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{{#Wiki_filter:ATTACHMENT NO.2TOAEP:NRC:0856A DONALDC.COOKNUCLEARPLANTUNITNOS.1AND2PROPOSEDTECHNICAL SPECIFICATIONS eoR84o'719ADOCggg'Ppp~~g t,''DR~~.;
{{#Wiki_filter:ATTACHMENT NO. 2 TO AEP:NRC:0856A DONALD C. COOK NUCLEAR PLANT UNIT NOS. 1 AND 2 PROPOSED    TECHNICAL SPECIFICATIONS 84o'71 9 eoR ADOCg gg'Ppp~~g   t,
ADMINISTRATIVE CONTROLS6.8.3a0Temporary changestoprocedures of6.8.1abovemaybemadeprovided:
                ''DR ~~.;
Theintentoftheoriginalprocedure isnotaltered.b.Thechangeisapprovedbytwomembersoftheplantmanagement staff,atleastoneofwhomholdsaSeniorReactorOperator's Licenseontheunitaffected.
 
C~Thechangeisdocumented, reviewedbythePNSRCandapprovedbythePlantManagerwithin14daysofimplementation.
ADMINISTRATIVE CONTROLS 6.8.3    Temporary changes  to procedures of 6.8.1  above may be made provided:
6.8.4Plantprocedures forpost-accident samplingshallbeestablished, implemented, andmaintained whichwillensurethecapability toobtainandanalyzereactorcoolantandcontainment atmosphere samplesandradioactive iodinesandparticulate samplesinplantgaseouseffluents underaccidentconditions.
a0  The  intent of the original procedure is not altered.
Theprogramwillincludethefollowing:
: b. The change  is approved by two members  of the plant  management staff, at least  one  of whom holds a Senior Reactor Operator's License on  the unit affected.
a~Trainingofpersonnel, b.Procedures forsamplingandanalysis, c~Provisions formaintenance ofsamplingandanalysisequipment.
C ~ The change is documented, reviewed by the PNSRC and approved by the Plant Manager within 14 days of implementation.
D.C.COOK-UNIT16-14Amendment No.
6.8.4    Plant procedures for post-accident sampling shall be established, implemented, and maintained which will ensure the capability to obtain and analyze reactor coolant and containment atmosphere samples and radioactive iodines and particulate samples in plant gaseous effluents under accident conditions. The program will include the following:
6.9REPORTING REUIREMENTS ROUTINEREPORTSANDREPORTABLE OCCURRENCES 6.9.1Inadditiontotheapplicable reporting requirements ofTitle10,CodeofFederalRegulations, thefollowing reportsshallbesub-mittedtotheDirectoroftheRegionalOfficeofInspection andEnforcement unlessotherwise noted.STARTUPREPORT6.9.1.1Asummaryreportofplantstartupandpowerescalation testingshallbesubmitted following (1)receiptofanoperating license,(2)amendment tothelicenseinvolving aplannedincreaseinpowerlevel,(3)installation offuelthathasadifferent designorhasbeenmanufactured byadifferent fuelsupplier, and(4)modifications thatmayhavesignificantly alteredthenuclear,thermal,orhydraulic performance oftheplant.6.9.1.2Thestartupreportshalladdresseachofthetestsidentified intheFSARandshallincludeadescription ofthemeasuredvaluesoftheoperating conditions orcharacteristics obtainedduringthetestprogramandacomparison ofthesevalueswithdesignpredictions andspecifications.
a ~ Training of personnel,
Anycorrective actionsthatwererequiredtoobtainsatisfactory operation shallalsobedescribed.
: b. Procedures for sampling and analysis, c~ Provisions for maintenance of sampling and analysis equipment.
Anyadditional specificdetailsrequiredinlicenseconditions basedonothercommitments shallbeincludedinthisreport.D.C.COOK-UNIT16-14aAmendment No.
D. C. COOK UNIT 1                    6-14                  Amendment No.
ADMINISTRATIVE CONTROLS6.8.3Temporary changestoprocedures of6.8.1abovemaybemadeprovided:
: 6. 9  REPORTING RE UIREMENTS ROUTINE REPORTS AND REPORTABLE OCCURRENCES 6.9.1      In addition to the applicable reporting requirements of Title 10, Code of Federal Regulations, the following reports shall be sub-mitted to the Director of the Regional Office of Inspection and Enforcement unless otherwise noted.
a.Theintentoftheoriginalprocedure isnotaltered.b.Thechangeisapprovedbytwomembersoftheplantmanagement staff,atleastoneofwhomholdsaSeniorReactorOperator's Licenseontheunitaffected.
STARTUP REPORT 6.9.1.1    A summary  report of plant startup and power escalation testing shall  be submitted  following (1) receipt of an operating license, (2) amendment to the license involving a planned increase in power level, (3) installation of fuel that has a different design or has been manufactured by a different fuel supplier, and (4) modifications that may have significantly altered the nuclear, thermal, or hydraulic performance of the plant.
ceThechangeisdocumented, reviewedbythePNSRCandapprovedbythePlantManagerwithin14daysofimplementation.
6.9.1.2    The  startup report shall address each of the tests identified in the FSAR and shall include a description of the measured values of the operating conditions or characteristics obtained during the test program and a comparison of these values with design predictions and specifications. Any corrective actions that were required to obtain satisfactory operation shall also be described. Any additional specific details required in license conditions based on other commitments shall be included in this report.
6.8.4Plantprocedures forpost-accident samplingshallbeestablished, implemented, andmaintained whichwillensurethecapability toobtainandanalyzereactorcoolantandcontainment atmosphere samplesandradioactive iodinesandparticulate samplesinplantgaseouseffluents underaccidentconditions.
D. C. COOK UNIT 1                      6-14a                Amendment No.
Theprogramwill-includethefollowing:
 
a~b.c~Trainingofpersonnel, Procedures forsamplingandanalysis, Provision formaintenance ofsamplingandanalysisequipment.
ADMINISTRATIVE CONTROLS 6.8.3    Temporary changes  to procedures of 6.8.1    above may be made provided:
D.C.COOK-UNIT26-14Amendment No.
: a. The intent of the original procedure is not altered.
6.9REPORTING REUIREMENTS ROUTINEREPORTSANDREPORTABLE OCCURRENCES 6.9.1Inadditiontotheapplicable reporting requirements ofTitle10,CodeofFederalRegulations, thefollowing reportsshallbesubmitted totheDirectoroftheRegionalOfficeofInspection andEnforcement unlessotherwise noted.STARTUPREPORT6.9.1.1Asummaryreportofplantstartupandpowerescalation testingshallbesubmitted following (1)receiptofanoperating license,(2)amendment tothelicenseinvolving aplannedincreaseinpowerlevel,(3)installation offuelthathasadifferent designorhasbeenmanufactured byadifferent fuelsupplier, and(4)modifications thatmayhavesignificantly alteredthenuclear,thermal,orhydraulic performance oftheplant.6.9.1.2Thestartupreportshalladdresseachofthetestsidentified intheFSARandshallincludeadescription ofthemeasuredvalueoftheoperating conditions orcharacteristics obtainedduringthetestprogramandacomparison ofthesevalueswithdesignpredictions andspecifications.
: b. The change  is approved by two members of the plant management  staff, at least one of whom holds a Senior Reactor  Operator's License on the unit affected.
Anycorrective actionsthatwererequiredtoobtainsatisfactory operation shallalsobedescribed.
ce  The change  is documented, reviewed by the PNSRC and approved by the Plant Manager within 14 days of implementation.
'Anyadditional specificdetailsrequiredinlicenseconditions basedonothercommitments shallbeincludedinthisreport.6.9.1.3Startupreportsshallbesubmitted within(1)90daysfollowing completion ofthestartuptestprogram,(2)90daysfollowing resumption orcommencement ofcommercial poweroperation, and(3)9monthsfollowing initialcriticality, whichever isearliest.
6.8.4    Plant procedures for post-accident sampling shall be established, implemented, and maintained which will ensure the capability to obtain and analyze reactor coolant and containment atmosphere samples and radioactive iodines and particulate  samples  in plant  gaseous  effluents under accident conditions. The program  will- include the following:
IftheStartupReportdoesnotcoverallthreeevents(i.e.,initialcriticality, completion ofstartuptestprogram,andresumption orcommencement ofcommercial D.C.COOK-UNIT26-14aAmendment No.
a~ Training of personnel,
TABLE3.3-6APOST-ACCIDENT RADIATION MONITORING INSTRUMENTATION INSTRUMENT MINIMUMCHANNELSOPERABLEAPPLICABLE MODESMEASUREMENT RANGEACTIONl.AREAMONITORSHIGHRANGEContainment Area112131to10rad/hr7PHOTON2.NobleGasEffluentMonitorsa)UNITVENTiMidRange*(VRS-1507) 1,2,3-232.5x10to10pCi/cciiHighRange(VRS-1509) 1I2I310to10pCi/cc5b)Atmospheric SteamDumpValvesDischarge c)GlandSeal(1)ExhaustMidRange(SRA-1807) d)Condenser Exhaust(1)SystemMidRange(SRA-1907) 1/Loop1,2,31/2i31,2,33to10pCi/cc5-232.Sxl0to10pCi/cc-232.5x10to10pCi/cc*Automatic Switchover toHighRangeonlyConfiguration (Alarm/Trip Setpointislxl0~Ci/cc)**PerRequirements ofSpecification 3.3.3.8(1)Theseinstruments areunderspecialtestoperation modeformoistureconcern,butarefunctionally OPERABLE.
: b. Procedures  for sampling and analysis, c~ Provision for maintenance of sampling and analysis equipment.
TABLE3.3-6APOST-ACCIDENT RADIATION MONITORING INSTRUMENTATION INSTRUMENT MINIMUMCHANNELSOPERABLEAPPLICABLE MODESMEASUREMENT RANGEACTIONl.AREAMONITORSHIGHRANGEContainment Area1I2I31to10rad/hr7PHOTON2.NobleGasEffluentMonitorsa)UNITVENTi.MidRange>>(VRS-2507) 1I2I3-232.5x10to10pCi/ccii.HighRange(VRS-2509)
D. C. COOK UNIT 2                      6-14                  Amendment No.
~1/2/310to10>Ci/cc5b)Atmospheric SteamDumpValvesDischarge c)GlandSeal(1)ExhaustMidRange(SRA-2807)
 
