ML050610207
| ML050610207 | |
| Person / Time | |
|---|---|
| Site: | Susquehanna  |
| Issue date: | 02/18/2005 |
| From: | Susquehanna |
| To: | Document Control Desk, Office of Nuclear Reactor Regulation |
| References | |
| 028401 | |
| Download: ML050610207 (35) | |
Text
Feb. 18, 2005 Page 1 of 2 MANUAL HARD COPY DISTRIBUTION DOCUMENT TRANSMITTAL 2005-7762 USER INFORAON CH*RO M EMPL#:028401 CA#: 0363 Addr CSA2 Phone T SITTAL INFORMATION:
TO: ' r ,/18/2O05 LOCATION: USNRC FROM: NUCLEAR RECORDS DOCUMENT CONTROL CENTER (NUCSA-2)
THE FOLLOWING CHANGES HAVE OCCURRED TO THE HARDCOPY OR ELECTRONIC MANUAL ASSIGNED TO YOU:
TSB1 - TECHNICAL SPECIFICATION BASES UNIT 1 MANUAL REMOVE MANUAL TABLE OF CONTENTS DATE: 01/25/2005 ADD MANUAL TABLE OF CONTENTS DATE: 02/17/2005 CATEGORY: DOCUMENTS TYPE: TSB1 ID: TEXT 3.1.6 REMOVE: REV:O ADD: REV: 1 CATEGORY: DOCUMENTS TYPE: TSB1 ID: TEXT 3.3.2.1 REMOVE: REV:0
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SSES MANUAL
. zlo f Manual Name: TSE1 Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1 MANUAL Table Of Contents Issue Date: 02/17/2005 Procedure Name : - Rev - Issue Date Change ID Ihange Number TEXT LOES 57 02/17/2005
Title:
LIST OF EFFECTIVE SECTIONS TEXT TOC 6 02/17/2005
Title:
TABLE OF CONTENTS TEXT 2.1.1 1 04/27/2004
Title:
SAFETY LIMITS (SLS) REACTOR CORE SLS TEXT 2.1.2 0 11/15/2002
Title:
SAFETY LIMITS (SLS) REACTOR COOLANT SYSTEM (RCS) 'PRESSURE SL TEXT 3.0 0 11/15/2002 ^
Title:
LIMITING CONDITION FOR OPERATION7(LCO) APPLICABILITY TEXT 3.1.1 0 / !11/15/2002
Title:
REACTIVITY CONTROL SYSTEMS, SHUTDOWN MARGIN (SDM)
TEXT 3.1.2 0. 11/15/2002
Title:
REACTIVITY CONTROL SYSTEMS REACTIVITY ANOMALIES TEXT 3.1.3 , 0 11/15/2002
Title:
REACTIVITY CONTROL SYSTEMS CONTROL ROD OPERABILITY
-~ .- ¶ 1nInflfn)
TEXT 3.1.4 u . L L.L J Ia"uu.
Title:
REACTIVITY CONTROL SYSTEMS CONTROL ROD* SCRAM TIMES TEXT 3.1.5 0 11/15/2002
Title:
REACTIVITY CONTROL SYSTEMS CONTROL ROD SCRAM ACCUMULATORS TEXT 3.1.6 1 02/17/2005
Title:
REACTIVITY CONTROL SYSTEMS ROD PATTERN CONTROL
. - . - L - . . - , - I-Report Date: 02/17/05 PagelI Page of of 8
- 8. Report Date: 02/17/05
.SSES MANUAL Manual Name: TSB1
. Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1 MANUAL TEXT 3.1.7 0 11/15/2002
Title:
REACTIVITY CONTROL SYSTEMS STANDBY LIQUID CONTROL (SLC) SYSTEM TEXT 3.1.8 0 11/15/2002
.Title:-REACTIVITY CONTROL SYSTEMS SCRAM DISCHARGE VOLUME (SDV) -VENT AND DRAIN VALVES TEXT 3.2.1 0 11/1512002' Titln: POWER DISTRIBUTION LIMITS AVERAGE PLANAR LINEAR HEAT'GENERATIdN RATE (APL11GR)
TEXT 3.2.2 0 11/15'/2002
Title:
POPER DISTRIBUTION LIMITS MINIMUMWCRITICAL POWiER RATIO (MCPR)
TEXT 3.2.3 0 11/15/2002 '
Title:
'POWER DISTRIBUTION'LINITS".LINEAR HEAT. GENERATION. RATE (LHGR)
TEXT 3.2.4 0 11/15/2002 .
Title:
POWER DISTRIBUTION LIMITS AVERAGE'POWER-'RANGE'MONITOR. (APRM) GAIN AND SETPOINTSKj TEXT 3.3.1.1 0 11/15/2002
Title:
INSTRUMENTATION REACTOR PROTECTION SYSTEM (RPS) -INSTRUMENTATION TEXT 3.3.1.2 0 11/15/2002
Title:
INSTRUMENTATION SOURCE'RANGE MONITOR (SRM) INSTRUMENTATION TEXT 3.3.1.3 0 . 11/22/2004 :
Title:
OPRM INSTRUMENTATION TEXT 3.3.2.1 1 02/17/2005
Title:
.INSTRUMENTATIONTCONTROL ROD BLOCK INSTRUMENTATION TEXT 3.3.2.2 0- 11/15/2002
Title:
INSTRUMENTATION FEEDWATER - MAIN-TURBINE HIGH WATER LEVEL'TRIP INSTRUMENTATION TEXT 3.3.3.1 0 11/15/2002
Title:
INSTRUMENTATION POST ACCIDENT MONITORING (PAM) INSTRUMENTATION LDCN 3702 "
Pag of 8IRIport D.e 02/17/05 Page 2 of 8 Report Date: 02/17/05-
- .SSES 4ANUAL Xanual Name,: TSB1 Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT'l.MANUAL; '-
TEXT 3.3.3.2 0 11/15/2002',.:. -
Title:
INSTRUMENTATION REMOTE.SHUTDOWN SYSTEM . .
TEXT 3.3.4.1 0 11/15/2002
Title:
INSTRUMENTATION END OF CYCLE:RECIRCULATION:PUMP TRIP (EOC-RPT) INSTRUMENTATION TEXT 3.3.4.2 0 11/1512002
Title:
-INSTRUMENTATION-ANTICIPATED TRANSIENTi-WITHOUT.SCRAM RECIRCULATION.PUMP TRIP..
(ATWS-RPT) INSTRUMENTATION TEXT 3.3.5.1 1 01/24/2005-.: :.. .
Title:
INSTRUMENTATION,.EMERGENCY.CORE COOLING.:SYSTEM: (ECCS) INSTRUMENTATION. :Z -
TEXT 3.3.5.2 0 11/1512002 :.-
Title:
INSTRUMENTATION REACTORCORE ISOLATIONTCOOLING:':(RCIC). SYSTEN"INSTRUMENTATION' TEXT 3.3.6.1 1 11/09/2004:..--
U '.
Title:
INSTRUMENTATION PRIMARY.;CONT.AINMENT. ISOLATION.'INSTRUMENTATION 4 TEXT 3.3.6.2 1 11/'09/2004'..:
Title:
INSTRUMENTATION- SECONDARY CONTAINMENT ISOLATION-INSTRUMENTATION .: '
TEXT 3.3.7.1 0 11/15/2002.:.,
Title:
INSTRUMENTATION.CONTRPL ROOM EMERGENCY,,OUTSIDE AIRLSUPPLY jCREOAS)'SYSTEM-INSTRUMENTATION TEXT 3.3.8.1 1 09/02/2004
Title:
INSTRUMENTATIONLOSS OF POWER' (LOP) INSTRUMENTATION ; '
TEXT 3.3.8.2 0 11/15/2002' .- .
,Title: INSTRUMENTATION REACTORPROTECTION::SYSTEM (RPS):ELECTRIC POWER-MONITORING TEXT 3.4.1 2 11/22/2004 .
Title:
REACTOR COOLANT SYSTEM .(RCS) RECIRCULATION LOOPS'OPERATING-.::
TEXT 3.4.2 0 11/15/2002 , -
Title:
REACTOR COOLANT SYSTEM (RCS) JETPUMPS.
