{{#Wiki_filter:Tennessee Valley Authority, Post Office Box 2000 Spring City, Tennessee 37381 November 2, 2017 10 cFR 50 4 10 CFR 50.71(e)U. S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, D.C. 20555-0001

Watts Bar Nuclear Plant, Units 1 and 2 Facility Operating License Nos. NPF-90 and NpF-96 NRC Docket Nos. 50-390 and 50-391 watts Bar Nuclear Plant Units 1 and 2 - Periodic submission for Changes Made to the WBN Technical Specification Bases and Technical Requirements Manual References'.

1 .TVA letter to NRC, "Watts Bar Nuclear Plant (WBN) Unit 1 Periodic Submission for Changes Made to the WBN Technical Specification Bases and Technical Requirements Manual," dated April 22, 201 6 (M1161 134077)NRC letter to TVA, "lssuance of Facility Operating License No.NPF-96, Watts Bar Nuclear Plant Unit 2," dated October 22, ZO1S (ML 1s251As87)

The purpose of this letter is to provide the Nuclear Regulatory Commission (NRC) with copies of changes to the Watts Bar Nuclear Plant (WBN) Units 1 and 2 Technical Specification (TS) Bases and to provide copies of changes to the Unit 1 and 2 Technical Requirements Manual (TRM). Copies of the TS Bases, through Revision 13T for Unit 1 and Revision 11 for Unit 2, are provided in accordance with WBN Units 1 and 2 TS Section 5.6, "Technical Specifications (TS) Bases Control Program." ln addition, copies of changes to the wBN Units 1 and 2 TRM, through Revision 64 for Unit 1 and Revision 7 for Unit 2, ate provided in accordance with WBN TRM Section 5.1, "Technical Requirements (TR) Control Program." These changes have been implemented at WBN during the period since WBN Unit 1's last update (Reference  

: 1) and since the issuance of the operating license for WBN Unit 2 (Reference 2). These changes meet the criteria described within the above control programs for which prior NRC approval is not required.

Both control programs require such changes to be provided to the NRC on a frequency consistent with Title 10 of the Code of Federal Regulations (10 CFR) 50.71(e).The WBN TS Bases and TRM updates for the table of contents and change pages are provided in the enclosures.

U.S. Nuclear Regulatory Commission Page 2 November 2,2017 Enclosures 1 and 2 to this submittal provide the WBN Unit 1 TS changes. Enclosures 3 and 4 to this submittal provide the WBN Unit 1 TRM changes. Enclosures 5 and 6 to this submittal provide the WBN Unit 2 TS changes. Enclosures 7 and 8 to this submittal provide the WBN Unit 2 TRM changes.There are no new regulatory commitments in this letter. Should you have questions regarding this submittal, please contact Kim Hulvey, Manager of Watts Bar Site Licensing, at (423) 365-77 20.Respectfully, Paul Simmons Site Vice President Watts Bar Nuclear Plant  

1 - WBN Unit 1 Technical Specification Bases - Table of Contents 2 - WBN Unit 1 Technical Specifications Bases - Changed pages 3 - WBN Unit 1 Technical Requirements Manual - Table of Contents 4 - WBN Unit 1 Technical Requirements Manual - Changed pages 5 - WBN Unit 2 Technical Specification Bases - Table of Contents 6 - WBN Unit 2 Technical Specifications Bases - Changed pages 7 - WBN Unit 2 Technical Requirements Manual - Table of Contents 8 - WBN Unit 2 Technical Requirements Manual - Changed pages cc (Enclosures):

NRC RegionalAdministrator - Region ll NRC Senior Resident lnspector - Watts Bar Nuclear plant NRR Project Manager - Watts Bar Nuclear Plant ENCLOSURE 1 WBN UNIT 1 TECHNICAL SPEGIFICATION BASES TABLE OF CONTENTS E-1 TABLE OF CONTENTS LIST OF FIGURES LtsT oF ACRONYMS ........................

vi LIST OF EFFECTIVE PAGES ........,.,..

Viii B 2.0 SAFEW LIMITS (SLs)............  

...8 2.0-1 B 2.1.1 Reactor Core SLs ...... B 2.0-1 B 2.1.2 Reactor Coolant System (RCS) Pressure SL ... B 2.0-8 B30 B 3.0 B 3.1 B 3.1 .1 B 3.1 .2 B 3.1 .3 B 3.1 .4 B 3.1 .5 B 3.1 .6 B 3.1 .7 B 3.1 .8 B 31.9 B 3 1 10 B 3.2 B 3.2.1 B 3.2.2 B 3.2.3 B 3.2.4 B 3.3 B 3.3.1 B 3.3.2 B 3.3.3 B334 B 3.3.5 B 3.3.6 B 3.3.7 B338 LrMrrNG CONDTTON FOR OPEMTTON (LCO)APPlrCABrlrrY............................B 3.0-1 SURVElLLANCE REQUIREMENT (SR)APPLrCABlLlry..........  

............8 3.0-10 REACTIVITY CONTROL SYSTEMS .....8 3.1-1 SHUTDO\A/I{

MARGTN (SDM) T"w > 200"F ......8 3.1-1 SHUTDO\ N MARGIN (SDM) T"w < 200'F ......83.1-7 Core Reactivity.................  

..............8 3.1-12 ModeratorTemperature Coefficient (MTC)..........  

..................8 3.1-18 Rod Group Alignment Limits...........  

B 3.1-24 Shutdown Bank lnsertion Limits........  

.................8 3.1-35 ControlBank lnsertion Limits ........8 3.140 Rod Position lndication.....