(1)d)Condenser ExhaustSystemMidRange(SRA-2907) 1/Loop1,2,31I2I31I2I33to10>Ci/cc5-232.5x10to10>Ci/cc-232.5x10to10~Ci/cc*Automatic Switchover toHighRangeonlyConfiguration (Alarm/Trip Setpointislx10~Ci/cc)**PerRequirements ofSpecification 3.3.3.6(1)Theseinstruments areunderspecialtestoperation modeformoistureconcern,butarefunctionally OPERABLE.
6.9  REPORTING RE UIREMENTS ROUTINE REPORTS AND REPORTABLE OCCURRENCES 6.9.1      In addition to the applicable reporting requirements of Title  10, Code of Federal Regulations, the following reports shall be submitted to the Director of the Regional Office of Inspection and Enforcement unless otherwise noted.
7TABLE4.3-3APOST-ACCIDENT RADIATION MONITORING INSTRUMENTATION SURVEILLANCE REUIREMENTS O00It3INSTRUMENT 1.AREAMONITORSCHANNELCHECKCHANNELCALIBRATION CHANNELMODESFORWHICHFUNCTIONAL SURVEILLANCE ISHighRangeContainment AreaN/A1I2I32.NobleGasEffluentMonitorsa)UnitVenti.Mid'ange(VRS-1507) ii.HighRange(VRS-1509)
STARTUP REPORT 6.9.1.1    A summary  report of plant startup and power escalation testing shall be submitted following (1) receipt of an operating license, (2) amendment to the license involving a planned increase in power level, (3) installation of fuel that has a different design or has been manufactured by a different fuel supplier, and (4) modifications that may have significantly altered the nuclear, thermal, or hydraulic performance of the plant.
N/A1I2I31,2,3b)Atmospheric SteamDumpValveDischarge c)GlandSealExhaust(1)MidRange(SRA-1807) d)Condenser ExhaustSystem(1)MidRange(SRA-1907)
6.9. 1. 2  The  startup report shall address each of the tests identified in the  FSAR and shall include a description of the measured value of the operating conditions or characteristics obtained during the test program and a comparison of these values with design predictions and specifications. Any corrective actions that were required to obtain satisfactory operation shall also be described.   'Any additional specific details required in license conditions based on other commitments shall be included in this report.
MRN/AN/AN/A1,2,31I2I31,2,30*Acceptable criteriaforcalibration areprovidedinTableII.F.1-3ofNUREG-0737.
6.9.1.3    Startup reports shall be submitted within (1) 90 days following completion of the startup test program, (2) 90 days following resumption or commencement of commercial power operation, and (3) 9 months  following  initial criticality, whichever is earliest.
(1)Theseinsgrpnents areundeysp8gjgpgstoperation modeformoistureconcern,u.arefunctxona ly-OAOQITABLE4.3-3APOST-ACCIDENT RADIATION MONITORING INSTRUMENTATION SURVEILLANCE REUIREMENTS INSTRUMENT CHANNELCHECKCHANNELCALIBRATION CHANNELMODESFORWHICHFUNCTIONAL SURVEILLANCE IS1.AREAMONITORSHighRangeContainment AreaN/A1,2,32.Nob'leGasEffluent'onitors a)UnitVent.i.MidRange(VRS-2507) ii.HighRange(VRS-2509)
If  the Startup Report does not cover  all three events (i.e.,
N/A1/2I31I2I3b)Atmospheric SteamDumpValveDischarge c)GlandSealExhaust(1),MidRange(SRA-2807) d)Condenser ExhaustSystem(1)MidRange(SRA-2907)
initial criticality,   completion of startup test program, and resumption or  commencement  of commercial D. C. COOK UNIT 2                      6-14a                Amendment No.
N/AN/AN/A1I2I31I2I31,2,30*Acceptable criteriaforcalibration areprovidedinTableII.F.1-,3 ofNUREG-0737.
 
(1)Theseinstruments areunderspecialtestoperation modeformoistureconcern,nutarefunctionally SBPutBFR..
TABLE  3.3-6A POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION MINIMUM CHANNELS      APPLICABLE        MEASUREMENT INSTRUMENT                               OPERABLE          MODES              RANGE                      ACTION
aTABLE3.3-11-POST-ACCIDENT MONITORING INSTRUMENTATION INSTRUMENT 1.Containment Pressure2.ReactorCoolantOutletTemperature
: l. AREA MONITORS HIGH RANGE 7
-T(WideRange)3.ReactorCoolantInletTemperature
Containment Area                                11 21 3          1  to  10    rad/hr PHOTON
-T(WideRange)4.ReactorCoolantPressure-WideRange5.Pressurizer WaterLevel6.SteamLinePressure7.SteamGenerator WaterLevel-NarrowRange8.Refueling WaterStorageTankWaterLevel,9.BoricAcidTankSolutionLevel10.Auxiliary Feedwater FlowRatell.ReactorCoolantSystemSubcooling MarginMonitor12.PORVPositionIndicator
: 2. Noble Gas  Effluent Monitors a)   UNIT VENT i    Mid Range*                                                         -2 to    3 (VRS-1507)                               1, 2,   3         2.5x10            10  p  Ci/cc ii (VRS-1509)
-LimitSwitches***
High Range 1I 2I  3          10  to  10 5
13.PORVBlockValvePositionIndicator
pCi/cc b)   Atmospheric Steam Dump Valves 5
-LimitSwitches14.SafetyValvePositionIndicator
Discharge                          1/Loop    1, 2,  3          3  to  10      pCi/cc (1) c)  Gland Seal Exhaust Mid Range                                                        -2          3 (SRA-1807)                                   1/ 2i  3          2. Sxl0      to  10    pCi/cc d)   Condenser Exhaust (1)
-Acoustic.
System Mid Range                                                        -2          3 (SRA-1907)                                   1, 2, 3          2.5x10        to  10    pCi/cc
Monitor15.Containment WaterLevel(NarrowRange)16.Containment WaterLevel(WideRange)17.Radiation Monitoring ChannelsMINIMUMCHANNELSOPERABLE2/SteamGenerator 1/SteamGenerator 1/SteamGenerator*
* Automatic Switchover     to High Range only Configuration (Alarm/Trip Setpoint  is lxl0 ~Ci/cc)
1/Valve1/Valve1/ValvePerTable3.3-6A0*SteamGenerator WaterLevelChannelscanbeusedasasubstitute forthecorresponding auxiliary feedwater flow.ratechannelinstrument.
** Per Requirements of Specification 3.3.3.8 (1) These instruments are under special test operation    mode for moisture concern, but are functionally OPERABLE.
**PRODAC250subcooling marginreadoutcanbeusedasasubstitute forthesubcooling monitorinstrument.
 
***Acoustic monitoring ofPORVposition(1channelperthreevalves-.headereddischarge) canbeusedasasubstitute forthepORVpositionIndicator
TABLE  3.3-6A POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION MINIMUM CHANNELS      APPLICABLE      MEASUREMENT INSTRUMENT                                 OPERABLE          MODES            RANGE                    ACTION
-LimitSwitchesinstruments.
: l. AREA MONITORS HIGH RANGE 7
AAoOIHINSTRUMENT 1.Containment PressureTABLE3.3-10POST-ACCIDENT MONITORING INSTRUMENTATION MINIMUMCHANNELSOPERABLE2.ReactorCoolantOutletTemperature
Containment Area                                1I 2I  3        1  to  10    rad/hr PHOTON
-T(WideRange)3.ReactorCoolantInletTemperature
: 2. Noble Gas  Effluent Monitors a)   UNIT VENT
-T(WideRange)4.ReactorCoolantPressure-WideRange5.Pressurizer WaterLevel6.SteamLinePressure7.SteamGenerator WaterLevel-NarrowRange8.Refueling WaterStorageTankWaterLevel9.BoricAcidTankSolutionLevel10.Auxiliary Feedwater FlowRate11.ReactorCoolantSystemSubcooling MarginMonitor12.PORVPositionIndicator
: i. Mid Range>>                                                         -2          3 (VRS-2507)                               1I 2I  3        2.5x10        to 10  pCi/cc ii. High Range                                                              5 (VRS-2509) ~
-LimitSwitches***
1/ 2/   3        10  to  10      >Ci/cc b)   Atmospheric Steam Dump Valves 5
13.PORVBlockValvePositionIndicator
Discharge                          1/Loop    1, 2,  3        3  to  10      >Ci/cc c)   Gland Seal (1)
-LimitSwitches14.SafetyValvePositionIndicator
Exhaust Mid Range                                                        -2          3 (SRA-2807)                                   1I 2I  3        2.5x10        to 10  >Ci/cc d)  Condenser Exhaust (1)
-AcousticMonitor15.Containment WaterLevel(NarrowRange)16.Containment WaterLevel(WideRange)17.Radiation Monitoring Channels22/SteamGenerator 1/SteamGenerator 1/SteamGenerator*
System Mid Range                                                        -2          3 (SRA-2907)                                    1I 2I  3        2.5x10        to 10  ~Ci/cc
1/Valve1/Valve1/ValvePerTable3.3-6A0*SteamGenerator WaterLevelChannelscanbeusedasasubstitute forthecorresponding auxiliary feedwater flowratechannelinstrument.
* Automatic Switchover to High Range only Configuration (Alarm/Trip Setpoint    is lx10  ~Ci/cc)
**PRODAC250subcooling marginreadoutcanbeusedasasubstitute forthesubcooling monitorinstrument.
** Per Requirements of Specification 3.3.3.6 (1) These instruments are under special    test operation  mode for moisture concern, but are functionally  OPERABLE.
***Acoustic monitoring ofPORVposition(1channelperthreevalves-headereddischarge) canbeusedasasubstitute forthePORVPositionIndicator
 
-LimitSwitchesinstruments.
7 TABLE 4.3-3A POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS O
TABLE4.3-7POST-ACCIDENT MONITORING INSTRUMENTATION SURVEILLANCE REUIREMENTS INSTRUMENT 1.Containment Pressure2.ReactorCoolantOutletTemperature
00                                                                            CHANNEL    MODES FOR WHICH CHANNEL      CHANNEL        FUNCTIONAL  SURVEILLANCE IS I INSTRUMENT                                CHECK      CALIBRATION t3 1. AREA MONITORS High Range Containment Area                                                  N/A        1I 2I  3
-T(WideRange)3ReactorCoolantInletTemperature
: 2. Noble Gas  Effluent Monitors a) Unit Vent
-TCOLD(WideRange)4.ReactorCoolantPressure-WideRange5.Pressurizer WaterLevel6.SteamLinePressure7.SteamGenerator WaterLevel-NarrowRange8.RWSTWaterLevel9.BoricAcidTankSolutionLevel10.Auxiliary Feedwater FlowRate/11.ReactorCoolantSystemSubcooling MarginMonitor12.PORVPositionIndicator
: i. Mid'ange (VRS-1507)                                                               1I 2I  3 ii. High Range (VRS-1509)                                                   N/A          1, 2, 3 b) Atmospheric Steam Dump Valve Discharge                M              R              N/A          1, 2, 3 c) Gland Seal Exhaust (1)
-LimitSwitches13.PORVBlockValvePositionIndicator
Mid Range (SRA-1807)                                                        N/A          1I 2I 3 (1) d) Condenser Exhaust System Mid Range (SRA-1907)                                                       N/A          1, 2, 3 0
-LimitSwitches14.SafetyValvePositionIndicator
* Acceptable criteria for calibration are provided in Table II.F.1-3 of NUREG-0737.
-AcousticMonitor15.Containment WaterLevel(NarrowRange)16.Containment WaterLevel(WideRange)17.Radiation Monitoring Channels(PerTable4.3-3A)CHANNELCHECKN/AN/ACHANNELCALIBRATION R
(1) These  insgrpnents concern,   u .are functxona    sp8gjg pgst operation mode for moisture are undey ly-
"TABLE4.3-10POST-ACCIDENT MONITORING INSTRUMENTATION SURVEILLANCE REUIREMENTS INSTRUMENT 1.Containment Pressure2.ReactorCoolantOutletTemperature
 