I _ .,.. ... . '.7 Report Date: 02/17/05 Page33 Page of-8 of -8, - . Report Date: 02/17/05 -
m -
.SSES MAQUAL
/i Manual Nam : TSB1 .v,9 Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1 MANUAL:---
TEXT 3.4.3 0 11/15/2002.
Title:
REACTOR COOLANT SYSTEM (RCS) SAFETY/RELIEF VALVES '(S/RVS)
TEXT 3.4.4 0 11/15/2002
Title:
REACTOR COOLANT SYSTEM (RCS) RCS OPERATIONAL LEAKAGE TEXT 3.4.5 0 21/15/2002
Title:
REACTOR COOLANT.SYSTEM-(RCS); RCS PRESSURE ISOLATION;VALVE.(PIV) LEAKAGE--
TEXT 3.4.6 0 11/15/2002
Title:
REACTOR COOLANT.SYSTEM (RCS) RCS ',FKFAGE;DETECTION INSTRUMENTATION .
TEXT 3.4.7 0 11/15/2002
Title:
REACTOR COOLANT SYSTEM (RCS) .RCS SPECIFIC ACTIVITY. ':.
TEXT 3.4.8 0 11/15/2002
Title:
REACTOR COOLANT.SYSTEM- (RCS) RESIDUAL HEAT'REMOVAL (RHR) SHUTDOWN COOLING' SYSTE1'_,
- HOT SH[UTDOWN TEXT 3.4.9 0 11/15/2002 -'
Title:
REACTOR COOLANT' SYSTEM. (RCS) RESIDUAL,,HEAT REMOVAL (RHR) SHUTDOWN COOLING SYSTEM
- COLD S;HUTDOWN TEXT 3.4.10 0 11/15/2002,. e
Title:
REACTOR COOLANT SYSTEM (RCS) RCS PRESSURE AND TEMPERATURE (P/T) LIMITS TEXT 3.4.11 0 11/15/2002
Title:
REACTOR COOLANT SYSTEM (RCS) REACTOR:STEAM DOME PRESSURE.
TEXT 3.5.1 0 11/15/2002
Title:
EMERGENCY CORECOOLING SYSTEMS (ECCS) AND REACTOR CORE ISOLATION COOLING (RCIC)
SYSTEM ECCS - OPERATING TEXT 3.5.2 0 11/15/2002
Title:
EMERGENCY CORE-COOLING SYSTEMS (ECCS) AN4D.REACTOR'CORE ISOLATION COOLING (RCIC)
SYSTEM ECCS - SHUTDOWN TEXT 3.5.3 0 11/15/2002,
Title:
EMERGENCY CORE COOLING SYSTEMS (ECCS) AND REACTOR CORE ISOLATION COOLING'(RCIC)
SYSTEM RCIC SYSTEM Pag e 4 -'of 8 . Report Date:'02/17/05 C
-. SSES .NANUAL
- Manual Name
- TSB1 Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1-.MANUAL...
TEXT 3.6.1.1 0 11/15/2002 .
Title:
CONTAINMENT SYSTEMS-PRIMARY CONTAINMENT TEXT 3.6.1.2 0 11/15/2002-.: .
Title:
CONTAINMENT SYSTEMS PRIMARY CONTAINMENT -AIR LOCK'-; ' I'--
TEXT 3.6.1.3 0 11/15/2002
Title:
CONTAINMENT SYSTEMS PRIMARY .CONTAINMENT ISOLATION VALVES (PCIVS)
LDCN 3092 TEXT 3.6.1.4 0 11/152002
Title:
CONTAINMENT SYSTEMS CONTAINMENT-T-PRESSURE' :
TEXT 3.6.1.5 0 11/15/-20'02.-:
Title:
CONTAINMENT SYSTEMS DRYWELL.:AIR'TEMPERATURE .. ' .-- '. '.
TEXT 3.6.1.6 0 11/15/2002 : -
K
Title:
CONTAINMENT SYSTEMS SUPPRESSIONiCH2.MIBER-TO-DRYWEll VACUU=M BREAKERS TEXT 3.6.2.1 0 11/15/2002
Title:
CONTAINM1ENT -SYSTEMS SUPPRESSION POOL AVERAGE TEMPERATURE TEXT 3.6.2.2 0 11/15/2002'. ' ;
Title:
CONTAINMENT SYSTEMS SUPPRESSION-POOL'.WATER LEVEL TEXT 3.6.2.3 0 11/15/2002--
Title:
CONTAINMENT SYSTEMS RESIDUAL HEAT REMOVAL (RHR) SUPPRESSION POOL COOLING TEXT 3.6.2.4 0 11/15/2002'. -.-
Title:
CONTAINMENT. SYSTEMS RESIDUAL HENT -REMOVAL (RHR) `SUPPRESSION: POOL SPRAY-TEXT 3.6.3.1 0 11/15/2002
Title:
CONTAINMENT.SYSTEMS PRIMARY,,CONTAINMENT HYDROGEN.RECOMBINERS -' -:
TEXT 3.6.3.2 0 11/15/2002,.--
Title:
CONTAINMENT SYSTEMS DRYWELL:AIR FLOW,-SYSTEM - , ,. ,
Page 5 of 8 .t.Dae'2/ R Report Date: 02/17/OS0'
lIX SSES MANUAL.
'If Manual Name: TSB1 t . .
Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1iMANUAL' TEXT 3.6.3.3 0 11/.15/2002
Title:
CONTAINMENT SYSTEMS PRIMARY CONTAINMENT OXYGEN CONCENTRATION TEXT 3.6.4.1 1 01/03/2005
Title:
CONTAINMENT SYSTEMS SECONDARY CONTAIJMENT. '* -.
TEXT 3.6.4.2 2 01/03/2005
Title:
CONTAINMENT i SYSTEMS SECONDARY CONTAINMENT ISOLATION VALVES (SCIVS)
TEXT 3.6.4.3 2 11/09/2004 .
Title:
CONTAINMENT SYSTEMS STANDBY GAS' TREATMEN?- (SGT) 'SYSTEM I"'
TEXT 3.7.1 0 11/15/2002'
Title:
PLANT SYSTEMS RESIDUAL. HEAT? REMOVAL;:SERVICE WATER (RI-HRSW) SYSTEM AND THE' ULTIMATE HEAT SINK (UHS)
TEXT 3.7.2 1 11/09/2004 .
Title:
PLANT SYSTEMS EMERGENCY SERVICE'WATER. (ESW)-SYSTEM ; ' "
TEXT 3.7.3 0 11/15/2002
Title:
PLANT SYSTEMS CONTROL ROOM'EMERGENCY OUTSIDE AIR'SUPPLY (CREOAS) SYSTEM TEXT 3.7.4 0 11/15/2002
Title:
PLANT SYSTEMS CONTROL'ROOM FLOOR COOLING"'SYSTEM TEXT 3.7.5 0 11/15/2002
Title:
PLANT SYSTEMS MAIN CONDENSER OFFGAS -
TEXT 3.7.6 1 01/17/2005
Title:
PLANT SYSTEMS MAIN TURBINE BYPASS SYSTEM TEXT 3.7.7 0 11/15/2002
Title:
PLANT SYSTEMS SPENT FUEL STORAGE POOL WIATER LEVEL TEXT 3.8.1 1 10/17/2003
Title:
ELECTRICAL POWER SYSTEMS AC SOURCES - OPERATING 1 Page 6 of 8, Report Date: 02/17/05
' SSES MANUAL J . _ .
Manual Ntaye: TSB1 Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1 MANUAL TEXT 3.8.2 0 11/15/2002 .
Title:
ELECTRICAL,,POWERSYSTEMS AC SOURCES.-'SHUTDOWN TEXT 3.8.3 0 11/15/2002'
Title:
ELECTRICAL POWER.SYSTEMS DIESEL.,FUEL'-;.OIL,::.LUBE OIL; AND STARTING AIR TEXT 3.8.4 0 11/15/2002.,
Title:
ELECTRICAL POWER- SYSTEMS, DC SOURCES:.-:.,OPERATING, - '
TEXT 3.8.5 0 11/15/,2002., I
Title:
ELECTRICAL POWER-SYSTEMSDC SOURCES,;-' SHUTDOWN'- " -: - -' : 1 . :.