B 3.148 PHYSICS TESTS Exceptions MODE 1 ...................  

...............8 3.1-55 PHYSlCSTESTSExceptionsMODE2..................  

...............B3.1$2 PO\A/ER DISTRIBUTION LIMITS ..........83.2-1 Heat Flux Hot Channel Factor (FO(Z)) .. .. . .......83.2-1 Nuclear Enthalpy Rise Hot Channel Factor (F"aH).........  

..................8 3.2-12 AxtAt FLUXDTFFERENCE (AFD).. . . . ..........8 3.2-19 QUADRANTPO\  

..B 3.3.1 Reactor Trip System (RTS) 1nstrumentation................................................

B 3.3-1 Eng ineered Safety Feature Actuation System (ESFAS) lnstrumentation................  

....................B 3.3-O4 Post Accident Monitoring (PAM) lnstrumentation................  

...8 3.3-121 Remote Shutdown System ............B 3.3-141 Loss of Power (LOP) Diesel Generator (DG)Start lnstrumentation  

..............B 3.3-147 Containment Vent lsolation lnstrumentation............

B 3.3-154 Control Room Emergency Ventilation System (CREVS) Actuation lnstrumentation................  

B 3.3-163 Auxiliary Building Gas Treatment System (ABGTS)Actuation lnstrumentation................  

.............8 3.3-171 (continued)

Revision 90 Watts Bar-Unit 1 TABLE OF CONTENTS (continued)

B 3.4 B 3.4.1 B 3.4.2 B 3.4.3 B 3.4.4 B 3.4.5 B 3.4.6 B 3.4.7 B3.48 B 3.4.9 B 3.4.10 B 3.4.11 B 3.4.12 B 3.4.1 3 B 3.4.14 B 3.4.15 B 3.4.16 B 3.4.17 B 3.5 B 3.5.1 B 3.5.2 B 3.5.3 B 3.5.4 B35s B 3.6 B 3.6.1 B 3.6.2 B36.3 B 3.6.4 B36.s B36.6 B 3.6.7 B36.8 B 3.6.9 B 3.6.10 B 3 6.11 B 3.6.12 B 3.6.1 3 B 3.6.14 B 3.6.15 REACTOR COOLANT SYSTEM (RCS)..........  

..........8 3.4-1 RCS Pressure, Temperature, and Flow Departure from Nucleate Boiling (DNB) Limits B 3.4-1 RCS Minimum Temperature for Criticahty . ........ ... .............

.............B 3.4-9 RCS Loops-MODES 1 and 2.........  

................8 3.4-17 RCS Loops-MODE 3...................  

....................B 3.4-27 RCS Loops-MODE 5, Loops Fi11ed............  

.....8 3.4-33 RCS Loops-MODE 5, Loops Not Filled.....  

.....B 3.4-38 Pressurizer..  

...............8 3.44'l PressurizerSafetyValves

.............B 3.446 Pressurizer Power Operated Relief Valves (PORVS)......  

................8 3.4-5'l Cold Overpressure Mitigation System (COMS) B 3.4-58 RCS Operational 1EAKAGE..................  

...........B 3.4-74 RCS Pressure lsolation Valve (PlV) Leakage.......  

..................8 3.4-81 RCS Leakage Detection lnstrumentation................  

................8 3.4-87 RCS Specific Activity B 3.4-93 Steam Generator (SG) Tube lntegrity  

...............8 3.4-99 EMERGENCY CORE COOLTNG SYSTEMS (ECCS) ....................B 3.5-1 Accumulators

...........B 3.5-1 ECCS-Operating..........  

..............8 3.5-10 ECCS-Shutdown..........  

.............8 3.5-20 Refueling Water Storage Tank (RWST).......  

............8 3.5-31 CoNTAlNMENT SYSTEMS.................. .B 3.6-1 Containment

...............8 3.6-1 Containment Air Locks ...................8 3.6*Containment lsolation Valves .......8 3.6-14 Containment Pressure......  

.............8 3.6-28 Containment Air Temperature...............  

B 3.6-31 Containment Spray Systems..................  

...........B 3.6-35 Hydrogen Recombiners - Deleted .....................B 3.6-43 Hydrogen Mitigation System (HMS) ..................8 3.6.49 Emergency Gas Treatment System (EGTS) ....B 3.6-55 Air Return System (ARS). .... . .....B 3.660 lce Bed ..8 3.6-65 lce Condenser Doors.......

83.6-74 Divider Barrier lntegrity........  

..........8 3.6-84 Containment Recirculation Drains . B 3.6-90 Shield Building..................  

..............8 3.6-95 (continued)

Revision 82,94 Watts Bar-Unit 1 TABLE OF CONTENTS (conttnued)

B 3.7 B 3.7.1 B 3.7.2 B 3.7.3 B 3.7.4 B37.5 B 3.7.6 B 3.7.7 B37.8 B 3.7.9 B 3.7.10 B 3.7.11 B 3.7.12 B 3.7.1 3 B 3.7.14 B 3.7-1 5 B 3.7-16 B 3.7-17 B 3.8 B 3.8.1 B 3.8.2 B 3.8.3 B 3.8.4 B 3.8.5 B386 B 3.8.7 B 3.8.8 B38.9 B 3.8.10 B 3.9 B 3.9.1 B 3.9.2 B3.93 B 3.9.4 B3.95 B396 B 3.9.7 B39.8 B 3.9.9 B 3 9.10 PLANT SYSTEMS,..  

..........B 3,7.1 Main Steam SafetyValves (MSSVS)......  