-T(WideRange)3.ReactorCoolantInletTemperature
O TABLE 4.3-3A A
-T(WideRange)4.ReactorCoolantPressure-WideRange5.Pressurizer WaterLevel6.SteamLinePressure7..SteamGenerator WaterLevel-NarrowRange8.RWSTWaterLevel9.BoricAcidTankSolutionLevel10.Auxiliary Feedwater FlowRate11.ReactorCoolantSystemSubcooling MarginMonitor12.PORVPositionIndicator
O Q
-LimitSwitches13.PORVBlockValve-PositionIndicator
POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS I
-LimitSwitches14.SafetyValvePositionIndicator
CHANNEL    MODES FOR WHICH CHANNEL        CHANNEL          FUNCTIONAL  SURVEILLANCE IS INSTRUMENT                               CHECK      CALIBRATION
-AcousticMonitor15.Containment WaterLevel(NarrowRange)16.Containment WaterLevel(WideRange)17.Radiation Monitoring Channels(PerTable4.3-3A)CHANNELCHECKN/AN/ACHANNELCALIBRATION R
: 1. AREA MONITORS High Range Containment Area                                                  N/A          1, 2, 3
CONTAINMENT SYSTEMS3/4.6.4COMBUSTIBLE GASCONTROLHYDROGENANALYZERS LIMITINGCONDITION FOROPERATION 3.6.4.1Twocontainment hydrogenanalyzers shallbeOPERABLE.
: 2. Nob'le Gas  Effluent'onitors a)   Unit Vent
APPLICABILITY:
          .i. Mid Range (VRS-2507)                                                               1/ 2I 3 ii. High Range (VRS-2509)                                                 N/A          1I 2I 3 b)   Atmospheric Steam Dump Valve Discharge                                              N/A          1I 2I 3 c)   Gland Seal Exhaust (1)
MODES1and2ACTION:a0Withonehydrogenanalysisdeviceinoperable, restoretheinoperable analysisdevicetoOPERABLEstatuswithin30daysorbeinatleastHOTSTANDBYwithinthenext6hours.b.Withbothhydrogenanalysisdevicesinoperable, restoreatleastoneanalysisdevicetoOPERABLEstatuswithin72hoursorbeinatleastHOTSTANDBYwithinthenext6hours.SURVEILLANCE REUIREMENTS 4.6.4.1Eachhydrogenanalysisdeviceshallbedemonstrated OPERABLEatleastonceper92daysonaSTAGGERED TESTBASISbyperforming aCHANNELCALIBRATION usingafourpercentandfifteenpercentnominalhydrogengas,balancenitrogen.
          ,Mid Range (SRA-2807)                                                      N/A          1I 2I 3 (1) d)   Condenser Exhaust System Mid Range (SRA-2907)                                                       N/A          1, 2, 3 0
D.C.COOK-UNIT13/46-23Amendment No.
* Acceptable criteria for calibration are provided in Table II.F.1-,3 of NUREG-0737.
CONTAINMENT SYSTEMS3/4.6.4COMBUSTIBLE GASCONTROLHYDROGENANALYZERS LIMITINGCONDITION FOROPERATION 3.6.4.1Twocontainment hydrogenanalyzers shallbeOPERABLE.
(1) These  instruments are under special test operation mode for moisture concern, nut are functionally SBPutBFR..
APPLICABILITY:
 
Modes1and2.ACTION:a.Withonehydrogenanalysisdeviceinoperable, restoretheinoperable analysisdevicetoOPERABLEstatuswithin30daysorbeinatleastHOTSTANDBYwithinthenext6hours.b.Withbothhydrogenanalysisdevicesinoperable, restoreatleastoneanalysisdevicetoOPERABLEstatuswithin72hoursorbeinatleastHOTSTANDBYwithinthenext6hours.SURVEILLANCE REUIREMENTS 4.6.4.1Eachhydrogenanalysisdeviceshallbedemonstrated OPERABLEatleastonceper92daysonaSTAGGERED TESTBASISbyperforming aCHANNELCALIBRATION usingafourpercentandfifteenpercentnominalhydrogengas,balancenitrogen.
a TABLE 3.3                                         POST-ACCIDENT MONITORING INSTRUMENTATION INSTRUMENT                                                       MINIMUM CHANNELS OPERABLE
D.C.COOK-UNIT23/46-33Amendment No.
: 1. Containment Pressure
INSTRUMENTATION CHLORINEDETECTION SYSTEMLIMITINGCONDIT1ON FOROPERATION 3.3.3.11Thechlorinedetection system,withitsalarmsetpointadjustedtoactuateatachlorineconcentra'tion oflessthanorequalto5ppm,,shallbeOPERABLE.
: 2. Reactor Coolant Outlet Temperature  T     (Wide Range)
APPLICABILIY:
: 3. Reactor Coolant Inlet Temperature  T     (Wide Range)
AllMODES.ACTION:a0Withthechlorinedetection systeminoperable, within1hourinitiateandmaintainoperation ofthecontrolroomemergency ventilation systemintherecirculation modeofoperation.
: 4. Reactor Coolant Pressure  Wide Range
b.Theprovisions ofSpecifications 3.0.4arenotapplicable.
: 5. Pressurizer Water Level
SURVEILLANCE REUIREMENTS 4.3.3.11Thechlorinedetection systemshallbedemonstrated OPERABLEbyperformance ofaCHANNELFUNCTIONAL TESTatleastonceper31daysandaCHANNELCALIBRATION atleastonceper18months.D.C.COOK-UNIT13/43-69Amendment No.
: 6. Steam Line Pressure                                                2/Steam Generator
INSTRUMENTATION CHLORINEDETECTION SYSTEMLIMITINGCONDITION FOROPERATION 3.3.3.11Thechlorinedetection system,withitsalarmsetpointadjustedtoactuateatachlorineconcentration oflessthanorequalto5ppm,shallbeOPERABLE.
: 7. Steam Generator Water Level  Narrow Range                        1/Steam Generator
APPLICABILITY:
: 8. Refueling Water Storage Tank Water Level
ALLMODES.ACTION:a0Withthechlorinedetection systeminoperable, within1hourinitiateandmaintainoperation ofthecontrolroomemergency ventilation systemintherecirculation modeofoperation.
  , 9. Boric Acid Tank Solution Level
b.Theprovisions ofSpecification 3.0.4arenotapplicable.
: 10.     Auxiliary Feedwater Flow Rate                                      1/Steam Generator*
SURVEILLANCE REUIREMENTS 4.3.3.11Thechlorinedetection systemshallbedemonstrated OPERABLEbyperformance ofaCHANNELFUNCTIONAL TESTatleastonceper31daysandaCHANNELCALIBRATION atleastonceper18months.D.C.COOK-UNIT23/43-64aAmendment No.
ll.     Reactor Coolant System Subcooling Margin Monitor
I INSTRUMENTATION BASES3/4'.3.9RADIOACTIVE LIUIDEFFLUENTINSTRUMENTATION Theradioactive liquideffluentinstrumentation isprovidedtomonitorandcontrol,asapplicable, thereleasesofradioactive materials inliquideffluentduringactualorpotential releases.
: 12.      PORV  Position Indicator  Limit Switches***                       1/Valve
Thealarm/trip setpoints fortheseinstruments shallbecalculated inaccordance withNRCapprovedmethodsintheODCMtoensurethatthealarm/trip willoccurpriortoexceeding thelimitsof10CFRPart20.TheOPERABILITY anduseofthisinstrumentation isconsistent withtherequirements ofGeneralDesignCriteriaspecified inSection11.3oftheFinalSafetyAnalysisReportfortheDonaldC.CookNuclearPlant.3/4.3.3.10 RADIOACTIVE GASEOUSEFFLUENTINSTRUMENTATION Theradioactive gaseouseffluentinstrumentation isprovidedtomonitoraridcontrol,asapplicable, thereleasesofradioactive materials ingaseouseffluents duringactualorpotential releases.
: 13.     PORV Block Valve Position Indicator  Limit Switches              1/Valve
Thealarm/trip setpoints fortheseinstruments shallbecalculated inaccordance withNRCapprovedmethodsintheODCMtoensurethatthealarm/trip willoccurpriortoexceeding thelimits.Thisinstrumentation alsoincludesprovisions formonitoring theconcentrations ofpotentially explosive gasmixturesinthewastegasholdupsystem.TheOPERABILITY anduseofthisinstru-mentation isconsistent withtherequirements ofGeneralDesignCriteriaspecified inSection11.3oftheFinalSafetyAnalysisReportfortheDonaldC.CookNuclearPlant.3/4.3.3.11 CHLORINEDETECTION SYSTEMTheOPERABILITY ofthedetection systemensuresthatsufficient capability isavailable topromptlydetectandinitiateprotective actionintheeventofanaccidental chlorinerelease.Thiscapability isrequiredtoprotectcontrolroompersonnel andisconsistent withtherecommendations ofRegulatory Guide1.95,"Protection ofNuclearPowerPlantControlRoomOperators AgainstanAccidental ChlorineRelease,"
: 14.     Safety Valve Position Indicator - Acoustic. Monitor                1/Valve
: February, 1975.D.C.COOK-UNIT1B3/43-5Amendment No.
: 15.     Containment Water Level (Narrow Range)
3/4.3INSTRUMENTATION BASES3/4.3.3.8 FIREDETECTION INSTRUMENTATION OPERABILITY ofthefiredetection instrumentation ensuresthatadequatewarningcapability isavailable forthepromptdetection offires.Thiscapability isrequiredinordertodetectandlocatefiresintheirearlystages.Promptdetection offireswillreducethepotential fordamagetosafety-related equipment andisanintegralelementintheoverallfacilityfireprotection program.Intheeventthataportionofthefiredetection instrumentation isinoperable, theestablishment offrequentfirepatrolsintheaffectedareasisrequiredtoprovidedetection capability untiltheinoperable instrumentation isreturnedtoservice.3/4.3.3.9 RADIOACTIVE LIUIDEFFLUENTINSTRUMENTATZON Theradioactive liquideffluentinstrumentation isprovidedtomonitorandcontrol,asapplicable, thereleasesofradioactive materials inliquideffluents duringactualorpotential releases.
: 16.     Containment Water Level (Wide Range)
Thealarm/trip setpoints fortheseinstruments shallbecalculated inaccordance withNRCapprovedmethodsintheODCMtoensurethatthealarm/trip willoccurpriortoexceeding thelimits.TheOPERABILITY anduseofthisinstrumentation isconsistent withtherequirements ofGeneralDesignCriteriaspecified inSection11.3oftheFinalSafetyAnalysisReportfortheDonaldC.CookNuclearPlant.3/4.3.3.10 RADIOACTIVE GASEOUSEFFLUENTINSTRUMENTATION Theradioactive gaseouseffluentinstrumentation isprovidedtomonitorandcontrol,asapplicable, thereleasesofradioactive materials ingaseouseffluents duringactualorpotential releases.
: 17.     Radiation Monitoring Channels                                      Per Table 3.3-6A 0
Thealarm/trip setpoints fortheseinstruments shallbecalculated inaccordance withNRCapprovedmethodsintheODCMtoensurethatthealarm/trip willoccurpriortoexceeding thelimitsof10CFRPart20.Thisinstrumentation alsoincludesprovisions formonitoring theconcentrations ofpotentially explosive gasmixturesinthewastegasholdupsystem.TheOPERABILITY anduseofthisinstrumentation isconsistent withtherequirements ofGeneralDesignCriteriaspecified inSection11.3oftheFinalSafetyAnalysisReportfor,theDonaldC.CookNuclearPlant.3/4.3.3.11 CHLORINEDETECTION SYSTEMTheOPERABILITY ofthedetection systemensuresthatsufficient capability isavailable topromptlydetectandinitiateprotective actionintheeventofanaccidental chlorinerelease.Thiscapability isrequiredtoprotectcontrolroompersonnel andisconsistent withtherecommendations ofRegulatory Guide1.95,"Protection ofNuclearPowerPlantControlRoomOperators AgainstanAccidental ChlorineRelease,"
      *Steam Generator Water Level Channels can be used as a    substitute for the corresponding auxiliary feedwater flow. rate channel instrument.
: February, 1975.D.C.COOK-UNIT2B3/43-3Amendment No.
      **PRODAC 250 subcooling margin readout can be used as a substitute    for the subcooling monitor instrument.
3/43.4TURBINEOVERSPEED PROTECTION hThisspecification isprovidedtoensurethattheturbineoverspeed protection instrumentation andtheturbinespeedcontrolvalvesareOPERABLEandwillprotecttheturbinefromexcessive overspeed.
    ***Acoustic monitoring of  PORV position (1 channel per three valves  headered discharge)
Protection fromturbineexcessive overspeed isrequiredsinceexcessive overspeed oftheturbinecouldgeneratepotentially damagingmissileswhichcouldimpactanddamagesafetyrelatedcomponents, equipment orstructures.
                                                                            .                    can be used as a  substitute for the pORV position Indicator  Limit Switches instruments.
D.C.COOK.-UNIT2B3/43-4Amendment No.
 