TEXT 3.8.6 0 11L15/20P02
Title:
ELECTRICAL POWER SYSTEMS.BATTERY:'CELL,'PARAMETERS .'.
TEXT 3.8.7 0 il/15/2002_
Q>
Title:
.ELECTRICAL POWER.SYSTE1S 'DISTRIBUTION SYSTEMS - OPERATING
TEXT 3.8.8 0 11/15/2002
Title:
ELECTRICAL POWER-SYSTEMS . DISTRIBUTIQNSYSTEMS - SHUTDOWN:
TEXT 3.9.1 0 11/,15/2002 ,
Title:
REFUELING OPERATIONS REFUELING.'EQUIPMENT.INTERLOCKS .
TEXT 3.9.2 0 !' 11/15/2002! 1
Title:
REFUELING OPERATIONS REFUEL POSITION ONE-ROD-OUT INTERLOCK TEXT 3.9.3 0 11/15/2002.; f
. . I
Title:
REFUELING OPERATIONS -CONTROL RQD;POSIT.IQN .' I .:-' . .
TEXT 3.9.4 0 11/15/2002 ' '
Title:
REFUELING OPERATIONS.CONTROL ROD POSITION INDICATION-. :-
TEXT 3.9.5 0 11/15/2002
Title:
REFUELING OPERATIONS CONTROL,,ROD OPERABILITY - REFUELING Report Date: 02/17/05 Page77 ,
Page of.88 .
-of.. Report Da~te: 02/17/05
SSES MANUAL Manual Name: TSB1 Manual
Title:
TECHNICAL SPECIFICATION BASES UNIT 1 MANUAL TEXT 3.9.6 0 11/15/2002 -
Title:
REFUELING OPERATIONS REACTOR PRESSURE VESSEL (RPV) WATER LEVEL
.. . I TEXT 3.9.7 0 11/15/2002
Title:
REFUELINGG OPERATIONS RESIDUAL HEAT' REMOVAL (RHR) - HIGH WYATER LEVEL
.. . .. L W TEXT 3.9.8: 0 11/15/2002-
Title:
REFUELIN OPERATIONS RESIDUAL HEAT REMOVAL (RHR) '--L:OW WATER LEVEL TEXT 3.10.1 0 11/15/2002
Title:
SPECIAL OPERATIONS INSERVICE LEAK AND. HYDROSTATICY TESTING OPERATION TEXT 3.10.2 0 11/15/2002
Title:
SPECIAL OPERATIONS REACTORM MODE SWITCH INTERLOCK TESTING.
TEXT 3.10.3 0 11/15/2002
Title:
SPECIAL OPERATIONS SINGLE CONTROL ROD WITHDRAWAL - HOT SHUTDOWN TEXT 3.10.4 0 - 11/15/20021:.;
Title:
SPECIAL OPERATIONS SINGLE CONTROL ROD WITHDRAWAL - COLD: SHUTDOWN TEXT 3.10.5 0.11/15/2002-
Title:
SPECIAL OPERATIONS SINGLE CONTROL ROD bRIVE' (CRD) REMOVAL - REFUELING TEXT 3.10.6 0 11/15/2002
Title:
SPECIAL OPERATIONS MULTIPLE CONTROL ROD WITHDRAWAL - REFUELING TEXT 3.10.7 0 .11/15/2002
Title:
SPECIAL OPERATIONS CONTROL ROD TESTING - OPERATING TEXT 3.10.8 11/15/2002
Title:
SPECIAL OPERATIONS SHUTDOWN MARGIN (SbM) TEST - REFUELING Report Date: 02/17/05 Page 8 Page 8 of 8 of. 8 Report Date: 02/17/05
I
.i TABLE OF CONTENTS (TECHNICALSPECIFICATIONS BASES)
B2.0 SAFETY LIMITS (SLs) ............... : B2.0-1 B2.1.1 ReactorCore SLs ............... B2.0-1 B2.1.2 Reactor Coolant System (RCS) Pressure SL ..... B2.0-7 B3.0 LIMITING CONDITION FOR OPERATION (LCO) APPLICABILITY ..... B3.0-1 B3.0 SURVEILLANCE REQUIREMENT,(SR) APPLICABILITY .... ... B3.0-10'.
B3.1 REACTIVITY CONTROL SYSTEMS ......................... B3.1-1 B3.1 .1 Shutdown Margin (SDM),.:.; ..................... ; .; B3.1-1 B3.1.2 Reactivity Anornalies ............ ... 1-8....,
B3.1.3 -Cotrol Rod OPERABILITY..; ... .... B3.1-13 B3.1.4 Control Rod Scram Times ................. 7 I . ...... B3.1-22 B3.1.5 Control Rod Scram Accairrmlators .......................... -' .
". . : . B3.1-29' B3.1.6 Rod Pattern Control . ....... ...... .TS/B3.1-34)-
B3.1.7 'Standby Liquid Control (SLC) System ................................... B3.1-39 B3.1.8 Scram Discharge Volume (SDV) Vent and Drain Valves B3.I-47.
B3.2 POWR P£)WrER DISTRIBU~~~lON
- - DISTRIBUTION ~TSIB3.2-1 ........... SBt21
LIIS, LIMITS4,~.~ ........................... @>i@-r^;; *@
B3.2.1 Average Planar Linear Heat7Generatior Rate (APLHGR).TS/B3.2-1 B3.2.2 Minimum Critical PowerRabo'qACPR).TS/B3.2-5,.
B3.2.3 Linear Heat Generationiate-L.LHGR) .B3.2-io B3.2.4 Average Power:Range6 Whnif&r(APRM) 'Gain-' - - ' '
and Setpoints... .......B3.2-14 B3.3 INSTRUMENTATION . , '_. TS 1331 .3-1 B3.3.1 .1 ReactorjProtectio'h System (RPS) Instrumentation .................... TS/B3.3-1 B3.3.1 .2 SourceRange Monitor (SRM) Instrumentation . . TS/B3.3-35 B3.3.1.3 Oscillation Power Range Monitor (OPRM) . .TS/B3.3-43a B3.3.2.1 :onbtrl Rod Block Instrumentation ............................; .. TS/B3.3-44 B3.3.2.2 'F6'dar, Main Td Ugh Water Level Trip
. Instrumentation .B3.3-55 B3.3.3.1 fti-+Post Accident Monitoring (PAM) Instrumentation .TS/B3.3-64 B3.3.3.2 RRemote Shutdown System. ........................ . ... .. ;.. B3.3-76 B3.3.4.1 JEndof Cycle Recirculation Pump Trip (EOC-RPT)
Instrumentation ......... - .. B3.3-81 B3.3.4.2 Anticipated Transient WVthout Scram Recirculation Pump Trip. (A1WS-RPT) instrumentation . ............................... B3:3-92 B3.3.5.1 Emergency Core Cooling System (ECCS)
Instrumentation .. B3.3-101 B3.3.5.2 -Reactor Core Isolation Cdoling (RCIC) System ' .