...........8 3.7-1 Main Steam lsolation Valves (MSlVs) 83.7-7 Main Feedwater lsolation Valves (MFlVs)and Main Feedwater Regulation Valves (MFRVS)and Associated Bypass Va1ves..........  

........ B 3.7-13 Atmospheric Dump Valves (ADVs)......  

..............8 3.7-20 Auxiliary Feedwater (AFW System.........  

..........8 3.7-24 Condensate Storage Tank (CST) .83.7-U Component Cooling System (CCS)..........  

.......8 3.7-38 Essential Raw Cooling Water (ERCW System........  

.............8 3.743 Ultimate Heat Sink (UHS)...........  

....83.748 Control Room Emergency Ventilation System (CREVS) .......B 3.7-51 Control Room Emergency Air Temperature ControlSystem (CREATCS).

B 3.7-58 Aufliary Building Gas Treatment System (ABGTS)......  

........8 3.7$2 Fuelstorage PoolWater Level............  

...............B 3.768 Secondary Speclfic Activity.................  

...............8 3.7-71 Spent FuelAssembly Storage ......8 3.7-75 Component Cooling System (CCS) - Shutdown....  

................8 3.7-78 Essential Raw Cooling Water (ERCW) System Shutdown....

B 3.7-83 ELECTRICAL POWER SYSTEMS...  

.....8 3.8-1 AC Sources-Operating  

..............B 3.8-1 AC Sources-Shutdown....  

..........B 3.8-37 DieselFuelOil, Lube Oil, and Starting Air................

B 3.843 DC Sources-Operating....  

..........8 3.8-54 DC Sources-Shutdown....  

..........8 3.8-70 Battery CellParameters...............  

............8 3.8-81 lnverters-Shutdorarn  

...................B 3.8-85 Distribution Systems-Operating B 3.8*9 Distribution Systems-Shutdown.......  

..............B 3.8-99 REFUELTNG OPERATlONS..................  

....................B 3.9-1 Boron Concentration.........  

..............8 3.9-1 Unborated Water Source lsolation Valves ........ B 3.9-5 Nuclear lnstrumentation  

B 3.9-8 Deleted B 3.9-12 Residual Heat Removal (RHR) and Coolant Circulation - High Water Level B 3.9-17 Residual Heat Removal (RHR) and Coolant Circulation - Low Water Leve! ...................

B 3.9-21 Refueling Cavity Water Leve1............  

..................8 3.9-25 Deleted . B 3.9-29 Spent FuelPoolBoron Concentration...................  

..................B 3.9-33 Decay Time............  

...B 3.9-35 Watts Bar-Unit 1 Revision 123 LIST OF TABLES Table No. Title Paqe Paqe B 3.8.1-2 TS Action or Surveillance Requirement (SR)Contingency Actions........  

B 3.8-36 B 3.8.9-1 AC and DC ElectricalPower Distribution Systems....... .B 3.8-98 Watts Bar-Unit 1 LIST OF FIGURES Fiqure No. Title Page B 2.1.1-1 Reactor Core Safety Limits vs Boundary of Protection

...................8 2.0:7 B 3.1.7-1 Control Bank lnsertion vs Percent RTP.............  