PLANTSYSTEMS3/4.7.5CONTROLROOMEMERGENCY VENTILATION SYSTEMLIMITINGCONDITION FOROPERATION 3.7.5.1Thecontrolroomemergency ventilation systemshallbeOPERABLEwith:a.Twoindependent heatingandcoolingsystems,b.Twoindependent pressurization fans,andc.OnecharcoalabsorberandHEPAfiltertrain.APPLICABILITY:
A A
ALLMODES.ACTION:MODES1,2,3,and4:Withoneheatingandcoolingsysteminoperable, restoretheinoperable systemtoOPERABLEstatuswithin7daysorbeinatleastHOTSTANDBYwithinthenext6hoursandinCOLDSHUTDOWNwithinthefollowing 30hours.b.Withonepressurization faninoperable, restoretheinoperable fantoOPERABLEstatuswithin7daysorbeinatleastHOTSTANDBYwithinthenext6hoursandinCOLDSHUTDOWNwithinthefollowing 30hours.c.Withthefiltertraininoperable, restorethefiltertraintoOPERABLEstatuswithin24hoursorbeinatleastHOT,STANDBY withinthenext6hoursandinCOLDSHUTDOWNwithinthefollowing 30hours.PMODES5and6:d.Withonepressurization faninoperable, dooneofthefollowing:
TABLE 3.3-10 oO                                      POST-ACCIDENT MONITORING INSTRUMENTATION I
(1)restoretheinoperable fantoOPERABLEstatuswithin7days,or(2)initiateandmaintainoperation oftheremaining OPERABLEpressurization fanandthefiltertraininarecirculation mode,or(3)suspendalloperations involving COREALTERATIONS orpositivereactivity changes.e.Withanyofthefollowing (1)bothheatingandcoolingsystems;(2)bothpressurization fans;,(3) thefiltertrain>inoperable, suspendalloperations involving COREALTERATIONS orpositive'reactivity changes.SURVEILLANCE REUIREMENTS 4.7.5.1Thecontrolroomemergency ventilation systemshallbedemonstrated OPERABLE:
INSTRUMENT                                                        MINIMUM CHANNELS OPERABLE H
a.Atleastonceper12hoursbyverifying thatthecontrolroomair0temperature is<120F.D.C.COOK-UNIT23/47-14Amendment No.
: 1. Containment Pressure
PLANTSYSTEMSSURVEILLANCE REUIREMENTS (Continued) b.Atleastonceper31daysonaSTAGGERED TESTBASISbyinitiating flowthroughtheHEPAfilterandcharcoaladsorbertrainandverifying thatthesystemoperatesforatleast15minutes.coAtleastonceper18monthsor(1)afteranystructural maintenance ontheHEPAfilterorcharcoaladsorberhousings, or(2)following
: 2. Reactor Coolant Outlet Temperature  T      (Wide Range)
: painting, fireorchemicalreleasexnanyventilation zonecom-municating withthesystemby:1.Verifying thatthecharcoaladsorbers remove>99%ofahalogenated hydrocarbon refrigerant testgaswhentheyaretestedin-placeinaccordance withANSIN510-1975 whileoperating theventilation systemataflowrateof,6000cfm+10%.2.3.Verifying thattheHEPAfilterbanksremove>99%oftheDOPwhentheyaretestedin-placeinaccordance withANSI.N510-1975 whileoperating theventilation systemataflowrateof6000cfm+10%.Verifying within31daysafterremovalthatalaboratory analysisofacarbonsamplefromeitheratleastonetestcanisteroratleasttwocarbonsamplesremovedfromoneofthecharcoaladsorbers demonstrates aremovalefficiency of>90%forradioactive methyliodidewhenthesampleistestedinaccordance withANSIN510-1975 (130C,95%R.H.).Thecarbonsamplesnotobtainedfromtestcanisters shallbepreparedbyeither:a)Emptyingoneentirebedfromaremovedadsorbertraymixingtheadsorbent thoroughly, andobtaining samplesatleasttwoinchesindiameterandwithalengthequaltothethickness ofthebed,orb)Emptyingalongitudinal samplefromanadsorbertray,mixingtheadsorbent thoroughly, andobtaining samplesatleasttwoinchesindiameterandwithalengthequaltothethickness ofthebed.4.Verifying a.systemflowrateof6000cfm+10%duringsystemoperation whentestedinaccordance withANSIN510-1975.
: 3. Reactor Coolant Inlet Temperature  T       (Wide Range)           2
d.Afterevery720hoursofcharcoaladsorberoperation byeither:D.C.COOK-UNIT23/47-15Amendment.
: 4. Reactor Coolant Pressure  Wide Range
No.
: 5. Pressurizer Water Level
PLANTSYSTEMS3/4.7.5CONTROLROOMEMERGENCY VENTILATION SYSTEMLZMITINGCONDITION FOROPERATION 3.7.5.1Thecontrolroomemergency ventilation systemshallbeOPERABLEwith:aoTwoindependent heatingandcoolingsystems,b.c~Twoindependent pressurization fans,andOnecharcoalabsorberandHEPAfiltertrain.APPLICABILITY:
: 6. Steam Line Pressure                                                  2/Steam Generator
ALLMODES.ACTION:MODES1,2,3,and4:a.Withoneheatingand.coolingsysteminoperable, restoretheinoperable systemtoOPERABLEstatuswithin7daysorbeinatleastHOTSTANDBYwithinthenext6hoursandinCOLDSHUTDOWNwithinthefollowing 30hours.b.Withonepressurization faninoperable, restoretheinoperable fantoOPERABLEstatuswithin7daysorbeinatleastHOTSTANDBYwithinthenext6hoursandinCOLDSHUTDOWNwithinthefollowing 30hours.c.Withthefiltertraininoperable, restorethefiltertraintoOPERABLEstatuswithin24hoursorbeinatleastHOTSTANDBYwithinthenext6hoursandinCOLDSHUTDOWNwithinthefollowing 30hours.MODES5and6:d.Withonepressurization faninoperable, dooneofthefollowing:
: 7. Steam Generator Water Level  Narrow Range                          1/Steam Generator
(1)restoretheinoperable fantoOPERABLEstatuswithin7days,or(2)initiateandmaintainoperation oftheremaining OPERABLEpressurization fanandthefiltertraininarecirculation mode,or(3)suspendalloperations involving COREALTERATIONS orpositivereactivity changes.e..With,anyofthefollowing (1)bothheatingandcoolingsystems;(2)bothpressurization fans;(3)thefiltertrain;inoperable',.
: 8. Refueling Water Storage Tank Water Level
suspendalloperations involving COREALTERATIONS orpositivereactivity changes.SURVEILLANCE REUIREMENTS
: 9. Boric Acid Tank Solution Level
~4.7.5.1Thecontrolroomemergency ventilation systemshallbedemonstrated OPERABLE:
: 10. Auxiliary Feedwater Flow Rate                                        1/Steam Generator*
a.Atleastoncepea'2hoursbyverifying thatthecontrolroomair0temperature is<120F.D.C.COOK-UNIT13/47-19Amendment No.}}
: 11. Reactor Coolant System Subcooling Margin Monitor
: 12. PORV Position Indicator  Limit Switches***                         1/Valve
: 13. PORV Block Valve Position Indicator  Limit Switches                1/Valve
: 14. Safety Valve Position Indicator  Acoustic Monitor                  1/Valve
: 15. Containment Water Level (Narrow Range)
: 16. Containment Water Level (Wide Range)
: 17. Radiation Monitoring Channels                                        Per Table 3.3-6A 0
      *Steam Generator Water Level Channels can be used as a    substitute for the corresponding auxiliary feedwater flow rate channel instrument.
    **PRODAC 250 subcooling margin readout can be used as a substitute      for the subcooling monitor instrument.
    ***Acoustic monitoring of  PORV  position  (1 channel per three valves  headered discharge) can be used as a  substitute for the  PORV  Position Indicator - Limit Switches instruments.
 