Instrumentation. -... ............. :.;-.;.;. B3.3-135 B3.3.6.1 Primary Containment Isolation Instrumentation . .....................B3.3-147 B3.3.6.2 Secondary Containment Isolation Instrumentation .. TS/B3.3-180 B3.3.7.1 Control Room Emergency Outside Air Supply,(CREOAS) ,
-System Instrumentation.. B3.3-192 K* )
(continued)
- - SUSQUEHANNAUNIT'1 TS/BTOC- 1 Revision 6 L. _,
l I- I TABLE OF CONTENTS (TECHNICAL SPECIFICATIONS BASES)
B3.3 INSTRUMENTATION (continued)
B3.3.8.1 Loss of Power (LOP) Instrumentation .......................... :.TStB3.3-205 B3.3.8.2 Reactor Protection System (RPS) Electric Power Monitoring ........ ; B3.3-213 B3.4 REACTOR COOLANT SYSTEM (RCS) .. B3.4-1 B3.4.1 Recirculation Loops Operating .. B3.4-1 B3.4.2 Jet Pumps.. B3.4-10 B3.4.3 Safety/Relief Valves (S/RVs) ...... TS/B3.4-15 B3.4.4 RCS Operational LEAKAGE' ...... B3.4-19 B3.4.5 RCS Pressure Isolation Valve (PIV) Leakage ................................ ;.B3.4-24 B3.4.6 RCS Leakage Detection Instrumentation .B3.4-30 B3.4.7' RCS Specific Activity ..................... B3.4-35 B3.4.8 Residual Heat Removal (RHR) Shutdown Cooling System - Hot Shutdown .................. B3.4-39 B3.4.9 Residual Heat Removal (RHR) Shutdown Cooling System - Cold Shutdown. B3.4-44 B3.4.10 RCS Pressure and Temperature (PMT) Limits TS/B3.4-49' B3.4.11 Reactor Steam Dome Pressure ..................... TS/B3.4-58 B3.5 EMERGENCY CORE COOLING SYSTEMS (ECCS) AND REACTOR CORE ISOLATION COOLING (RCIC) SYSTEM .................................. B3.&1 B3.5.1 ECCS - Operating .............. B3.5-1 B3.5.2 ECCS - Shutdown ............... : B3.5-19 B3.5.3 RCIC System .: .........-....... TS/B3.5-25 B3.6 CONTAINMENT SYSTEMS .................. ,.'........ TS/B3.6-1 B3.6.1.1 Primary Containment ............. TS/B3.6-1 B3.6.1.2 Primary Containment Air Lock .B3.6-7 B3.6.1.'3 Primary Containment Isolation Valves (PCIIVs) . . TS/B3.6-15 B3.6.1.4 Containment Pressure ....................... B3.6-41 B3.6.1.5 i Drywell Air Termperature . ... TS/B3.6-44 B3.6.1.6 i Suppression Chamber-to-Drywell Vacuum Breakers TS/B3.6-47 B3.6.2.1 Suppression Pool Average Temperature ........... B3.6-53 B3.6.2.2 Suppression Pool Water Level ............................. ;............ B3.6-59' B3.6.2.3 Residual Heat Removal,(RHR) Suppression Pool Cooling ........... B3.6-62 B3.6.2.4 Residual Heat Removal (RHR) Suppression Pool Spray .B3.6-66 B3.6.3.1 Primary Containment Hydrogen Recombiners .B3.6-70 B3.6.3.2 Drywell Air Flow.System ................................... B3.6-76 B3.6.3.3 Primarry Containment Oxygen Concentration ................................. B3.6-81 B3.6.4.1 Secondary Containment ................ -. ...... TS/B3.6-84 B3.6.4.2 Secondary Containment Isolation Valves (SCIVs .TS/B3.6-91 B3.6.4.3 StandbyGas Treatment (SGT) System ........................... TS/B3.6-101
- I (continued)
SUSQUEHANNA-UNIT 1 - ,
, TS / BTOC - 2 Revision 6 '
- v f
- TABLE OF CONTENTS (TECHNICAL SPECIFICATIONS BASES)
PL N Y T M ............................................ ................... T 13 .7-B3.7 PLANT SYSTEMS ;;;....;TSIB3.7-1 B3.7.1 Residual Heat Removal Service Water (RHRSW) System and the Ultimate Heat Sink (UHS) .TSIB3.7-1 B3.7.2 Emergency Service Water (ESW) System ............................. TS/B3.7-7 B3.7.3 Control Room Emergency Outside Air Supply (CREOAS) System ....... TS/B3.7-12 B3.7A Control Room Floor Cooling System ....... TS/B3.7-19 B3.7.5 Main Condenser Offgas ....... B3.7-24 B3.7.6 Main Turbine Bypass System ...............................
- TS/B3.7-27 B3.7.7 Spent Fuel Storage Pool Water Level .3.7-31 B3.8 ELECTRICAL POWER SYSTEM .TS/B3.8-1 B3.8.1 AC Sources - Operating .TS/B3.8-1 B3.8.2 ACSure - Shutdown..3,8-38
- ~~~~~~~~............................. AoreB.8-3 hton-....
B3.8.3 Diesel Fuel Oil, Lube Oil, and Starting Air . .... B3.8-45 B3.8.4 DC Sources - Operating .................... ;:;;....... TS/13.8-54 B3.8.5 DC Sources - Shutdown.8................... B3.8-66 B3.8.6 Battery Cell Parameters ...... B3.8-71 B3.8.7 Distribution Systems - Operating .B3.8-78 B3.8.8 Distribution Systems -Shutdown ...................... B3.8-86 8..
B3.9 REFUELING OPERATIONS ................... TS/B3.9-1 B3.9.1 Refueling Equipment Interlocks .TS/B3.9-1 B3.9.2 Refuel Position One-Rod-Out Interlock .......................... 8:
B3.9-5 B3.9.3 Control Rod Position ............. ;. .... B 83.9-9 B3.9.4 Control Rod Position Indication. B3.9-12 B3.9.5 Control Rod OPERABILITY- Refueling.B3.9-16 B3.9.6 Reactor Pressure Vessel (RPV) Water Level .83.9-19 B3.9.7 Residual Heat Removal (RHR) - High Water Level B3.9-22 B3.9.8 Residual Heat Removal (RHR) - Low Water Level .3.9-26 B3.10 SPECIAL OPERATIONS .......................................... TS/13.10-1 B3.10.1 - . Inservice Leak and Hydrostatic Testing Operation .TS/B3.10-1 B3.10.2 Reactor Mode Switch Interlock Testing .3.10 6 B3.10.3 Single Control Rod Withdrawal - Hot Shutdown. B3.10-11 B3.10.4 Single Control Rod Withdrawal - Cold Shutdown .B3.10-16 83.10.5 Single Control Rod Drive (CRD) Removal - Refueling .3.10-21 B3.10.6 - Multiple Control Rod Withdrawal - Refueling. B3.10-26 B3.10.7 Control Rod Testing - Operating .B3.10-29 B3.10.8 SHUTDOWN MARGIN (SDM) Test- Refueling. B3.10-33 ITSB1 Text TOC
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Section Title Revision B 3.6 CONTAINMENT SYSTEMS BASES Page TS / B 3.6-1 2 Page TS / B 3.6-1 a 3 Pages TS / B 3.6-2 through TS / B 3.6-5 -2 PageTS/B3.6-6 3 Pages TS / B 3.6-6a and TS I B 3.6-6b 2 Page TS / B 3.6-6c Pages B 3.6-7 through B 3.6-14 I0 Page TS / B 3.6-15 2 Pages TS / B 3.6-15a and TS B 3.6-15b 0 Page B 3.6-16 0 Page TS / B 3.6-17 I Page TS / B 3.6-17a .0 Pages TS /83.6-18 and TS B 3.6-19 0 Page TS/B3.6-20 Page TS /B3.6-21 -2 Page TS / B 3.6-22 I Page TS / B 3.6-22a Page TS B 3.6-23 0 Pages TS / B 3.6-24 through TS I B 3.6-25 0 Page TS/ B 3.6-26 0 Corrected Page TSiB3.6-27 - 2 Page TS/ B 3.6-28 5 Page TS/ B 3.6-29 Page TS/B 3.6-30 *1~
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B 3.10 SPECIAL OPERATIONS BASES PageTS/B13.10-1 I Pages B 3.10-2 through B 3.10-31 0 Page TS / B 3.10-32 I Pages B 3.10-33 through B 3.10-37 0 PageTS/B3.10-38 I TSBI1text LOES 211105
,_L i., . . I SUSQUEHANNA- UNIT I T / B LOES-6 TS Revision 57 -
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.PPL Rev. 1 Rod Pattern Control B 3.1.6.