B 3.147 B 3.2.1-1 K(z) - Normalized Fq(z) as a Function of Core Height ...83.2-11 B 3.2.3-1 AXIAL FLUX DIFFERENCE Acceptable Operation Limits as a Function of RATED THERMAL POWER ..83.2-23 Watts Bar-Unit 1 Acronym ABGTS ACRP ASME AFD AFW ARO ARFS ADV BOC CAOC CCS CFR COLR CREVS CSS CST DNB ECCS EFPD EGTS EOC ERCW ESF ESFAS HEPA HVAC LCO MFIV MFRV MSIV MSSV MTC NMS ODCM PCP PDMS PIV PORV PTLR QPTR RAOC RCCA RCP RCS RHR RTP LIST OF ACRONYMS (Page 1 ot 2)Title Auxiliary Building Gas Treatment System Auxiliary Control Room Panel American Society of Mechanical Engineers Axial Flux Difference Auxiliary Feedwater System All Rods Out Air Return Fan System Atmospheric Dump Valve Beginning of Cycle Constant Axial Offset Control Component Cooling System Code of Federal Regulations Core Operating Limits Report Control Room Emergency Ventilation System Containment Spray System Condensate Storage Tank Departure from Nucleate Boiling Emergency Core Cooling System Effective Full-Power Days Emergency Gas Treatment System End of Cycle Essential Raw Cooling Water Engineered Safety Feature Engineered Safety Features Actuation System High Efficiency Particulate Air Heating, Ventilating, and Air-Conditioning Limiting Condition For Operation Main Feedwater lsolation Valve Main Feedwater Regulation Valve Main Steam Line lsolation Valve Main Steam Safety Valve Moderator Temperature Coefficient Neutron Monitoring System Offsite Dose Calculation Manual Process Control Program Power Distribution Monitoring System Pressure lsolation Valve Power-Operated Relief Valve Pressure and Temperature Limits Report Quadrant Power Tilt Ratio Relaxed Axial Offset Control Rod Cluster Control Assembly Reactor Coolant Pump Reactor Coolant System Residual Heat Removal Rated Thermal Power Watts Bar-Unit 1 Revision 104 LIST OF ACRONYMS (Page 2 of 2)Acronvm Title RTS Reactor Trip System RWST Refueling Water Storage Tank SG Steam Generator SI Safety lnjection SL Safety Limit SR Surveillance Requirement UHS Ultimate Heat Sink Watts Bar-Unit 1 vil TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page Number: i ii iii iv V vi vii viii ix x xi xii xiii xiv XV xvi xvii xviii xix xx xxi xxii xxiii xxiv xxv xxvi xxvii xxviii xxix Revision Number: 90 94 123 0 0 104 0 137 120 123 135 123 131 136 132 124 19 32 46 60 6B 75 85 94 102 110 120 129 137 Page Number: B 2.0-1 B 2.0-2 B 2.0-3 82.04 B 2.0-5 B 2.0-6 B 2.0-7 B 2.0-8 B 2.0-9 B 2.0-1 0 B 2.0-1 1 B 2.4-12 B 3.0-1 B 3.0-2 B 3.0-3 B 3.04 B 3.0-5 B 3.0-6 B 3.0-7 B 3.0-8 B 3.0-9 B 3.0-9a B 3 0-9b B 3 0-10 B 3.0-1 1 B 3.0-12 B 3 0-1 3 B 3.0-14 B 3.1-1 B 3.1-2 B 3.1-3 B 3.14 B 3.1-5 B 3.1-6 B 3.1-7 B 3 1-8 B 3.1-9 B 3.1-10 B 3 .1-11 B 3.1-12 B 3.1-13 B 3.1-14 B 3.1-15 Revision Number: 0 59 0 59 108 59 0 0 0 0 108 0 133 0 0 68 68 68 0 103 133 133 133 0 137 53 68 68 0 0 0 68 0 0 0 0 68 0 0 01 32 0 0 vilt Watts Bar-Unit 1 Revision 137 TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page Num..hgr: B 3 1-16 B 3.1-17 B 3.1-1 8 B 3.1-1 I B 3.1-20 B 3.1-21 B 3.1-22 B 3.1-23 B 3.1-24 B 3.1-25 B 3.1-26 B 3.1-27 B 3.1-28 B 3.1-29 B 3 1-30 B 3.1-31 B 3.1-32 B 3 1-33 B 3.1-34 B 3.1-35 B 3 1-36 B 3.1-37 B 3.1-38 B 3.1-39 B 3.140 B 3.141 B 3. 142 B 3. 143 B 3144 B 3.1-45 B 3.1-46 B 3.147 B 3.1-48 B 3.1-49 B 3.1-50 B 3 1-51 B 3.1-52 B 3.1-53 B 3.1-54 B 3.1-54a B 3.1-55 B 3.1-56 B 3.1-57 B 3.1-58 B 3.1-59 B 3.1-60 Revision Nqmhpr: 0 0 32 32 32 32 32 0 51 51 0 104 0 0 104 0 0 0 0 51 0 0 0 0 51 0 0 0 0 0 0 0 51 0 0 104 104 104 70 104 0 40 4A 0 0 104 Page N..umb--e""r; B 3.1-61 B 3 1-62 B 3.1-63 B 3.1-64 B 3.1-65 B 3.1-66 B 3.1-67 B 3.2-1 B 3.2-2 B 3.2-3 B 3.24 B 3.2-5 B 3.2-6 B 3.2-7 B 3.2-8 B 3.2-9 B 3.2-1 0 B 3.2-11 B 3.2-12 B 3.2-1 3 B 3.2-14 B 3.2-15 B 3 2-16 B 3.2-17 B 3.2-18 B 3 2-1 I B 3,2-20 B 3.2-21 B 3.2-22 B 3.2-23 B 3.2-24 B 3.2-25 B 3.2-26 B 3.2-27 B 3.2-28 B 3.2-29 B 3.2-30 B 3.3-1 B 3.3-2 B 3.3-3 B 3.34 B 3.3-5 B 3.3-6 B 3.3-7 B 3.3-8 B 3.3-9 Revision Number: 120 4A 40 39 0 39 40 104 39 104 104 0 0 104 104 18 104 0 104 59 104 0 0 144 104 0 0 0 0 0 104 0 104 0 0 104 104 0 0 0 60 60 0 0 0 0 ix Watts Bar-Unit 1 Revision TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page Number;, B 3.3-1 0 B33-1 1 B 3.3-12 B 3.3-1 3 B 3.3-14 B 3.3-1 5 B 3 3-16 B 3.3-17 B 3 3-1 8 B 3.3-19 B 3.3-20 B 3.3-21 B 3.3-22 B 3.3-23 B 3.3-24 B 3.3-25 B 3.3-26 B 3.3-27 B 3.3-28 B 3.3-29 B 3.3-30 B 3.3-31 B 3.3-32 B 3.3-33 B 3.3-34 B 3.3-35 B 3.3-36 B 3.3-37 B 3.3-38 B 3.3-39 B 3.3-40 B 3.341 B 3.342 B 3.343 B 3.344 B 3.3-45 B 3.3-46 B 3.3-47 B 3.3-48 B 3.3-49 B 3 3-50 B 3 3-51 B 3.3-52 B 3.3-53 B 3.3-54 B 3.3-55 B 3.3-56 B 3.3-57 B 3.3-58 Revision Number: 0 0 27 27 0 0 17 13 13 13 0 0 0 90 90 90 90 0 13 13 13 13 13 90 90 13 0 0 0 0 0 90 104 0 0 0 90 90 90 0 90 90 90 90 0 0 104 104 90 Page Numh"g.n B 3.3-59 B 3.3-60 B 3.3-61 B 3.3-62 B 3.3-62a B 3.3-63 B 3.3-64 B 3.3-65 B 3.3-66 B 3.3-67 B 3.3-68 B 3.3-69 B 3.3-70 B 3.3-71 B 3.3-72 B 3 3-73 B 3.3-74 B 3.3-75 B 3.3-76 B 3.3-77 B 3.3-78 B 3.3-79 B 3.3-80 B 3.3-81 B 3.3-82 B 3.3-83 B 3.3-84 B 3.3-85 B 3.3-86 B 3.3-87 B 3.3-88 B 3 3-89 B 3 3-90 B 3.3-91 B 3 3-92 B 3.3-93 B 3.3-94 B 3.3.94a B 3 3-95 B 3.3-96 B 3.3-97 B 3.3-98 B 3.3-99 B 3.3-1 00 B 3.3-1 01 B 3.3-1 02 B 3.3-1 03 B 3.3-1 04 B 3.3-105 Revision Number: 90 0 90 90 90 104 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 I I 0 0 0 0 0 0 0 0 0 0 13 0 109 109 2 0 0 0 0 0 0 123 90 90 90 123 Watts Bar-Unit 1 Revision 123 TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page NUmbef;B 3.3-1 06 B 3.3-107 B 3.3-1 0B B 3 3-109 B 3 3-1 10 B 3.3-111 B 3.3-112 B 3.3-1 13 B 3.3-114 B 3.3-1 15 B 3.3-1 16 B 3 3-117 B 3.3-1 18 B 3.3-1 18a B 3.3-1 19 B 3.3-120 B 3.3-121 B 3.3-122 B 3.3-123 B 3.3-124 B 3.3-125 B 3.3-126 B 3.3-127 B 3.3-128 B 3.3-129 B 3.3-1 30 B 3.3-1 3'1 B 3.3-132 B 3 3-1 33 B 3.3-134 B 3.3-1 35 B 3 3-1 36 B 3.3-137 B 3 3-1 38 B 3.3-1 39 B 3.3-140 B 3.3-141 B 3.3-142 B 3.3-143 B 3.3-144 B 3.3-145 B 3.3-146 B 3.3-147 B 3.3-148 B 3.3-149 83.3-1 50 83.3-1 51 83.3-1 52 Revision Num,hgf: 123 90 96 96 90 90 90 90 90 90 95 1 34 90 34 96 0 0 0 0 0 0 0 0 0 94 94 94 94 135 94 94 94 94 94 94 0 0 68 0 0 0 48 0 0 0 Page l$unhg.J:.