TABLE 4.3-7 POST-ACCIDENT MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS CHANNEL          CHANNEL INSTRUMENT                                                         CHECK          CALIBRATION
: 1. Containment Pressure
: 2. Reactor Coolant Outlet Temperature  T     (Wide Range) 3  Reactor Coolant Inlet Temperature  TCOLD (Wide Range)
: 4. Reactor Coolant Pressure  Wide Range
: 5. Pressurizer Water Level
: 6. Steam Line Pressure
: 7. Steam Generator Water Level  Narrow Range
: 8. RWST Water Level
: 9. Boric Acid Tank Solution Level
: 10. Auxiliary Feedwater Flow Rate
                  /
: 11. Reactor Coolant System Subcooling Margin Monitor
: 12. PORV Position Indicator  Limit Switches
: 13. PORV Block Valve Position Indicator  Limit Switches
: 14. Safety Valve Position Indicator  Acoustic Monitor                                  R
: 15. Containment Water Level (Narrow Range)                           N/A
: 16. Containment Water Level (Wide Range)                             N/A
: 17. Radiation Monitoring Channels (Per Table 4.3-3A)
 
                                                "TABLE  4.3-10 POST-ACCIDENT MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS CHANNEL          CHANNEL INSTRUMENT                                                         CHECK          CALIBRATION
: 1. Containment Pressure
: 2. Reactor Coolant Outlet Temperature  T     (Wide Range)
: 3. Reactor Coolant Inlet Temperature  T       (Wide Range)
: 4. Reactor Coolant Pressure  Wide Range
: 5. Pressurizer Water Level
: 6. Steam Line Pressure
: 7. .Steam Generator Water Level  Narrow Range
: 8. RWST Water Level
: 9. Boric Acid Tank Solution Level
: 10. Auxiliary Feedwater Flow Rate                                                        R
: 11. Reactor Coolant System Subcooling Margin Monitor
: 12. PORV Position Indicator  Limit Switches
: 13. PORV Block Valve- Position Indicator  Limit Switches
: 14. Safety Valve Position Indicator  Acoustic Monitor
: 15. Containment Water Level (Narrow Range)                           N/A
: 16. Containment Water Level (Wide Range)                             N/A
: 17. Radiation Monitoring Channels (Per Table 4.3-3A)
 
CONTAINMENT SYSTEMS 3/4.6.4  COMBUSTIBLE GAS CONTROL HYDROGEN ANALYZERS LIMITING CONDITION  FOR OPERATION 3.6.4.1    Two containment hydrogen analyzers shall be OPERABLE.
APPLICABILITY:  MODES 1  and 2 ACTION:
a0  With one hydrogen analysis device inoperable, restore the inoperable analysis device to OPERABLE status within 30 days or be in at least HOT STANDBY within the next 6 hours.
: b. With both hydrogen analysis devices inoperable, restore at least one analysis device to OPERABLE status within 72 hours or be in at least HOT STANDBY within the next 6 hours.
SURVEILLANCE RE UIREMENTS 4.6.4.1    Each hydrogen analysis device shall be demonstrated OPERABLE at least once per 92 days on a STAGGERED TEST BASIS by performing a CHANNEL CALIBRATION using a four percent and fifteen percent nominal hydrogen gas, balance nitrogen.
D. C. COOK UNIT 1                3/4 6-23            Amendment No.
 
CONTAINMENT SYSTEMS 3/4.6.4  COMBUSTIBLE GAS CONTROL HYDROGEN ANALYZERS LIMITING CONDITION  FOR OPERATION 3.6.4.1    Two containment hydrogen analyzers shall be OPERABLE.
APPLICABILITY:       Modes 1 and 2.
ACTION:
: a. With one hydrogen analysis device inoperable, restore the inoperable analysis device to OPERABLE status within 30 days or be in at least HOT STANDBY within the next 6 hours.
: b. With both hydrogen analysis devices inoperable, restore at least one analysis device to OPERABLE status within 72 hours or be in at least HOT STANDBY within the next 6 hours.
SURVEILLANCE RE UIREMENTS 4.6.4.1    Each hydrogen analysis device shall be demonstrated OPERABLE at least once per 92 days on a STAGGERED TEST BASIS by performing a CHANNEL CALIBRATION using a four percent and fifteen percent nominal hydrogen gas, balance nitrogen.
D. C. COOK UNIT 2                3/4 6-33            Amendment No.
 
INSTRUMENTATION CHLORINE DETECTION SYSTEM LIMITING CONDIT1ON    FOR OPERATION 3.3.3.11    The  chlorine detection system, with its alarm setpoint adjusted to actuate at a chlorine concentra'tion of less than or equal to 5 ppm,
            ,shall be OPERABLE.
APPLICABILIY:     All MODES.
ACTION:
a0    With the chlorine detection system inoperable, within 1 hour initiate and maintain operation of the control room emergency ventilation system in the recirculation mode of operation.
: b. The  provisions of Specifications 3.0.4 are not applicable.
SURVEILLANCE RE UIREMENTS 4.3.3.11    The  chlorine detection system shall be demonstrated  OPERABLE  by performance of a  CHANNEL FUNCTIONAL TEST at  least  once per 31 days  and a CHANNEL CALIBRATION at least once  per 18 months.
D. C. COOK UNIT 1                3/4 3-69              Amendment No.
 
INSTRUMENTATION CHLORINE DETECTION SYSTEM LIMITING CONDITION  FOR OPERATION 3.3.3.11  The  chlorine detection system, with its alarm setpoint adjusted to actuate at a chlorine concentration of less than or equal to 5 ppm, shall be OPERABLE.
APPLICABILITY:       ALL MODES.
ACTION:
a0    With the chlorine detection system inoperable, within 1 hour initiate and maintain operation of the control room emergency ventilation system in the recirculation  mode  of operation.
: b. The provisions of Specification 3.0.4 are not applicable.
SURVEILLANCE RE UIREMENTS 4.3.3.11  The  chlorine detection system shall be demonstrated OPERABLE by performance  of a CHANNEL FUNCTIONAL TEST at least once per 31 days and a  CHANNEL CALIBRATION at least once per 18 months.
D. C. COOK UNIT 2                3/4 3-64a            Amendment No.
 
I INSTRUMENTATION BASES 3/4 '.3.9  RADIOACTIVE LI UID EFFLUENT INSTRUMENTATION The  radioactive liquid effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in liquid effluent during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits of 10 CFR Part 20. The OPERABILITY and use of this instrumentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for the Donald C. Cook Nuclear Plant.
3/4.3.3.10   RADIOACTIVE GASEOUS EFFLUENT INSTRUMENTATION The  radioactive gaseous effluent instrumentation is provided to monitor arid control, as applicable, the releases of radioactive materials in gaseous effluents during actual or potential releases.         The alarm/trip setpoints for  these  instruments  shall  be  calculated  in accordance  with NRC approved methods in    the ODCM to  ensure  that  the alarm/trip will occur prior to exceeding    the  limits. This  instrumentation  also includes  provisions for monitoring the concentrations of potentially explosive gas mixtures in the waste gas holdup system. The OPERABILITY and use of this instru-mentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for the Donald C. Cook Nuclear Plant.
3/4.3.3.11   CHLORINE DETECTION SYSTEM The OPERABILITY  of the detection system ensures that sufficient capability is available to promptly detect and initiate protective action in the event of an accidental chlorine release. This capability is required to protect control room personnel and is consistent with the recommendations of Regulatory Guide 1.95, "Protection of Nuclear Power Plant Control        Room Operators Against an Accidental Chlorine Release," February, 1975.
D. C. COOK UNIT 1                  B  3/4 3-5              Amendment No.
 
3/4.3  INSTRUMENTATION BASES 3/4.3.3.8   FIRE DETECTION INSTRUMENTATION OPERABILITY   of the fire detection instrumentation ensures that adequate warning  capability is available for the prompt detection of fires. This capability is required in order to detect and locate fires in their early stages. Prompt detection of fires will reduce the potential for damage to safety-related equipment and is an integral element in the overall facility fire protection program.
In the event that a portion of the fire detection instrumentation is inoperable, the establishment of frequent fire patrols in the affected areas is required to provide detection capability until the inoperable instrumentation is returned to service.
3/4.3.3.9   RADIOACTIVE LI UID EFFLUENT INSTRUMENTATZON The  radioactive liquid effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in liquid effluents during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits. The OPERABILITY and use of this instrumentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for the Donald C. Cook Nuclear Plant.
3/4.3.3.10   RADIOACTIVE GASEOUS EFFLUENT INSTRUMENTATION The  radioactive gaseous effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in gaseous effluents during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits of 10 CFR Part 20. This instrumentation also includes provisions for monitoring the concentrations of potentially explosive gas mixtures in the waste gas holdup system. The OPERABILITY and use of this instrumentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for
, the Donald C. Cook Nuclear Plant.
3/4.3.3.11   CHLORINE DETECTION SYSTEM The OPERABILITY  of the detection system ensures that sufficient capability is available to promptly detect and initiate protective action in the event of an accidental chlorine release. This capability is required to protect control room personnel and is consistent with the recommendations of Regulatory Guide 1.95, "Protection of Nuclear Power Plant Control Room Operators Against an Accidental Chlorine Release," February, 1975.
D. C. COOK UNIT 2                B 3/4 3-3              Amendment No.
 
3/4 3.4  TURBINE OVERSPEED PROTECTION h
This specification  is provided to  ensure that the turbine overspeed protection instrumentation and the turbine speed control valves are OPERABLE and will protect the turbine from excessive overspeed. Protection from turbine excessive overspeed is required since excessive overspeed of the turbine could generate potentially damaging missiles which could impact and damage safety related components, equipment or structures.
D. C. COOK. UNIT 2                B 3/4 3-4              Amendment No.
 