B3.1 REACTIVITY CONTROL SYSTEMS B 3.1.6 Rod Pattern Control
- BASES BACKGROU NID Control rod patterns during startup conditions are controlled by the
- . operator and the rod worth minimizer (RWM) (LCO 3.3.2.1, "Control Rod Block Instrumentation"),"so that only specified control rod sequences and relative positions are allowed over the operating range of all control rods inserted to 10% RTP. The sequences limit the potential amount of
-reactivity addition that could occur in the event of a Control Rod Drop Accident (CRDA).
This Specification assures that the control rod patterns are consistent with the assumptions the as . .
of the CRDA analyses of References 1 and 2.
t.i- .
APPLICABLE The analytical methods and assumptions used in evaluating the CRDA SAFETY are summarized in References 1 and 2. CRDA analyses assume that the ANALYSES reactor operator follows prescribed withdrawal sequences. These sequences define the potential initial conditions for the CRDA analysis.
The RWM (LCO 3.3.2.1) provides backup to operator control of the' withdrawal sequences to ensure that the initial conditions of the CRDA analysis are not violated.:
Prevention or mitigation of positive reactivity insertion events is necessary to limit the energy deposition in the fuel, thereby preventing significant fuel damage which could result in the undue release of radioactivity. Since the failure consequences'for UO2 have been shown to be insignificant below fuel energy depositions of 300 cal/gm (Ref. 3), the fuel damage limit of 280 cal/gm provides a margin of safety from significant core damage which would result in release of radioactivity (Refs. 4 and 5). Generic evaluations (Ref. 1 & 6) of a design basis CRDA have shown that the maximum reactor pressure will be less than the required ASME Code' limits (Ref.7). The offsite doses are calculated each cycle using the methodology in reference I to demonstrate that the calculated offsite doses will be well within the required limits (Ref. 5). Control rod patterns.
analyzed in Reference I follow the banked position withdrawal sequence (BPWS). The BPWS is applicable from the condition of all control rods fully inserted to 10% RTP (Ref. 2). For the BPWS, the control rods are required to be moved in'groups, with all control rods assigned to a specific group required to be within specified banked positions (continued)
SUSQUEHANNA - UNIT 1 TS B 3.1-34. Revision I
PPL Rev. 1
- Rod Pattern Control
-B 3.1.6
- 1t 1 BASES APPLICAE ILE (e.g., between notches 08 and 12). The banked positions are established SAFETY to minimize the maximum incremental control rod worth without being ANALYSE S overly restrictive during normal plant operation. For each reload cycle the (continue d) CRDA is analyzed to demonstrate that the 280 cal/gm fuel damage limit will not be violated during a CRDA while following the BPWS mode of operation for control rod patterns. These analyses consider the effects of fully inserted inoperable and OPERABLE control rods not withdrawn in the normal sequence of BPWS, but are still in compliance with the BPWS requirements regarding out of sequence control rods. These requirements allow a limited number (i.e., eight) and distribution of fully inserted inoperable control rods.
When performing a shutdown of the plant, an optional BPWS control rod sequence (Ref. 9) may be used provided that all withdrawn control rods have been confirmed to be coupled prior to reaching THERMAL POWER of <10% RTP. The rods may be inserted without the need to stop at intermediate positions since the possibility of a CRDA is eliminated by the confirmation that withdrawn control rods are coupled. When using the Reference 9 control rod sequence for shutdown, the RWM may be reprogrammed to enforce the requirements of the improved BPWS control rod insertion, or may be bypassed and the improved BPWS shutdown sequence implemented under LCO 3.3.2.1, Condition D controls.
In order to use the Reference 9 BPWS shutdown process, an extra check is 'required in order to consider a control rod to be uconfirmed" to be coupled. This extra check ensures that-no Single Operator Error can result in an incorrect coupling check. For purposes of this shutdown process, the method for confirming that control rods are coupled varies ..I depending on the position of the control rod in the core. Details on this coupling confirmation requirement are provided in Reference 9, which requires that any partially inserted control rods, which have not been confirmed to be coupled since their last withdrawal, be fully inserted prior to reaching THERMAL POWER of <10% RTP. If a control rod has been . I checked for coupling at notch 48 and the rod has since only been moved inward, this rod is in contact with it's drive and is not required to be fully inserted prior to reaching THERMAL POWER of <10% RTP. However, if it cannot be confirmed that the control rod has been moved inward, then that rod shall be fully inserted prior to reaching the THERMAL POWER of
<10% RTP. This extra check may be performed as an administrative
-check, by examining logs, previous (continued)
SUSQUEHANNA - UNIT 1 ' 'TS / B '3.1-35 . I .Revision 1 '
PPL Ftev. 1 Rod Pattern C :ontrol B 3.1.6 i
. 4 K2 BASES ..
APPLICABLE surveillance's or other information. If the requirements for use of the SAFETY BPWS control rod insertion process contained in Reference 9 are ANALYSES followed, the plant is considered to be in compliance with the BPWS (continued) requirements, as required by LOC 3.1.6.
' Rod pattern control satisfies Criterion 3 of the NRC Policy Statement (Ref. 8).
LCO Compliance with the prescribed control rod sequences minimizes the potential consequences of a CRDA by limiting the initial conditions to those consistent with the BPWS. This LCO only applies to OPERABLE' control rods. For inoperable control rods required to be inserted, separate requirements are specified in LCO 3.1.3, "Control Rod OPERABILITY,"
consistent with the allowances for inoperable control rods in the BPWS.
APPLICABILITY In MODES 1 and 2, when THERMAL POWER is
- 10% RTi P, the CRDA is a Design Basis Accident and, therefore,' compliance with the assumptions of the safety analysis is required. When THERMAL POWER is
> 10% RTP, there is no credible control rod configuration that results in a control rod worth that could exceed the 280 cal/gm fuel damage limit during a CRDA (Ref. 2). In MODES 3, 4, and 5, since the reactor is shut down and only a single control rod can be withdrawn from a core cell containing fuel assemblies, adequate SDM ensures that the consequences of a CRDA are acceptable, since the reactor will remain subcritical with a single control rod withdrawn.
ACTIONS A.1 and A.2 With one or more OPERABLE control rods not in compliance with the prescribed control rod sequence, actions may be taken to either correct the control rod pattern or declare the associated control rods inoperable within 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br />. Noncompliance with the prescribed sequence may be the result of "double notching," drifting from a control rod drive cooling water transient, leaking scram valves, or a power reduction to < 10% RTP before establishing the correct control rod pattern. The number of OPERABLE control rods not in compliance with the prescribed sequence is limited to eight, to prevent the operator from attempting to correct a control rod pattern that significantly deviates from the prescribed sequence. When the control (continued)
SUSQUEHANNA - UNIT-1 TS / B 3.1-36 Revision 1.
PPL Rev. I Rod Pattern Control B 3.1.6 BASES ACTIONS A.1 and A.2 (continued) rod pattern is not in compliance with the prescribed sequence, all control rod movement should be stopped except for moves needed to correct the rod pattern, or scram if warranted.
Required Action A.1 is modified by a Note which allows the RWM to be, bypassed to allow the affected control rods to be'returned to their correct position. LCO 3.3.2.1 requires verification of control rod movement by a qualified member of the technical staff. This ensures that the control rods will be moved to the correct position. A control rod not in compliance with the prescribed sequence is not considered inoperable except as required by Required Action A.2. -OPERABILITY of control rods is determined by compliance with LCO 3.1.3, "Control Rod OPERABILITY," LCO 3.1.4, "Control Rod Scram Times," and LCO 3.1.5, "Control Rod Scram Accumulators." The allowed Completion Time of 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> is reasonable, considering the restrictions on the number of allowed out of sequence control rods and the low probability of a CRDA occurring during the time the control rods are out of sequence.
K1- B.1 and B.2 If nine or more OPERABLE control rods are out of sequence, the control rod pattern significantly deviates from the prescribed sequence. Control rod withdrawal should be suspended immediately to prevent the potential
- for further deviation from the prescribed sequence. Control rod insertion to correct control rods withdrawn beyond their allowed position is allowed since, in general, insertion of control rods has less impact on control rod worth than withdrawals have. Required Action B.1 is modified by a Note which allows the RWM to be bypassed to allow the affected control rods to be returned to their correct position. LCO 3.3.2.1 requires verification
- of control rod movement by a qualified member of the technical staff.