83.3-1 53 83.3-154 83.3-1 54A B 3 3-1s5 B 3.3-1 56 B 3.3-157 83 3-1 58 B 3.3-1 59 B 3 3-160 B 3.3-161 B 3.3-162 B 3 3-163 B 3.3-164 B 3 3-165 B 3 3-166 B 3.3-167 B 3.3-168 B 3.3-169 B 3.3-170 B 3.3-171 B 3.3-172 B 3.3-173 B 3.3-174 B 3.3-175 B 3.3-176 B 3.3-177 B 3.3-178 B 3.4-1 B 3.4-2 B 3.4-3 B 3.44 B34-5 B 3.4-6 B34-7 B 3.4-8 B 3.4-9 B 3.4-10 B 3.4-11 B 3.4-12 B 3.4-1 3 B 3.4-14 B 3.4-1 5 B 3.4-16 B 3.4-17 B 3.4-1 8 B 3.4-1 I B 3.4-20 B 3.4-21 Revision Numbqr: 0 119 119 9 119 119 119 119 90 26 90 0 45 0 0 45 0 0 0 119 119 119 119 119 119 119 119 0 60 60 29 60 0 55 29 0 0 0 0 0 0 0 0 0 82 82 0 0 0 0 Watts Bar-Unit 1 Revision 135 TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page Num.h"p.r:

