIN from all operating conditions after xenon decay and cooldown to 200 0 F. The maximum expected boration capability, usable volume requirement, is 5641 gallons of 20,000 ppm borated water from the boric acid

.storage tanks or 99,598 gallons of 2400 ppm borated water from the refueling water storage tank. The minimum contained RWST volume is based on ECCS considerations. See Section B 3/4.5.5.

COOK NUCLEAR PLANT - UNIT 1 B 3/4 1-2 AMENDMENT NO.

3 4.4 REACTOR COOLANT SYSTEM BASES 3 4.4.1 REACTOR COOLANT LOOPS The plant is designed to operate with all reactor coolant loops in operation, and maintain DNBR above 1.69 during all normal operations and anticipated transients. A loss of flow in two loops will cause a reactor trip if operating above P-7 (11 percent of RATED THERMAL POWER) while a loss of low in one loop will cause a reactor trip if operating above P-8 (31 percent of RATED THERMAL POWER).

In MODE 3, a single reactor coolant loop provides sufficient heat removal capability for removing decay heat; however, single failure considerations require that two loops be OPERABLE. Three loops are required to be OPERABLE and to operate if the control rods are capable of withdrawal and the reactor trip breakers are closed. The requirement assures adequate DNBR margin in the event of an uncontrolled rod withdrawal in this mode.

In MODES 4 and 5, a single reactor coolant loop or RHR loop provides sufficient heat removal capabi.lity for removing decay heat; but single failure considerations require that at least two loops be OPERABLE. Thus, if the reactor coolant loops are not OPERABLE, this specification requires two RHR loops to be OPERABLE.

The operation of one Reactor Coolant Pump or one RHR pump provides adequate flow to ensure mixing, prevent stratification and produce gradual reactivity changes during boron concentration reductions in the Reactor Coolant System. The reactivity change rate associated with boron reduction will, therefore, be within the capability of operator recognition and control.

The restrictions on starting a Reactor Coolant Pump below P-7 with one or more RCS cold legs less than or equal to 152 F are provided to prevent RCS pressure transients, caused by energy additions from the secondary system, which could exceed the limits of Appendix G to 10 CFR Part 50. The RCS will be protected against overpressure transients and will not exceed the limits of Appendix G by either (1) restricting the water volume in the pressurizer and thereby providing a volume for the primary coolant to expand into or (2) by restricting starting of the RCP's to 0 when the secondary water temperature of each steam generator is less than 50 F above each of the RCS cold leg temperatures.

COOK NUCLEAR PLANT - UNIT 1 B 3/4 4-1 AMENDMENT NO.

REACTOR COOLANT SYSTEM BASES 3 4.4.9 PRESSURE TEMPERATURE LIMITS All components in the Reactor Coolant System are designed to withstand the effects of cyclic loads due to system temperature and pressure changes.

These cyclic loads are introduced by normal load transients, reactor trips, and startup and shutdown operations. The various categories of load cycles used for design purposes are provided in Section 4.1.4 of the FSAR. During startup and shutdown, the rates of temperature and pressure changes are limited so that the maximum specified heatup and cooldown rates are consistent with the design assumptions and satisfy the stress limits for cyclic operation.

An ID or OD one-quarter thickness surface flaw is postulated at the location in the vessel which is found to be the limiting case. There are several factors which influence the postulated location. The thermal induced bending stress during heatup is compressive on the inner surface while tensile on the outer surface of the vessel wall. During cooldown the bending stress profile is reversed. In addition, the material toughness is dependent upon irradiation and temperature and therefore the fluence profile through the reactor vessel wall, the rate of heatup and also the rate of cooldown influence the postulated flaw location.

The heatup limit curve, Figure 3.4-2, is a composite curve which was prepared by determining the most conservative case, with either the inside or outside wall controlling, for any heatup rate up to 60 0 F per hour. The cooldown limit curves of Figure 3.4-3 are composite curves which were prepared based upon the same type analysis with the exception that the controlling location is always the inside wall where the cooldown thermal gradients tend to produce tensile stresses while, producing compressive stresses at the outside wall. The heatup and cooldown curves were prepared based upon the most limiting value of the predicted adjusted reference temperature at the end of 32 EFPY.

Reactor operation and resultant fast neutron (E ) 1 Mev) irradiation will cause an increase in the RTN . Therefore, an adjusted reference temperature, based upon the fluence, and Phe copper and nickel content of the material must be predicted. The heatup and cooldown limit curves of Figures 3.4-2 and 3.4-3 include the adjusted RT at the end of 32 EFPY, as well as adjustments for possible errors in the pressure and temperature sensing instruments.