When nine or more OPERABLE control rods are not in compliance with BPWS, the reactor mode switch must be placed in the shutdown position
-within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />., With the mode switch in shutdown, the reactor is shut down, and as such, does not meet the applicability requirements of this LCO. The allowed Completion Time of 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> is reasonable to allow insertion of control rods to restore compliance, and is appropriate relative to the low probability.
- -:-(continued)
SUSQUEHANNA - UNIT I -TS / B 3:1-37 Revision 2
RP PL Rev.1 ' ' -1 Rod Pattei m Control B 3.1.6 BASES I - . i ACTIONS B.1 and B.2 (continued) of a CRDA occurring with the control rods out of sequence.
SURVEILLANCE SR 3.1.6.1 REQUIREMENTS The control rod pattern is verified to be in compliance with the BPWS at a 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> Frequency to ensure the assumptions of the CRDA analyses are met. The 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> Frequency was developed considering that the primary check on compliance with the BPWS is performed by the RWM 1
(LCO 3.3.2.1), which provides control rod blocks to enforce the required
. I sequence and is required to be OPERABLE when operating at II
<10% RTP. i
.r
. . I REFERENCES 1. 'PL-NF-90-001-A, uApplication of Reactor Analysis Methods for BWR Design and Analysis," Section 2.8, July 1992, Supplement 1-A,' . - . i August 1995, Supplement 2-A, July 1996, and Supplement 3-A, I March 2001.
2.' 3 Modifications to the Requirements for Control Rod Drop Accident Mitigating System," BWR Owners Group, July 1986.
I . i
- 3. NUREG-0979, Section 4.2.1.3.2, April 1983.
- 4. NUREG-0800, Section 15.4.9, Revision 2, July 1981.
- 5. 10 CFR 100.11.'
- 6. NEDO-21778-A, "Transient Pressure Rises Affected Fracture Toughness Requirements for Boiling Water Reactors,"
December 1978.-
- 7. ASME, Boiler and Pressure Vessel Code.
8.; Final Policy Statement on Technical Specifications Improvements,
- .July 22,1993 (58 FR 39132).
- 9. NEDO 33091-A, Revision 2, "Improved BPWS Control Rod Insertion I.
Process," April 2003.
SUSQUEHANNA - UNIT 1 .. TS / B 3.1-38 -Revision 1 A, _ _ A, . . _ _ . . .
PPL Rev. 1 Control Rod Block Instrumentation B 3.3.2.1 B'3.3 INSTRUMENTATION .
B 3.3.2.1 Control Rod Block Instrumentation BASES BACKGROUND 'Control rods provide the primary means for control of reactivity changes.
Control rod block instrumentation includes channel sensors, logic circuitry, switches, and relays that are designed to ensure that specified fuel design limits are not exceeded for postulated transients and accidents. During high power operation, the rod block monitor (RBM) provides protection for control rod withdrawal error events. During low power operations, control rod blocks from the rod worth minimizer (RWM) enforce specific control rod sequences designed to mitigate the consequences of the control rod drop -
- accident (CRDA). During shutdown conditions, control rod blocks from the Reactor Mode Switch-Shutdown Position Function ensure that all control rods remain inserted to prevent inadvertent criticalities.
The purpose of the RBM is to limit control rod withdrawal if localized neutron
-flux exceeds a predetermined setpoint during control rod manipulations.
The RBM supplies a trip signal to the Reactor Manual Control System (RMCS) to'appropriately inhibit control rod withdrawal during power operation above the low power range setpoint. The RBM has two channels,
' either of which can initiate a control rod block when the channel output exceeds the control rod block setpoint. One RBM channel inputs into one RMCS rod block circuit and the other RBM channel inputs into the second RMCS rod block circuit. The RBM channel signal is generated by averaging a set of local power range monitor (LPRM) signals at various core heights surrounding the control rod being withdrawn. A signal from one average power range monitor (APRM) channel assigned to each Reactor Protection System (RPS) trip system supplies a reference signal for the RBM channel in the same trip system. This reference signal is used to enable the RBM. If.
the APRM is indicating less than the low power range setpoint, the RBM is automatically bypassed. The RBM is also automatically bypassed if a
- peripheral control rod is selected (Ref. 2).
The purpose of the RWM is to control rod patterns during startup, such that only specified control rod sequences and relative positions are allowed over the operating range from all control rods inserted to 10% RTP. The sequences effectively limit the potential amount and rate of reactivity increase during a CRDA. Prescribed control rod sequences are stored in the RWM, which will initiate control rod withdrawal and insert blocks when the actual sequence deviates beyond allowances
- from the stored sequence. The RWM determines the actual sequence (continued)
SUSQUEHANNA - UNIT 1 * - TS / B 3.3-44 ' ' Revision 2
PPL Rev. 1 Control Rod Block Instrumentation B 3.3.2.1 I ; -: ... , . .- I . . .
. I ! I : . - . I
.'BASES BACKGRO UND based position indication for each control rod. The RWM also uses steam (continuecd) flow signals to determine when the reactor power is above the preset power level at which the RWM is automatically bypassed (Ref. 1). The RWM is a single channel system that provides input into RMCS rod block channel 2.
The function of the individual rod sequence steps (banking steps) is to minimize the potential reactivity increase from postulated CRDA at low power levels. However, if the possibility for a control rod to drop can be eliminated, th6n banking steps at low power levels are not needed to ensure the applicable event limits; can not be exceeded. The rods may be inserted without the need to stop at intermediate positions since the possibility of a CRDA is eliminated by the confirmation that withdrawn control rods are coupled.
To eliminate the possibility of a CRDA, administrative controls require that any partially inserted control rods, which have not been confirmed to be coupled since their last withdrawal, be fully inserted prior to reaching the THERMAL POWER of <10% RTP. If a control rod has been checked for coupling at notch 48 and the rod has not been moved inward, this rod is in contact with it's drive and is not required to be fully inserted prior to reaching the THERMAL POWER of <10% RTP. However, if it cannot be confirmed that the control rod has been moved inward, then that rod shall be fully inserted prior to reaching the THERMAL POWER of <10% RTP.
The remaining control rods may then be inserted without the need to stop at intermediate positions since the possibility of a CRDA'has been eliminated..
With the reactor mode switch in the shutdown position, a control rod withdrawal block is applied to all control rods to ensure that the shutdown condition is maintained. This Function prevents inadvertent criticality as the result of a control rod withdrawal during MODE 3 or 4, or during MODE 5 when the reactor mode switch is required to be in the shutdown position. The reactor mode switch has two channels, each inputting into a separate RMCS rod block circuit. A rod block in either RMCS circuit will provide a control rod block to all control rods.
APPLICABLE 1.' Rod Block Monitor SAFETn ANALY' 3ES, The RBM is designed to limit control rod withdrawal if localized neutron flux LCO, anid exceeds a predetermined setpoint. The RBM was originally designed to APPLIC,ABILITY (continued)
S.U SSQUEHANNA - UNIT 1 TS / B 3.3-45 . 0 Revision 2 .
PPL Rev. 1 Control Rod Block Instrumentation B 3.3.2.1 0.p: BASES-APPLICABLE prevent fuel damage during a Rod Withdrawal Error (RWE) event while SAFETY operating in the'power range in a normal mode of operation. FSAR 15.4.2 ANALYSES, (Ref. 10) (Rod Withdrawal Error- At Power) originally took credit for the LCO, and - RBM automatically actuating to stop control rod motion and preventing fuel APPLICABILITY . damage during an RWE event at power. However, current reload analyses (continued) do not take credit for the RBM system. The Allowable Values are chosen as a function of power level to not exceed the APRM scram setpoints.
The RBM function satisfies Criterion 4 of the NRC Policy Statement (Ref. 7).
Two channels of the RBM are required to be OPERABLE, with their setpoints within the appropriate Allowable Value for the associated power range, to ensure that no single instrument failure can preclude a rod block for this Function. The actual setpoints are calibrated consistent with applicable setpoint methodology.