B 3.4-22 B 3.4-23 B 3.4-24 B 3.4-25 B 3.4-26 B 3.4-27 B 3.4-28 B 3.4-29 B 3 4-30 B 3.4-31 B 3.4-32 B 3.4-33 B 3.4-34 B 3.4-35 B 3.4-36 B 3.4-37 B 3.4-38 B 3.4-39 B 3.4-40 B 3.4-41 B 3.4-42 B 3.4-43 B 3.4-44 B 3.4-45 B.3.446 B 3.447 B 3.4-48 B 3.4-49 B 3.4-50 B 3.4-51 B 3.4-52 B 3.4-53 B 3.4-54 B 3.4-55 B 3.4-56 B 3.4-57 B 3.4-58 B 3.4-59 B 3 4-60 B 3.4-61 B 3.4-62 B 3.4-63 B 3.4-64 B 3.4-65 B 3.4-66 B 3.4-67 B 3.4-68 Revision NumbeI 0 82 0 79 29 123 123 123 123 123 79 79 79 82 79 29 0 68 0 0 0 0 29 29 0 0 0 89 89 0 42 6B 42 42 42 89 0 0 0 0 0 0 0 68 0 68 0 Page N.unl,h,H,r; B 3.4-69 8.3.4-70 B 3.4-71 B 3.4-72 B 3.4-73 B 3.4-74 B 3.4-75 B 3.4-76 B 3 4-77 B 3.4-78 B 3.4-79 B 3.4-80 B 3.4-81 B 3.4-82 B 3 4-83 B 3.4-84 B 3.4-85 B 3.4-86 B 3,4-87 B 3.4-88 B 3.4-89 B 3.4-90 B 3.4-91 B 3.4-92 B 3.4-93 B 3.4-94 B 3.4-95 B 3.4-96 B 3.4-97 B 3.4-98 B 3.4-99 B 3.4-1 00 B 3.4-101 B 3.4-102 B 3.4-103 B 3.4-104 B 3.5-1 B 3.5-2 B35-3 B 3.5-4 B 3.5-5 B 3.5-6 B 3.5-7 B 3.5-8 B 3.5-9 B 3.5-1 0 B 3.5-1 1 Revision Numbe[0 0 7 7 89 82 82 82 82 82 82 82 0 0 0 0 89 89 92 12 92 92 92 92 52 118 52 118 118 118 82 82 82 82 82 82 0 39 39 39 0 98 98 0 98 61 0 xil Watts Bar-Unit 1 Revision 123 TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page lSunDer.;B 3.5-12 B 3.5-1 3 B 3.5-14 B 3.5-15 B 3 5-16 B 3.5-17 B 3 5-18 B 3.5-19 B 3.5-20 B 3.5-21 B 3.5-22 B 3.5-23 B 3.5-24 B 3 5-25 B 3.5-26 B 3.5-27 B 3.5-28 B 3.5-29 B 3.5-30 B 3.5-31 B 3.5-32 B 3.5-33 B 3.5-34 B 3.6-1 B 3.6-2 B36-3 B 3.6-4 B 3.6-5 B 3.6-6 B 3.6-7 B 3.6-8 B36-9 B 3 6-10 B36-1 1 B 3.6-12 B 3.6-1 3 B 3.6-14 B 3.6-15 B 3 6-16 B 3.6-17 B 3 6-18 B 3.6-19 B 3.6-20 B 3.6-21 B 3.6-22 B 3.6-23 B 3.6-24 Revision Numbs.t.39 39 68 68 0 62 89 80 0 68 0 0 0 0 131 131 0 29 29 0 0 0 29 10 10 130 10 10 5 10 130 0 0 0 10 10 0 0 0 130 9B 98 0 98 98 98 98 Page Numh.p".r; B 3.6-25 B 3.6-26 B 3.6-27 B 3.6-28 B 3.6-29 B 3.6-30 B 3.6-31 B 3 6-32 B 3 6-33 B 3.6-34 B 3.6-35 B 3.6-36 B 3.6-37 B 3.6-38 B 3 6-39 B 3.640 B 3.6-41 B3642 B 3.6-43 B 3.6-44 B3645 B 3.6-46 B 3.6-47 B 3.6-48 B 3.6-49 B 3.6-50 B 3.6-s1 B 3.6-52 B 3.6-53 B 3.6-54 B 3.6-55 B 3 6-s6 B 3.6-57 B 3 6-58 B 3.6-59 B 3.6-60 B 3.6-61 B 3.6-62 B 3.6-63 B 3.6-64 B 3.6-65 B 3.6-66 B 3.6-67 B 3.6-68 B 3.6-69 B 3.6-70 B 3.6-71 Revision N,unber: 10 10 10 127 0 71 0 0 29 29 0 0 127 100 0 98 83 89 94 94 94 94 94 94 0 128 0 0 0 16 0 102 71 29 101 0 0 0 0 0 81 0 0 0 29 81 36 xilt Watts Bar-Unit 1 Revision 131 TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page Nu.mher: B 3.6-72 B 3.6-72a B 3.6-73 B 3.6-74 B 3.6-75 B 3.6-76 B 3.6-77 B 3.6-78 B 3 6-79 B 3.6-80 B 3.6-81 B 3.6-82 B 3 6-83 B 3.6-84 B 3 6-85 B 3.6-86 B 3.6-87 B 3.6-88 B 3.6-89 B 3.6-90 B 3.6-91 B 3.6-92 B 3.6-93 B 3.6-94 B 3.6-95 B 3.6-96 B 3.6-97 B 3.6-98 83 6-99 B 3.7-1 B 3.7-2 B 3.7-3 B 3.74 B 3.7-5 B 3.7-6 B 3.7-7 B 3.7-8 B 3.7-9 B 3.7-10 B 3.7-11 B 3.7-12 B 3.7-13 B 3.7-14 B 3.7-1 5 B 3.7-16 B 3.7-17 B 3.7-18 B.3.7-19 B 3.7-20 Revision Number.36 36 36 0 0 0 0 36 0 6 6 21 6 0 0 0 0 0 0 0 0 0 0 0 129 129 129 129 129 31 31 41 121 121 89 0 0 0 0 0 89 76 0 0 0 76 89 89 0 Page N.-u.mh"p"r; B 3.7-21 B 3.7-22 B 3.7-23 B 3.7-24 B 3.7-25 B 3.7-26 B 3.7-27 B 3.7-28 B 3.7-29 B 3 7-30 B 3.7-31 B 3.7-32 B 3.7-33 B 3.7-34 B 3 7-35 B 3.7-36 B 3.7-37 B 3.7-38 B 3.7-39 B 3.740 B 3.741 B 3.742 B 3.743 B 3.744 B 3.745 B 3.746 B 3.747 B 3.748 B 3.7-49 B 3.7-50 B 3.7-51 B 3.7-52 B 3.7-53 B 3.7-54 B 3.7-55 B 3.7-56 B 3.7-57 B 3.7-57a B 3.7-58 B 3.7-59 B 3.7-59a B 3.7-60 B 3.7-61 B 3.7-62 B 3.7-62a B 3.7-63 B 3.7-64 B 3.7-65 B 3.7-66 Revision Number: 0 68 24 0 0 0 0 68 0 0 89 20 89 0 41 0 29 136 0 136 136 136 0 0 0 0 0 0 0 29 91 91 91 117 122 122 91 91 64 64 134 45 64 119 119 119 119 119 35 xiv Watts Bar-Unit 1 Revision 136 TECHNICAL SPECIFICATIONS BASES LIST OF EFFECTIVE PAGES Page Number.B 3.7-67 B 3.7-68 B 3.7-69 B 3.7-70 B 3.7-71 B 3.7-72 B 3.7-73 B 3.7-74 B 3.7-75 B 3.7-76 B 3.7-77 B 3.7-78 B 3.7-79 B 3.7-80 B 3.7-81 B 3.7-82 B 3.7-83 B 3.7-84 B 3.7-8s B 3.7-86 B 3.7-87 B 3.7-88 B 3.7-89 B 3.7-90 B 3.8-1 B 3.8-2 B 3.8-3 B 3.8-4 B 3.84a B 3.84b B 3.8-4c B 3.8-5 B 3.8-6 B 3.8-7 B38-8 B 3.8-8a B38-9 B 3.8-1 0 B 3.8-1 0a B 3.8-1 1 B 3.8-12 B 3.8-1 3 B 3.8-14 B 3.8-1 5 B 3 8-16 B 3.8-17 B 3.8-18 B 3.8-1 I B 3.8-20 B 3.8-21 Revision Numb.p-r;119 119 0 119 47 0 0 0 61 61 61 123 123 123 123 123 123 123 123 123 123 123 123 123 125 132 132 125 125 125 125 125 0 132 132 132 132 132 132 132 132 132 132 132 125 0 29 125 125 115 Page Nurnber: B 3.8-22 B 3.8-23 B 3.8-24 B 3.8-25 B 3.8-26 B 3.8-27 B 3.8-28 B 3.8-29 B 3 8-30 B 3.8-31 B 3.8-32 B 3.8-33 B 3.8-34 B 3.8-35 B 3.8-36 B 3.8-36a B 3.8-37 B 3.8-38 B 3.8-39 B 3.8-40 B 3.841 B 3.842 B 3.8-43 B 3.8-44 B 3.845 B3846 B 3.847 B 3.8-48 B 3.849 B 3 8-50 B 3.8-s1 B 3.8-52 B 3.8-53 B 3.8-54 B 3 8-55 B 3,8-56 B 3.8-57 B 3.8-58 B 3.8-59 B 3.8-60 B 3.8*1 B 3 8-62 B 3.8-63 B 3.8-64 B 3.8-65 B 3 8-66 B 3.8-67 B 3.8-68 B 3.8-69 B 3.8-70 Revision N-u.mh"gn 115 115 0 0 115 19 50 115 0 115 132 0 125 125 125 132 0 0 0 0 0 0 0 0 0 0 55 55 0 0 29 106 29 105 0 113 113 0 0 0 69 0 112 66 19 19 19 0 0 0 Watts Bar-Unit 1 Revision 132 TECHNICAL SPECIFICATIONS BASES LIST OF Revision Nqmbet";0 0 0 0 0 0 0 0 0 0 97 97 97 75 0 97 75 0 125 0 78 0 78 0 0 0 0 124 0 0 0 0 0 0 68 0 0 68 0 0 0 0 0 119 119 119 119 119 0 23 EFFECTIVE PAGES Page Num..h""p.r; 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: 6) 07-28-97 Spent Fuel Pool Rerack Revision 12 09-10-97 Heat Trace for Radiation Monitors Revision 13 (Amendment