PLANT SYSTEMS 3/4.7.5  CONTROL ROOM EMERGENCY VENTILATION SYSTEM LIMITING CONDITION    FOR OPERATION 3.7.5.1    The  control  room emergency  ventilation   system    shall be OPERABLE  with:
: a. Two  independent heating and cooling systems,
: b. Two  independent pressurization fans, and
: c. One  charcoal absorber and    HEPA  filter train.
APPLICABILITY:         ALL MODES.
ACTION:
MODES  1, 2, 3, and 4:
With one heating and cooling system inoperable, restore the inoperable system to    OPERABLE  status within    7  days or be  in at least HOT STANDBY within the next      6 hours and in    COLD SHUTDOWN within the following 30 hours.
: b. With one pressurization fan inoperable, restore the inoperable fan to  OPERABLE status within 7 days or be      in  at  least HOT STANDBY within the next 6 hours and    in  COLD SHUTDOWN within      the following 30 hours.
: c. With the  filter train  inoperable, restore the filter train to OPERABLE status within 24 hours or be in at least HOT,STANDBY within the next 6 hours and in COLD SHUTDOWN within the following 30 hours.          P MODES 5  and 6:
: d. With one pressurization fan inoperable, do one of the following: (1) restore the inoperable fan to OPERABLE status within 7 days, or (2) initiate and maintain operation of the remaining OPERABLE pressurization fan and the filter train in a recirculation mode, or (3) suspend all operations involving   CORE ALTERATIONS    or positive reactivity changes.
: e. With any of the following (1) both heating and cooling systems; (2) both pressurization fans;,(3) the filter train> inoperable, suspend all operations involving CORE ALTERATIONS or positive 'reactivity changes.
SURVEILLANCE RE UIREMENTS 4.7.5.1    The  control  room emergency  ventilation   system    shall  be demonstrated OPERABLE:
: a. At least once per  12 hours by 0
verifying that the control      room  air temperature  is < 120 F.
D. C. COOK - UNIT 2                3/4 7-14                  Amendment No.
 
PLANT SYSTEMS SURVEILLANCE RE UIREMENTS    (Continued)
: b. At least once per 31 days on a STAGGERED TEST BASIS by initiating flow through the HEPA filter and charcoal adsorber train and verifying that the system operates for at least 15 minutes.
co  At least once per 18 months or (1) after any structural maintenance on the HEPA filter or charcoal adsorber housings, or (2) following painting, fire or chemical release xn any ventilation zone com-municating with the system by:
: 1. Verifying that the charcoal adsorbers remove > 99% of a halogenated hydrocarbon refrigerant test gas when they are tested in-place in accordance with ANSI N510-1975 while operating the ventilation system at a flow rate of
              , 6000 cfm + 10%.
: 2. Verifying that the  HEPA filter banks  remove  > 99% of the DOP  when they are tested  in-place in accordance with ANSI
                .N510-1975 while operating    the ventilation system at a flow rate of 6000 cfm + 10%.
: 3. Verifying within 31 days after removal that a laboratory analysis of a carbon sample from either at least one test canister or at least two carbon samples removed from one of the charcoal adsorbers demonstrates a removal efficiency of > 90% for radioactive methyl iodide when the sample is tested in accordance with ANSI N510-1975 (130 C, 95% R.H.).
The carbon samples not obtained from test canisters shall be prepared by either:
a)   Emptying one entire bed from a removed adsorber tray mixing the adsorbent thoroughly, and obtaining samples at least two inches in diameter and with a length equal to the thickness of the bed, or b)     Emptying a longitudinal sample from an adsorber tray, mixing the adsorbent thoroughly, and obtaining samples at least two inches in diameter and with a length equal to the thickness of the bed.
: 4. Verifying a.system flow rate of 6000 cfm    + 10% during system operation when tested in accordance with    ANSI N510-1975.
: d. After every    720 hours  of charcoal adsorber operation  by  either:
D. C. COOK UNIT 2                  3/4 7-15              Amendment. No.
 
PLANT SYSTEMS 3/4. 7. 5  CONTROL ROOM EMERGENCY VENTILATION SYSTEM LZMITING CONDITION FOR OPERATION 3.7.5.1    The  control  room emergency    ventilation system  shall  be OPERABLE  with:
ao    Two  independent heating and cooling systems,
: b. Two  independent pressurization fans, and c~    One  charcoal absorber and      HEPA  filter train.
APPLICABILITY:           ALL MODES.
ACTION:
MODES  1, 2, 3, and 4:
: a. With one heating and. cooling system inoperable, restore the inoperable system to OPERABLE status within 7 days or be in at least HOT STANDBY within the next 6 hours and in COLD SHUTDOWN within the following 30 hours.
: b. With one pressurization fan inoperable, restore the inoperable fan to  OPERABLE  status within    7 days or be  in at least HOT STANDBY within the next  6  hours and    in  COLD SHUTDOWN  within the following 30 hours.
: c. With the  filter train      inoperable, restore the  filter train  to OPERABLE status within    24 hours or be    in at least  HOT STANDBY  within the next 6 hours and  in  COLD SHUTDOWN    within the following  30  hours.
MODES 5  and 6:
: d. With one pressurization fan inoperable, do one of the following: (1) restore the inoperable fan to OPERABLE status within 7 days, or (2) initiate and maintain operation of the remaining OPERABLE pressurization fan and the filter train in a recirculation mode, or (3) suspend all operations involving       CORE ALTERATIONS  or positive reactivity changes.
: e.   .With, any of the following (1) both heating and cooling systems; (2) both pressurization fans; (3) the filter train; inoperable',. suspend all operations involving CORE ALTERATIONS or positive reactivity changes.
SURVEILLANCE RE UIREMENTS        ~
4.7.5.1    The  control  room emergency    ventilation system  shall  be demonstrated OPERABLE:
: a. At least once pea'2 hours  0 by verifying that the control room air temperature    is <   120 F.
D. C. COOK UNIT 1                      3/4 7-19                Amendment No.}}

Latest revision as of 11:51, 22 October 2019

Proposed Tech Specs for Compliance w/NUREG-0737 Requirements
ML17334A533
Person / Time
Site: Cook  American Electric Power icon.png
Issue date: 07/19/1984
From:
INDIANA MICHIGAN POWER CO. (FORMERLY INDIANA & MICHIG
To:
Shared Package
ML17334A532 List:
References
NUDOCS 8407240188
Download: ML17334A533 (24)


Text

ATTACHMENT NO. 2 TO AEP:NRC:0856A DONALD C. COOK NUCLEAR PLANT UNIT NOS. 1 AND 2 PROPOSED TECHNICAL SPECIFICATIONS 84o'71 9 eoR ADOCg gg'Ppp~~g t,

DR ~~.;

ADMINISTRATIVE CONTROLS 6.8.3 Temporary changes to procedures of 6.8.1 above may be made provided:

a0 The intent of the original procedure is not altered.

b. The change is approved by two members of the plant management staff, at least one of whom holds a Senior Reactor Operator's License on the unit affected.

C ~ The change is documented, reviewed by the PNSRC and approved by the Plant Manager within 14 days of implementation.

6.8.4 Plant procedures for post-accident sampling shall be established, implemented, and maintained which will ensure the capability to obtain and analyze reactor coolant and containment atmosphere samples and radioactive iodines and particulate samples in plant gaseous effluents under accident conditions. The program will include the following:

a ~ Training of personnel,

b. Procedures for sampling and analysis, c~ Provisions for maintenance of sampling and analysis equipment.

D. C. COOK UNIT 1 6-14 Amendment No.

6. 9 REPORTING RE UIREMENTS ROUTINE REPORTS AND REPORTABLE OCCURRENCES 6.9.1 In addition to the applicable reporting requirements of Title 10, Code of Federal Regulations, the following reports shall be sub-mitted to the Director of the Regional Office of Inspection and Enforcement unless otherwise noted.

STARTUP REPORT 6.9.1.1 A summary report of plant startup and power escalation testing shall be submitted following (1) receipt of an operating license, (2) amendment to the license involving a planned increase in power level, (3) installation of fuel that has a different design or has been manufactured by a different fuel supplier, and (4) modifications that may have significantly altered the nuclear, thermal, or hydraulic performance of the plant.

6.9.1.2 The startup report shall address each of the tests identified in the FSAR and shall include a description of the measured values of the operating conditions or characteristics obtained during the test program and a comparison of these values with design predictions and specifications. Any corrective actions that were required to obtain satisfactory operation shall also be described. Any additional specific details required in license conditions based on other commitments shall be included in this report.

D. C. COOK UNIT 1 6-14a Amendment No.

ADMINISTRATIVE CONTROLS 6.8.3 Temporary changes to procedures of 6.8.1 above may be made provided:

a. The intent of the original procedure is not altered.
b. The change is approved by two members of the plant management staff, at least one of whom holds a Senior Reactor Operator's License on the unit affected.

ce The change is documented, reviewed by the PNSRC and approved by the Plant Manager within 14 days of implementation.

6.8.4 Plant procedures for post-accident sampling shall be established, implemented, and maintained which will ensure the capability to obtain and analyze reactor coolant and containment atmosphere samples and radioactive iodines and particulate samples in plant gaseous effluents under accident conditions. The program will- include the following:

a~ Training of personnel,

b. Procedures for sampling and analysis, c~ Provision for maintenance of sampling and analysis equipment.

D. C. COOK UNIT 2 6-14 Amendment No.

6.9 REPORTING RE UIREMENTS ROUTINE REPORTS AND REPORTABLE OCCURRENCES 6.9.1 In addition to the applicable reporting requirements of Title 10, Code of Federal Regulations, the following reports shall be submitted to the Director of the Regional Office of Inspection and Enforcement unless otherwise noted.

STARTUP REPORT 6.9.1.1 A summary report of plant startup and power escalation testing shall be submitted following (1) receipt of an operating license, (2) amendment to the license involving a planned increase in power level, (3) installation of fuel that has a different design or has been manufactured by a different fuel supplier, and (4) modifications that may have significantly altered the nuclear, thermal, or hydraulic performance of the plant.

6.9. 1. 2 The startup report shall address each of the tests identified in the FSAR and shall include a description of the measured value of the operating conditions or characteristics obtained during the test program and a comparison of these values with design predictions and specifications. Any corrective actions that were required to obtain satisfactory operation shall also be described. 'Any additional specific details required in license conditions based on other commitments shall be included in this report.

6.9.1.3 Startup reports shall be submitted within (1) 90 days following completion of the startup test program, (2) 90 days following resumption or commencement of commercial power operation, and (3) 9 months following initial criticality, whichever is earliest.

If the Startup Report does not cover all three events (i.e.,

initial criticality, completion of startup test program, and resumption or commencement of commercial D. C. COOK UNIT 2 6-14a Amendment No.