COOK NUCLEAR PLANT - UNIT 1 B 3/4 4-6 AMENDMENT NO.

REACTOR COOLANT SYSTEM BASES The 32 EFPY heatup and cooldown curves were developed based on the following:

1. The intermediate shell plate, B4406-3, being the limiting material

'ith a copper and nickel content of .15% and .49% respectively.

2. The fluence values contained in Table 6-14 of Westinghouse's WCAP-12483 report, "Analysis of Capsule U From the American Electric Power Company D. C. Cook Unit 1 Reactor Vessel Radiation Surveillance Program," dated January 1990.
3. Figure 1, NRC Regulatory Guide 1.99, Revision 2 The shift in RTN of the reactor vessel material has been established by removing and evaluating the material surveillance capsules installed near the inside wall of the reactor vessel in accordance with the removal schedule in Table 4.4-5. Per this schedule, Capsule U is the last capsule to be removed until Capsule S is to be removed after 32 EFPY (EOL). Capsule V, W, and Z will remain in the reactor vessel, and will be removed to address industry reactor embrittlement concerns, if required.

The pressure-temperature limit lines shown on Figure 3.4-2 for reactor criticality and for inservice leak and hydrostatic testing have been provided to assure compliance with the minimum temperature requirements of Appendix G to 10 CFR 50.

The number of reactor vessel irradiation surveillance specimens and the frequencies for removing and testing these specimens are provided in Table 4.4-5 to assure compliance with the requirements of Appendix H to 10 CFR Part 50.

The limitations imposed on pressurizer heatup and cooldown and spray water temperature differential are provided to assure that the pressurizer is operated within the design criteria assumed for the fatigue analysis performed in accordance with the ASME Code requirements.

The OPERABILITY of two PORVs, one PORV and the RHR safety valve, or an RCS vent opening of greater than or equal to 2 square inches ensures that the RCS will be protected from pressure transients which could exceed the limits of Appendix G to 10 CFR0 Part 50 when one or more of the RCS cold legs are less than or equal to 152 F. Either PORV or RHR safety valve has adequate relieving capability to protect the RCS from overpressurization when the transient is limited to either (1) the start of an idle RCP with the secondary water temperature of the steam generator less than or equal to 50 0 F above the RCS cold leg temperatures or (2) the start of a charging pump and its injection into a water solid RCS.

COOK NUCLEAR PLANT - UNIT 1 B 3/4 4-7 AMENDMENT NO.

EMERGENCY CORE COOLING SYSTEM BASES With the RCS temperature below 350 F, one OPERABLE ECCS subsystem is acceptable without single failure consideration on the basis 6f the stable reactivity condition of the reactor and the limited core cooling requirements.

The limitation for a maximum of one centri.fugal charging pump to be OPERABLE and the Surveillance Requirement to verify all charging pumps and safety injection pumps, except the required OPERABLE charging pump, to be inoperable below 152 F provides assurance that a mass addition pressure transient can be relieved by the operation of a single PORV.

The Surveillance Requirements provided to ensure OPERABILITY of each component ensures that at a minimum, the assumptions used in the safety analyses are met and that subsystem OPERABILITY is maintained. Surveillance requirements for throttle valve position stops and flow balance testing provide assurance that proper ECCS flows will be maintained in the event of a LOCA. Maintenance of proper flow resistance and pressure drop in the piping system to each injection point is necessary to: (1) prevent total pump flow from exceeding runout conditions when the system is in its minimum resistance configuration, (2) provide the proper flow split between injection points in accordance with the assumptions used in the ECCS-LOCA analyses, and (3) provide an acceptable level of total ECCS flow to all injection points equal to or above that assumed in the ECCS-LOCA analyses.

3 4.5.4 BORON INJECTION SYSTEM The OPERABILITY of the boron injection system as part of the ECCS ensures that sufficient negative reactivity is injected into the core to counteract any positive increase in reactivity caused by RCS system cooldown. RCS cooldown can be caused by inadvertent depressurization, a loss-of-coolant accident or a steam line rupture.

The limits on injection tank minimum contained volume and boron concentration ensure that the assumptions used in the steam line break analysis are met.

The OPERABILITY of the redundant heat tracing channels associated with the boron injection system ensure that the solubility of the boron solution will

~

be maintained above the solubility limit of 135 F at 21000 ppm boron.

COOK NUCLEAR PLANT - UNIT 1 B 3/4 5-2 AMENDMENT NO.

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