: 7) 09-11-97 Cycle 2 Core Reload Revision 14 10-10-97 Hot Leg Recirculation Timeframe Revision 15 02-12-98 EGTS Logic Testing Revision'16 (Amendment  

: 11) 09-09-98 Relocation of F(Q) Penalty to COLR Revision 19 (Amendment  

: 12) 10-19-98 Online Testing of the Diesel Batteries and Performance of the 24 Hour Diesel Endurance Run Watts Bar-Unit 1 XVii Revision 19 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT Revision 20 (Amendment  

: 13) 10-26-98 Clarification of Surveillance Testing Requirements for TDAFW Pump Revision 21 11-30-98 Clarification to lce Condenser Door ACTIONS and door lifi tests, and lce Bed sampling and flow blockage SRs Revision 22 (Amendment  

: 14) 11-10-98 COMS - Four Hour Allowance to Make RHR Suction Relief Valve Operable Revision 23 01-05-99 RHR Pump Alignment for Refueling Operations Revision 24 (Amendment  

: 16) 12-17-98 New action for Steam Generator ADVs due to lnoperable ACAS.Revision 25 02-08-99 Delete Reference to PORV Testing Not Performed in Lower Modes Revision 26 (Amendment  

: 17) 12-30-98 Slave Relay Surveillance Frequency Extension to 18 Months Revision 27 (Amendment  

'18) 01-15-99 Deletion of Power Range Neutron Flux High Negative Rate Reactor Trip Function Revision 28 04-02-99 P2500 replacement with lntegrated Computer System (lCS). Delete Reference to ERFDS as a redundant input signal.Revision 29 03-13-00 Added notes to address instrument error in various parameters shown in the Bases.Also corrected the applicable modes for TS 3.6.5 from 3 and 4 to 2,3 and 4.Revision 30 (Amendment  

: 23) 03-22-00 For SR 3.3.2.10, Table 3.3.2-1, one time relief from turbine trip response time testing. Also added Reference 14 to the Bases for LCO 3.3.2.Revision 31 (Amendment  

: 19) 03-07-00 Reset Power Range High Flux Reactor Trip Setpoints for Multiple lnoperable MSSVS.I Revision 32 O4-13-OO Clarification to Reflect Core Reactivity and I nltrc Behavior.Watts Bar-Unit 1 xvilt Revision 32 TECHNICAL SPECIFICATION BASES . REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT 0s-02-00 Revision 33 Revision 34 (Amendment 24)Revision 35 Revision 36 (Amendments 22 and 25)Revision 37 (Amendment 26)Revision 38 Revision 39 (Amendments 21and 28)Revision 40 Revision 41 (Amendment 31)Revision 42 Revision 43 Revision 44 (Amendment 33)Revision 45 (Amendment 35)Revision 46 07-07-00 08-14-00 08-23-00 09-08-00 09-17-00 09-1 3-00 09-28-00 01-22-01 03-07-01 05-29-01 01-31-02 02-12-A2 a2-25-42 Clarification identifying four distribution boards primarily used for operational convenience.