Nominal trip setpoints are specified in the setpoint calculations. The nominal setpoints are selected to ensure that the setpoints do not exceed the Allowable Values between successive CHANNEL CALIBRATIONS.
Operation with a trip setpoint less conservative than the nominal trip
- )u setpoint, but within its Allowable Value, is acceptable. Trip setpoints are those predetermined values of output at which an action should take place.
The setpoints are compared to the actual process parameter (e.g., reactor-
-power), and when the measured output value of the process parameter exceeds the setpoint, the associated device (e.g., trip unit) changes state.
The analytic limits are derived from the limiting values of the process parameters. The Allowable Values are derived from the analytic limits, corrected for calibration, process, and some of the instrument errors. The trip setpoints are then determined accounting for the remaining instrument errors (e.g.,"drift). -The trip setpoints derived in this manner provide' adequate protection because instrumentation uncertainties, process
- -effects, calibration tolerances, instrument drift, and severe environment errors (for channels that must function in harsh environments as defined by 10 CFR 50.49) are accounted for.
The RBM will function when operating greater than 30% RTP. Below this power level, the RBM is not required to be OPERABLE.
- 2. Rod Worth Minimizer The RWM enforces the banked position withdrawal sequence (BPWS) to ensure that the initial conditions of the CRDA analysis are not violated.
(continued)
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'I, BASES APPLICABLE -The analytical methods and assumptions used in evaluating the CRDA SAFETY are summarized in References 2, 3, 4, and 5. -The BPWS requires that ANALYSES, control rods be moved in groups, with all control rods assigned to a LCO, and specific group required to be within specified banked positions.
APPLICABILITY Requirements that the control rod sequence is in compliance with the (continued) - BPWS are specified in LCO 3.1.6, "Rod Pattem Control."
When performing a shutdown of the plant, an optional BPWS control rod sequence (Ref. 7) ~may be used if the coupling of each withdrawn control rod has been confirmed. The rods may be inserted without the need to stop at intermediate positions. When using the Referehce 11 control rod insertion sequence for shutdown, the rod worth minimizer may be reprogrammed to enforce the requirements of the improved BPWS control rod insertion, or may be bypassed and the improved BPWS shutdown sequence implemented under the controls in Condition D.
The RWNM Function satisfies Criterion 3 of the NRC Policy Statement.
(Ref. 7)
Since the RWM is designed to act as a backup to operator control of the rod sequences, only one channel of the RWM is available and required to be OPERABLE (Ref. 6). Special circumstances provided for in the
- ) - Required Action of LCO 3.1.3, "Control Rod OPERABILITY," and LCO 3.1.6 may necessitate bypassing the RWM to allow continued
- operation with inoperable control rods, or to allow correction of a control rod pattern not in compliance with the BPWS. The RWM may be bypassed as required by these conditions, but then it must be considered
- inoperable and the Required Actions of this LCO followed.
Compliance with the BPWS, and therefore OPERABILITY of the RWM, is required in MODES 1 and 2 when THERMAL POWER is < 10% RTP.
When THERMAL POWER is > 10% RTP, there is no possible control rod configuration that results in a control rod worth that could exceed the 280 cal/gm fuel damage limit during a CRDA (Refs. 4 and 6). In
- -MODES 3 and 4, all control rods are required to be inserted into the core (except as provided in 3.10 "Special Operations'); therefore, a CRDA cannot occur. In MODE 5, since only a single control rod can be withdrawn from a core cell containing fuel assemblies, adequate SDM ensures that the consequences of a CRDA are acceptable, since the reactor will be subcritical.
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APPLICABLE 3. Reactor Mode Switch-Shutdown Position SAFETY ANALYSES During MODES 3 and 4, and during MODE 5 when the reactor mode LCO, and switch is required to be in the shutdown position, the core is assumed to APPLICABILITY be subcritical; therefore, no positive reactivity insertion events are (continued) analyzed. The Reactor Mode Switch-Shutdown Position control rod withdrawal block ensures that the reactor remains subcritical by blocking control rod withdrawal, thereby preserving the assumptions of the safety analysis.
The Reactor Mode'Switch-Shutdown Position Function satisfies Criterion 3 of the NRC Policy Statement. (Ref. 7)
Two channels are required to be OPERABLE to ensure that no single channel failure, will preclude a rod block when required. There is no Allowable Value for this Function since the channels are mechanically actuated based solely on reactor mode switch position.
During shutdown conditions (MODE 3, 4, or 5), no positive reactivity insertion events are analyzed because assumptions are that control rod withdrawal blocks are'provided to prevent criticality. Therefore, when the reactor mode switch is in the shutdown position, the control rod withdrawal block is required to be OPERABLE. During MODE 5 with the reactor mode switch in the refueling position, the refuel position one-rod-out interlock (LCO 3.9.2) provides the required control rod withdrawal blocks.
'ACTIONS A.1 .. . .
With one RBM channel inoperable, the remaining OPERABLE channel is adequate to perform the control rod block function; however, overall reliability is reduced because a single failure in the remaining OPERABLE channel can result in no control rod block capability for the RBM. For this reason, Required Action A.1 requires restoration of the inoperable channel to OPERABLE status. The Completion Time of 5 days is based on the low probability of an event occurring coincident with a failure in the remaining OPERABLE channel.
(continued)
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'- PPL Rev. 1 Control Rod Block Instrumentation I- B 3.3.2.1 BASES ACTIONS B.1 (continued)
If Required Action A.1 is not met and the associated Completion Time has expired, the inoperable channel must be placed in trip within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. If both RBM'channels are inoperable, the RBM is not capable of performing its intended function; thus, one channel must also be placed
'in trip. This initiates a control rod withdrawal block, thereby ensuring that the RBM function is'met.
The 48 hour5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> Completion Time is intended to allow the operator time to evaluate and repair any discovered inoperabilities and is acceptable because it minimizes risk while allowing time for restoration or tripping of inoperable channels.
C.1. C.2.1.1. C.2.1.2. and C.2.2 With the RWM inoperable during a reactor startup, the operator is still capable of enforcing the prescribed control rod sequence. However, the overall reliability is reduced because a single operator error can result in violating the control rod sequence. Therefore, control rod movement must be immediately suspended except by scram. Alternatively, startup may continue'if at least 12 control rods have already been withdrawn, or a'reactor startup with an inoperable RWM was not performed in the last calendar year, i.e., the last 12 months. Required Actions C.2.1.1 and C.2.1.2 require verification of these conditions by review of plaint logs' and control room indications. A reactor startup with an inoperable RWM is defined as rod withdrawal'during startup when the RWM is required to be OPERABLE. Once Required Action C.2.1.1 or C.2.1.2 is satisfactorily completed, control rod withdrawal may proceed in accordance with the restrictions imposed by Required Action C.2.2. Required Action C.2.2 allows for the RWM Function to be performed manually and requires a double check of compliance with the prescribed rod sequence by a second licensed operator (Reactor Operator or Senior Reactor Operator) or other qualified member of the technical staff. The RWM may be bypassed under these conditions to allow continued operations. In addition, Required Actions of LCO 3.1.3 and LCO 3.1.6 may require bypassing the RWM, during which time the RWM must be considered inoperable with Condition C entered and its Required Actions taken.
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With the RWM inoperable during a reactor shutdown, the operator is still capable of enforcing the prescribed control rod sequence. Required Action D.1 allows for the RWM Function to be performed manually and requires a double check of compliance with the prescribed rod sequence by a second licensed operator (Reactor Operator or Senior Reactor Operator) or other qualified member of the technical staff. The RWM may be bypassed under.
these conditions to allow the reactor shutdown to continue.
E.1 and E.2 With one Reactor Mode Switch-Shutdown Position control rod withdrawal .I i
block channel inoperable, the remaining OPERABLE channel is adequate to'perform the control rod withdrawal block function. However, since the Required Actions are consistent with the normal action of an OPERABLE Reactor Mode Switch-Shutdown Position Function (i.e., maintaining all control rods inserted), there is no distinction between having one or two channels inoperable.