TABLE 3.3-6A POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION MINIMUM CHANNELS APPLICABLE MEASUREMENT INSTRUMENT OPERABLE MODES RANGE ACTION

l. AREA MONITORS HIGH RANGE 7

Containment Area 11 21 3 1 to 10 rad/hr PHOTON

2. Noble Gas Effluent Monitors a) UNIT VENT i Mid Range* -2 to 3 (VRS-1507) 1, 2, 3 2.5x10 10 p Ci/cc ii (VRS-1509)

High Range 1I 2I 3 10 to 10 5

pCi/cc b) Atmospheric Steam Dump Valves 5

Discharge 1/Loop 1, 2, 3 3 to 10 pCi/cc (1) c) Gland Seal Exhaust Mid Range -2 3 (SRA-1807) 1/ 2i 3 2. Sxl0 to 10 pCi/cc d) Condenser Exhaust (1)

System Mid Range -2 3 (SRA-1907) 1, 2, 3 2.5x10 to 10 pCi/cc

  • Automatic Switchover to High Range only Configuration (Alarm/Trip Setpoint is lxl0 ~Ci/cc)
    • Per Requirements of Specification 3.3.3.8 (1) These instruments are under special test operation mode for moisture concern, but are functionally OPERABLE.

TABLE 3.3-6A POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION MINIMUM CHANNELS APPLICABLE MEASUREMENT INSTRUMENT OPERABLE MODES RANGE ACTION

l. AREA MONITORS HIGH RANGE 7

Containment Area 1I 2I 3 1 to 10 rad/hr PHOTON

2. Noble Gas Effluent Monitors a) UNIT VENT
i. Mid Range>> -2 3 (VRS-2507) 1I 2I 3 2.5x10 to 10 pCi/cc ii. High Range 5 (VRS-2509) ~

1/ 2/ 3 10 to 10 >Ci/cc b) Atmospheric Steam Dump Valves 5

Discharge 1/Loop 1, 2, 3 3 to 10 >Ci/cc c) Gland Seal (1)

Exhaust Mid Range -2 3 (SRA-2807) 1I 2I 3 2.5x10 to 10 >Ci/cc d) Condenser Exhaust (1)

System Mid Range -2 3 (SRA-2907) 1I 2I 3 2.5x10 to 10 ~Ci/cc

  • Automatic Switchover to High Range only Configuration (Alarm/Trip Setpoint is lx10 ~Ci/cc)
    • Per Requirements of Specification 3.3.3.6 (1) These instruments are under special test operation mode for moisture concern, but are functionally OPERABLE.

7 TABLE 4.3-3A POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS O

00 CHANNEL MODES FOR WHICH CHANNEL CHANNEL FUNCTIONAL SURVEILLANCE IS I INSTRUMENT CHECK CALIBRATION t3 1. AREA MONITORS High Range Containment Area N/A 1I 2I 3

2. Noble Gas Effluent Monitors a) Unit Vent
i. Mid'ange (VRS-1507) 1I 2I 3 ii. High Range (VRS-1509) N/A 1, 2, 3 b) Atmospheric Steam Dump Valve Discharge M R N/A 1, 2, 3 c) Gland Seal Exhaust (1)

Mid Range (SRA-1807) N/A 1I 2I 3 (1) d) Condenser Exhaust System Mid Range (SRA-1907) N/A 1, 2, 3 0

  • Acceptable criteria for calibration are provided in Table II.F.1-3 of NUREG-0737.

(1) These insgrpnents concern, u .are functxona sp8gjg pgst operation mode for moisture are undey ly-

O TABLE 4.3-3A A

O Q

POST-ACCIDENT RADIATION MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS I

CHANNEL MODES FOR WHICH CHANNEL CHANNEL FUNCTIONAL SURVEILLANCE IS INSTRUMENT CHECK CALIBRATION

1. AREA MONITORS High Range Containment Area N/A 1, 2, 3
2. Nob'le Gas Effluent'onitors a) Unit Vent

.i. Mid Range (VRS-2507) 1/ 2I 3 ii. High Range (VRS-2509) N/A 1I 2I 3 b) Atmospheric Steam Dump Valve Discharge N/A 1I 2I 3 c) Gland Seal Exhaust (1)

,Mid Range (SRA-2807) N/A 1I 2I 3 (1) d) Condenser Exhaust System Mid Range (SRA-2907) N/A 1, 2, 3 0

  • Acceptable criteria for calibration are provided in Table II.F.1-,3 of NUREG-0737.

(1) These instruments are under special test operation mode for moisture concern, nut are functionally SBPutBFR..

a TABLE 3.3 POST-ACCIDENT MONITORING INSTRUMENTATION INSTRUMENT MINIMUM CHANNELS OPERABLE

1. Containment Pressure
2. Reactor Coolant Outlet Temperature T (Wide Range)
3. Reactor Coolant Inlet Temperature T (Wide Range)
4. Reactor Coolant Pressure Wide Range
5. Pressurizer Water Level
6. Steam Line Pressure 2/Steam Generator
7. Steam Generator Water Level Narrow Range 1/Steam Generator
8. Refueling Water Storage Tank Water Level

, 9. Boric Acid Tank Solution Level

10. Auxiliary Feedwater Flow Rate 1/Steam Generator*

ll. Reactor Coolant System Subcooling Margin Monitor

12. PORV Position Indicator Limit Switches*** 1/Valve
13. PORV Block Valve Position Indicator Limit Switches 1/Valve
14. Safety Valve Position Indicator - Acoustic. Monitor 1/Valve
15. Containment Water Level (Narrow Range)
16. Containment Water Level (Wide Range)
17. Radiation Monitoring Channels Per Table 3.3-6A 0
  • Steam Generator Water Level Channels can be used as a substitute for the corresponding auxiliary feedwater flow. rate channel instrument.
    • PRODAC 250 subcooling margin readout can be used as a substitute for the subcooling monitor instrument.
      • Acoustic monitoring of PORV position (1 channel per three valves headered discharge)

. can be used as a substitute for the pORV position Indicator Limit Switches instruments.

A A

TABLE 3.3-10 oO POST-ACCIDENT MONITORING INSTRUMENTATION I

INSTRUMENT MINIMUM CHANNELS OPERABLE H

1. Containment Pressure
2. Reactor Coolant Outlet Temperature T (Wide Range)
3. Reactor Coolant Inlet Temperature T (Wide Range) 2
4. Reactor Coolant Pressure Wide Range
5. Pressurizer Water Level
6. Steam Line Pressure 2/Steam Generator
7. Steam Generator Water Level Narrow Range 1/Steam Generator
8. Refueling Water Storage Tank Water Level
9. Boric Acid Tank Solution Level
10. Auxiliary Feedwater Flow Rate 1/Steam Generator*
11. Reactor Coolant System Subcooling Margin Monitor
12. PORV Position Indicator Limit Switches*** 1/Valve
13. PORV Block Valve Position Indicator Limit Switches 1/Valve
14. Safety Valve Position Indicator Acoustic Monitor 1/Valve
15. Containment Water Level (Narrow Range)
16. Containment Water Level (Wide Range)
17. Radiation Monitoring Channels Per Table 3.3-6A 0
  • Steam Generator Water Level Channels can be used as a substitute for the corresponding auxiliary feedwater flow rate channel instrument.
    • PRODAC 250 subcooling margin readout can be used as a substitute for the subcooling monitor instrument.
      • Acoustic monitoring of PORV position (1 channel per three valves headered discharge) can be used as a substitute for the PORV Position Indicator - Limit Switches instruments.

TABLE 4.3-7 POST-ACCIDENT MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS CHANNEL CHANNEL INSTRUMENT CHECK CALIBRATION

1. Containment Pressure
2. Reactor Coolant Outlet Temperature T (Wide Range) 3 Reactor Coolant Inlet Temperature TCOLD (Wide Range)
4. Reactor Coolant Pressure Wide Range
5. Pressurizer Water Level
6. Steam Line Pressure
7. Steam Generator Water Level Narrow Range
8. RWST Water Level
9. Boric Acid Tank Solution Level
10. Auxiliary Feedwater Flow Rate

/

11. Reactor Coolant System Subcooling Margin Monitor
12. PORV Position Indicator Limit Switches
13. PORV Block Valve Position Indicator Limit Switches
14. Safety Valve Position Indicator Acoustic Monitor R
15. Containment Water Level (Narrow Range) N/A
16. Containment Water Level (Wide Range) N/A
17. Radiation Monitoring Channels (Per Table 4.3-3A)

"TABLE 4.3-10 POST-ACCIDENT MONITORING INSTRUMENTATION SURVEILLANCE RE UIREMENTS CHANNEL CHANNEL INSTRUMENT CHECK CALIBRATION

1. Containment Pressure
2. Reactor Coolant Outlet Temperature T (Wide Range)
3. Reactor Coolant Inlet Temperature T (Wide Range)
4. Reactor Coolant Pressure Wide Range
5. Pressurizer Water Level
6. Steam Line Pressure
7. .Steam Generator Water Level Narrow Range
8. RWST Water Level
9. Boric Acid Tank Solution Level
10. Auxiliary Feedwater Flow Rate R
11. Reactor Coolant System Subcooling Margin Monitor
12. PORV Position Indicator Limit Switches
13. PORV Block Valve- Position Indicator Limit Switches
14. Safety Valve Position Indicator Acoustic Monitor
15. Containment Water Level (Narrow Range) N/A
16. Containment Water Level (Wide Range) N/A
17. Radiation Monitoring Channels (Per Table 4.3-3A)

CONTAINMENT SYSTEMS 3/4.6.4 COMBUSTIBLE GAS CONTROL HYDROGEN ANALYZERS LIMITING CONDITION FOR OPERATION 3.6.4.1 Two containment hydrogen analyzers shall be OPERABLE.

APPLICABILITY: MODES 1 and 2 ACTION:

a0 With one hydrogen analysis device inoperable, restore the inoperable analysis device to OPERABLE status within 30 days 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 />.

b. With both hydrogen analysis devices inoperable, restore at least one analysis device to OPERABLE status within 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> 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 />.

SURVEILLANCE RE UIREMENTS 4.6.4.1 Each hydrogen analysis device shall be demonstrated OPERABLE at least once per 92 days on a STAGGERED TEST BASIS by performing a CHANNEL CALIBRATION using a four percent and fifteen percent nominal hydrogen gas, balance nitrogen.

D. C. COOK UNIT 1 3/4 6-23 Amendment No.

CONTAINMENT SYSTEMS 3/4.6.4 COMBUSTIBLE GAS CONTROL HYDROGEN ANALYZERS LIMITING CONDITION FOR OPERATION 3.6.4.1 Two containment hydrogen analyzers shall be OPERABLE.

APPLICABILITY: Modes 1 and 2.

ACTION:

a. With one hydrogen analysis device inoperable, restore the inoperable analysis device to OPERABLE status within 30 days 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 />.
b. With both hydrogen analysis devices inoperable, restore at least one analysis device to OPERABLE status within 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> 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 />.

SURVEILLANCE RE UIREMENTS 4.6.4.1 Each hydrogen analysis device shall be demonstrated OPERABLE at least once per 92 days on a STAGGERED TEST BASIS by performing a CHANNEL CALIBRATION using a four percent and fifteen percent nominal hydrogen gas, balance nitrogen.