In both cases (one or both channels inoperable), suspending all control rod withdrawal and initiating action to fully insert all insertable'control rods in core cells containing one or more fuel assemblies will ensure that the core is subcritical with adequate SDM ensured by LCO 3.1.1. Control rods in' core cells containing no fuel assemblies do not affect the reactivity of the core and'are therefore not required to be inserted. Action must continue until all insertable control rods in core cells containing one or more fuel assemblies are fully inserted.
SURVEILLANCE As noted at the beginning of the'SRs, the SRs for each Control Rod Block REQUIREMENTS instrumentation Function are found in the SRs column of Table 3.3.2.1-1.
The Surveillances are modified by a Note to indicate that when an RBM channel is placed in an inoperable status solely for performance of required Surveillances, entry into associated Conditions and Required Actions may be delayed for up to 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> provided the associated Function maintains control rod block capability. Upon completion of the Surveillance, or expiration of the 6 hour6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> allowance, the channel must be returned to OPERABLE status or the applicable Condition entered and Required Actions taken. This Note is based on the reliability analysis (Ref. 9)
(continued) ; '
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PPL Rev. 1 Control Rod Block Instrumentation B 3.3.2.1 BASES SURVEILLANCE assumption of the average time required to perform channel Surveillance.
REQUIREMENTS That analysis demonstrated that the 6 hour6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> testing allowance does not (continued) significantly reduce the probability that a control rod block will be initiated when necessary.
SR 3.3.2.1.1 A CHANNEL FUNCTIONAL TEST is performed for each RBM channel to ensure that the entire channel will perform the intended function. It includes the Reactor Manual Control Multiplexing System input. The Frequency of 92 days is based on reliability analyses (Ref. 8).
SR 3.3.2.1.2 and SR 3.3.2.1.3 A CHANNEL FUNCTIONAL TEST is performed for the RWM to ensure that the entire system will perform the intended function. The CHANNEL FUNCTIONAL TEST for the RWM is performed by attempting to withdraw a control rod not in compliance with the prescribed sequence and verifying a control rod block occurs and by verifying proper indication of the selection error of at least one out-of-sequence control rod. As noted inthe SRs, SR 3.3.2.1.2 is not required to be performed until 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> after any control rod is withdrawn in MODE 2. As noted, SR 3.3.2.1.3 is not required to be performed until 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> after THERMAL POWER is
< 10% RTP in MODE 1. This allows entry into MODE 2 for SR 3.3.2.1.2, and entry into MODE 1 when THERMAL POWER is < 10% RTP for SR 3.3.2.1.3, to perform the required Surveillance if the 92 day Frequency is not met per SR 3.0.2. The 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> allowance is based on operating experience and in consideration of providing a reasonable time in which to complete the SRs. The Frequencies are based on reliability analysis (Ref. 8).
SR 3.3.2.1.4 The RBM trips are automatically bypassed when power is below a specified value and a peripheral control rod is not selected.' The power Allowable Value must be verified periodically to not be bypassed when2->
30% RTP. This is performed by a Functional check. If any RBM bypass setpoint is non-conservative, then the affected RBM channel is (continued)
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PPL Rev. I Control Rod Block Instrumentation B 3.3.2.1 BASES SURVEILLANCE SR 3.3.2.1.4 (continued)'
Msnf lID MFAtKlT.r rum JIIUCIVICI'4 I %s considered inoperable. Alternatively, the RBM channel can be placed in
-the conservative condition (i.e., enabling the RBM trip).. Ifplaced in this condition, the SR is met and the RBM channel is not considered inoperable. As noted neutron detectors are excluded from the Surveillance because they are passive devices, with minimal drift, and because of the difficulty of simulating a meaningful signal.
Neutron detectors are adequately tested in SR 3.3.1.1.2 and SR 3.3.1.1.8. The 24 month Frequency is based on the need to perform the surveillance during a plant start-up.
SR 3.3.2.1.5 The RWM is automatically bypassed when power is above a specified value. The power level is deAermined from steam flow signals. The automatic bypass setpoint must be verified periodically to be not bypassed < 10% RTP. This is performed by a Functional check. If the RWM low power setpoint is nonconservative, then the RWM is considered inoperable. Alternately, the low power setpoint channel can be placed in the conservative condition (nonbypass). If placed in the nonbypassed condition, the SR is met and the RWM is not considered inoperable. The Frequency is based on the need to perform the Surveillance during a plant start-up.
SR 3.3.2.1.6 A CHANNEL FUNCTIONAL TEST is performed for the Reactor Mode
- Switch-Shutdown Position Function to ensure that the entire channel will perform the intended function. The CHANNEL FUNCTIONAL TEST for the'Reactor Mode Switch-Shutdown Position Function is performed by attempting to withdraw any control rod with the reactor mode switch in the' shutdown position and verifying a control rod block occurs.
As noted in the SR, the Surveillance is not required to be performed until.
1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> after the reactor mode switch is in the shutdown position, since testing of this interlock with the reactor mode switch in any other position cannot be performed without using jumpers, lifted leads, or movable (continued) 0 SUSQUEHANNA - UNIT I . " TS / B 3.3-52 Revision 1 t:
PPL Rev. 1 Control Rod Block Instrumentation B 3.3.2.1 X3 BASES SURVEILLANCE SR 3.3.2.1.6 (continued)
REQUIREMENTS links. This allows entry into MODES 3 and 4 if the 24 month Frequency is not met per SR 3.0.2. 'The 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> allowance is based on operating experience and in consideration of providing a reasonable time in which to complete the.SRs.-
The 24 month Frequency is based on the need to perform portions of this Surveillance under.the conditions that apply during a plant outage and the potential for an unplanned transient if the Surveillance were performed with the reactor at power. Operating experience has shown these components usually pass the Surveillance when performed at the 24 month Frequency.--,
CHANNEL CALIBRATION is a test that verifies the channel responds to the measured parameter with the necessary range and accuracy.
CHANNEL CALIBRATION leaves the channel adjusted to account for instrument drifts between'successive calibration consistent with the plant specific setpoint methodology.
As noted, neutron detectors are excluded from the CHANNEL CALIBRATION because they are passive devices, with minimal drift, and because of the difficulty of simulating a meaningful signal. Neutron detectors are adequately tested in SR ,3.3.1.1.2 and SR 3.3.1.1.8.
The Frequency is based upon the assumption of a 24 month calibration interval in the determination of the magnitude of equipment drift in the setpoint analysis. -
The RWM will only enforce the proper control rod sequence if the rod sequence is properly input into the RWM computer. This SR ensures that the proper sequence is'loaded into the RWM so that it can perform its intended function. 'The Surveillance is performed once prior to declaring RWM OPERABLE following loading of sequence into RWM, since this is when rod sequence input errors are possible.
- )
(continued)
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REFERENCES 1. FSAR, Section 7.7.1.2.8.
- 2 FSAR, Section 7.6.1.a.5.7
- 3. NEDE-2401 1-P-A-9-US, "General Electrical Standard Application for Reload Fuel," Supplement for United States, Section S 2.2.3.1, September 1988.
- 4. "Modifications to the Requirements for Control Rod Drop Accident Mitigating Systems," BWR Owners' Group, July 1986.
- 5. NEDO-21231, "Banked Position Withdrawal Sequence,"
January 1977.
- 6. NRC SER, "Acceptance of Referencing of Licensing Topical Report NEDE-24011-P-A," "General Electric Standard Application for Reactor Fuel, Revision 8, Amendment 17," December 27, 1987.
- 7. Final Policy Statement on Technical Specifications Improvements, July 22,1993 (58 FR 32193)
- 8. NEDC-30851 -P-A, "Technical Specification Improvement Analysis for BWR Control Rod Block Instrumentation," October 1988.
- 9. GENE-770-06-1, "Addendum to Bases for changes to Surveillance Test Intervals and Allowed Out-of-Service Times for Selected Instrumentation, Technical Specifications," February 1991.
- 10. FSAR, Section 15.4.2.
- 11. NEDO 33091-A, Revision 2, "Improved BPWS Control Rod Insertion Process,* April 2003.
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