D. C. COOK UNIT 2 3/4 6-33 Amendment No.

INSTRUMENTATION CHLORINE DETECTION SYSTEM LIMITING CONDIT1ON FOR OPERATION 3.3.3.11 The chlorine detection system, with its alarm setpoint adjusted to actuate at a chlorine concentra'tion of less than or equal to 5 ppm,

,shall be OPERABLE.

APPLICABILIY: All MODES.

ACTION:

a0 With the chlorine detection system inoperable, within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> initiate and maintain operation of the control room emergency ventilation system in the recirculation mode of operation.

b. The provisions of Specifications 3.0.4 are not applicable.

SURVEILLANCE RE UIREMENTS 4.3.3.11 The chlorine detection system shall be demonstrated OPERABLE by performance of a CHANNEL FUNCTIONAL TEST at least once per 31 days and a CHANNEL CALIBRATION at least once per 18 months.

D. C. COOK UNIT 1 3/4 3-69 Amendment No.

INSTRUMENTATION CHLORINE DETECTION SYSTEM LIMITING CONDITION FOR OPERATION 3.3.3.11 The chlorine detection system, with its alarm setpoint adjusted to actuate at a chlorine concentration of less than or equal to 5 ppm, shall be OPERABLE.

APPLICABILITY: ALL MODES.

ACTION:

a0 With the chlorine detection system inoperable, within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> initiate and maintain operation of the control room emergency ventilation system in the recirculation mode of operation.

b. The provisions of Specification 3.0.4 are not applicable.

SURVEILLANCE RE UIREMENTS 4.3.3.11 The chlorine detection system shall be demonstrated OPERABLE by performance of a CHANNEL FUNCTIONAL TEST at least once per 31 days and a CHANNEL CALIBRATION at least once per 18 months.

D. C. COOK UNIT 2 3/4 3-64a Amendment No.

I INSTRUMENTATION BASES 3/4 '.3.9 RADIOACTIVE LI UID EFFLUENT INSTRUMENTATION The radioactive liquid effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in liquid effluent during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits of 10 CFR Part 20. The OPERABILITY and use of this instrumentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for the Donald C. Cook Nuclear Plant.

3/4.3.3.10 RADIOACTIVE GASEOUS EFFLUENT INSTRUMENTATION The radioactive gaseous effluent instrumentation is provided to monitor arid control, as applicable, the releases of radioactive materials in gaseous effluents during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits. This instrumentation also includes provisions for monitoring the concentrations of potentially explosive gas mixtures in the waste gas holdup system. The OPERABILITY and use of this instru-mentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for the Donald C. Cook Nuclear Plant.

3/4.3.3.11 CHLORINE DETECTION SYSTEM The OPERABILITY of the detection system ensures that sufficient capability is available to promptly detect and initiate protective action in the event of an accidental chlorine release. This capability is required to protect control room personnel and is consistent with the recommendations of Regulatory Guide 1.95, "Protection of Nuclear Power Plant Control Room Operators Against an Accidental Chlorine Release," February, 1975.

D. C. COOK UNIT 1 B 3/4 3-5 Amendment No.

3/4.3 INSTRUMENTATION BASES 3/4.3.3.8 FIRE DETECTION INSTRUMENTATION OPERABILITY of the fire detection instrumentation ensures that adequate warning capability is available for the prompt detection of fires. This capability is required in order to detect and locate fires in their early stages. Prompt detection of fires will reduce the potential for damage to safety-related equipment and is an integral element in the overall facility fire protection program.

In the event that a portion of the fire detection instrumentation is inoperable, the establishment of frequent fire patrols in the affected areas is required to provide detection capability until the inoperable instrumentation is returned to service.

3/4.3.3.9 RADIOACTIVE LI UID EFFLUENT INSTRUMENTATZON The radioactive liquid effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in liquid effluents during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits. The OPERABILITY and use of this instrumentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for the Donald C. Cook Nuclear Plant.

3/4.3.3.10 RADIOACTIVE GASEOUS EFFLUENT INSTRUMENTATION The radioactive gaseous effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in gaseous effluents during actual or potential releases. The alarm/trip setpoints for these instruments shall be calculated in accordance with NRC approved methods in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits of 10 CFR Part 20. This instrumentation also includes provisions for monitoring the concentrations of potentially explosive gas mixtures in the waste gas holdup system. The OPERABILITY and use of this instrumentation is consistent with the requirements of General Design Criteria specified in Section 11.3 of the Final Safety Analysis Report for

, the Donald C. Cook Nuclear Plant.

3/4.3.3.11 CHLORINE DETECTION SYSTEM The OPERABILITY of the detection system ensures that sufficient capability is available to promptly detect and initiate protective action in the event of an accidental chlorine release. This capability is required to protect control room personnel and is consistent with the recommendations of Regulatory Guide 1.95, "Protection of Nuclear Power Plant Control Room Operators Against an Accidental Chlorine Release," February, 1975.

D. C. COOK UNIT 2 B 3/4 3-3 Amendment No.

3/4 3.4 TURBINE OVERSPEED PROTECTION h

This specification is provided to ensure that the turbine overspeed protection instrumentation and the turbine speed control valves are OPERABLE and will protect the turbine from excessive overspeed. Protection from turbine excessive overspeed is required since excessive overspeed of the turbine could generate potentially damaging missiles which could impact and damage safety related components, equipment or structures.

D. C. COOK. UNIT 2 B 3/4 3-4 Amendment No.

PLANT SYSTEMS 3/4.7.5 CONTROL ROOM EMERGENCY VENTILATION SYSTEM LIMITING CONDITION FOR OPERATION 3.7.5.1 The control room emergency ventilation system shall be OPERABLE with:

a. Two independent heating and cooling systems,
b. Two independent pressurization fans, and
c. One charcoal absorber and HEPA filter train.

APPLICABILITY: ALL MODES.

ACTION:

MODES 1, 2, 3, and 4:

With one heating and cooling system inoperable, restore the inoperable system to OPERABLE status within 7 days 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 in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />.

b. With one pressurization fan inoperable, restore the inoperable fan to OPERABLE status within 7 days 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 in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />.
c. With the filter train inoperable, restore the filter train to OPERABLE status within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> 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 in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. P MODES 5 and 6:
d. With one pressurization fan inoperable, do one of the following: (1) restore the inoperable fan to OPERABLE status within 7 days, or (2) initiate and maintain operation of the remaining OPERABLE pressurization fan and the filter train in a recirculation mode, or (3) suspend all operations involving CORE ALTERATIONS or positive reactivity changes.
e. With any of the following (1) both heating and cooling systems; (2) both pressurization fans;,(3) the filter train> inoperable, suspend all operations involving CORE ALTERATIONS or positive 'reactivity changes.

SURVEILLANCE RE UIREMENTS 4.7.5.1 The control room emergency ventilation system shall be demonstrated OPERABLE:

a. At least once per 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> by 0

verifying that the control room air temperature is < 120 F.

D. C. COOK - UNIT 2 3/4 7-14 Amendment No.

PLANT SYSTEMS SURVEILLANCE RE UIREMENTS (Continued)

b. At least once per 31 days on a STAGGERED TEST BASIS by initiating flow through the HEPA filter and charcoal adsorber train and verifying that the system operates for at least 15 minutes.

co At least once per 18 months or (1) after any structural maintenance on the HEPA filter or charcoal adsorber housings, or (2) following painting, fire or chemical release xn any ventilation zone com-municating with the system by:

1. Verifying that the charcoal adsorbers remove > 99% of a halogenated hydrocarbon refrigerant test gas when they are tested in-place in accordance with ANSI N510-1975 while operating the ventilation system at a flow rate of

, 6000 cfm + 10%.

2. Verifying that the HEPA filter banks remove > 99% of the DOP when they are tested in-place in accordance with ANSI

.N510-1975 while operating the ventilation system at a flow rate of 6000 cfm + 10%.

3. Verifying within 31 days after removal that a laboratory analysis of a carbon sample from either at least one test canister or at least two carbon samples removed from one of the charcoal adsorbers demonstrates a removal efficiency of > 90% for radioactive methyl iodide when the sample is tested in accordance with ANSI N510-1975 (130 C, 95% R.H.).

The carbon samples not obtained from test canisters shall be prepared by either:

a) Emptying one entire bed from a removed adsorber tray mixing the adsorbent thoroughly, and obtaining samples at least two inches in diameter and with a length equal to the thickness of the bed, or b) Emptying a longitudinal sample from an adsorber tray, mixing the adsorbent thoroughly, and obtaining samples at least two inches in diameter and with a length equal to the thickness of the bed.

4. Verifying a.system flow rate of 6000 cfm + 10% during system operation when tested in accordance with ANSI N510-1975.
d. After every 720 hours0.00833 days <br />0.2 hours <br />0.00119 weeks <br />2.7396e-4 months <br /> of charcoal adsorber operation by either:

D. C. COOK UNIT 2 3/4 7-15 Amendment. No.

PLANT SYSTEMS 3/4. 7. 5 CONTROL ROOM EMERGENCY VENTILATION SYSTEM LZMITING CONDITION FOR OPERATION 3.7.5.1 The control room emergency ventilation system shall be OPERABLE with:

ao Two independent heating and cooling systems,

b. Two independent pressurization fans, and c~ One charcoal absorber and HEPA filter train.

APPLICABILITY: ALL MODES.

ACTION:

MODES 1, 2, 3, and 4:

a. With one heating and. cooling system inoperable, restore the inoperable system to OPERABLE status within 7 days 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 in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />.
b. With one pressurization fan inoperable, restore the inoperable fan to OPERABLE status within 7 days or be in at least HOT STANDBY within the next 6 hours and in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />.
c. With the filter train inoperable, restore the filter train to OPERABLE status within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> 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 in COLD SHUTDOWN within the following 30 hours.

MODES 5 and 6:

d. With one pressurization fan inoperable, do one of the following: (1) restore the inoperable fan to OPERABLE status within 7 days, or (2) initiate and maintain operation of the remaining OPERABLE pressurization fan and the filter train in a recirculation mode, or (3) suspend all operations involving CORE ALTERATIONS or positive reactivity changes.
e. .With, any of the following (1) both heating and cooling systems; (2) both pressurization fans; (3) the filter train; inoperable',. suspend all operations involving CORE ALTERATIONS or positive reactivity changes.

SURVEILLANCE RE UIREMENTS ~

4.7.5.1 The control room emergency ventilation system shall be demonstrated OPERABLE:

a. At least once pea'2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> 0 by verifying that the control room air temperature is < 120 F.

D. C. COOK UNIT 1 3/4 7-19 Amendment No.