Elimination of Response Time Testing Clarification of ABGTS Surveillance Testing Revision of lce Condenser sampling and flow channel surveillance requirements Administrative Controls for Open Penetrations During Refueling Operations SR 3.2.1.2 was revised to reflect the area of the core that will be flux mapped.Amendment 21 - lmplementation of Best Estimate LOCA analysis.Amendment 28 - Revision of LCO 3.1 .10,"Physics Tests Exceptions - Mode 2." Clarifies WBN's compliance with ANSI/ANS-19.6.1 and deletes the detailed descriptions of Physics Tests.Power Uprate from 3411 MWt to 3459 MWt Using Leading Edge Flow Meter (LEFM)Clarify Operability Requ irements for Pressu rizer PORVs Change CVI Response Time from 5 to 6 Seconds lce weight reduction from 1236 to 1110 lbs per basket and peak containment pressure revision from 11 .21 to 10.46 psig.Relaxation of CORE ALTERATIONS Restrictions Clarify Equivalent lsolation Requirements in LCO 3.9.4 Watts Bar-Unit 1 xix Revision 46 TECHNICAL SPECIFICATION BASES . REVISION LISTING (This listing is an administrative tool malntained by WBN Licensing and may be updated without formally revising the Technical Speclfication Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT Revision 47 (Amendment  

: 38) 03-01-02 RCS operational LEAKAGE and SG Alternate Repair Criteria forAxial Outside Diameter Stress Corrosion Cracking (oDSCC)Revision 48 (Amendment  

: 36) 03-06-02 lncrease Degraded Voltage Time Delay from 6 to 10 seconds.Revision 49 (Amendment  

: 34) 03-08-02 Deletion of the PoslAccident Sampling System (PASS) requirements from Section 5.7.2.6 of the Technical Specifications.

: 39) 08-30-02 Extension of the allowed outage time (AOT)for a single diesel generator from 72 hours to 14 days.Revision 51 11-14-02 Clarify that Shutdown Banks C and D have only One Rod Group Revision 52 (Amendment 4'l) 12-20-02 RCS Specific Activity Level reduction from<1.0 pCi/gm to <0.265 pCi/gm.Revision 53 (Amendmenl42) 01-24-A3 Revise SR 3.0.3 for Missed Surveillances Revision 54 (Amendment  

: 43) 05-01-03 Exigent TS SR 3.5.2.3 to delete Sl Hot Leg lnjection lines from SR untilUlC5 outage.Revision 55 05-22-03 Editorialcorrections (PER 02-015499), correct peak containment pressure, and revise l-131 gap inventory for an FHA.Revision 56 07-10-03 TS Bases for SRs 3.8.4.8 through SR 3. 8.4. 1 0 clarifi cation of inter-tier connection resistance test.Revision 57 08-11-03 TS Bases for B 3.5.2 Background information provides clarification when the 9 hrs for hot leg recirculation is initiated.

: 45) 09-26-03 The Bases for LCO 3.8.7 and 3.8.8 were revised to delete the Unit 2 lnverters.

: 46) 09-30-03 Address new DNB Correlation inB.2.1.1 and B,3.2.12 for Robust FuelAssembly (RFA)-2.Revision 60 (Amendmenl4T) 10-06-03 RCS Flow Measurement Using Elbow Tap Flow Meters (Revise Table 3.3.1-1(10)  

&sR 3.4.1.4).Watts Bar-Unit 1 Revision 60 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT Revision 62 Revision 63 Revision 64 (Amendment 50)Revision 65 Revision 66 Revision 67 (Amendment 45)Revision 68 (Amendment 55)Revision 61 (Amendments 40 and 48)1 0-14-03 lncorporated changes required to implement the Tritium Program (Amendment  

: 40) and Stepped Boron Concentration increases for RWST and CLAs (Amendment  

: 48) depending on the number of TPBARS installed into the reactor core.Clarified ECCS venting in Bases Section B 3.5.2 (WBN-TS-03-1 9)The contingency actions listed in Bases Table 3.8. 1-2were reworded to be consistent with the NRC Safety Evaluation that approved Tech Spec Amendment 39.lncorporated Amendment 50 for the seismic qualification of the Main Control Room duct work. Amendment 50 revised the Bases for LCO 3.7.10, .CREVS," and LCO 3.7 .11,'CREATCS." An editorial correction was made on Page B 3.7-61.Revised the Bases for Action B.3.1 of LCO 3.8.1 to clarify that a common cause assessment is not required when a diesel generator is made inoperable due to the performance of a surveillance.

Revised Page B 3.8-64 (Bases for LCO 3.8.4) to add a reference to SR 3.8.4.13 that was inadvertently deleted by the changes made for Amendment 12.Revised the Bases for LCOs 3 .8.7, 3.8.8 and 3.8.9 to incorporate changes to the Vital lnverters (DCN 51370). Refer to the changes made for Bases Revision 58 (Amendment 45)Amendment 55 modified the requirements for mode change limitations in LCO 3.0.4 and SR 3.0.4 by incorporating TSTF-359, Revision 9.10-15-03 12-08-03 03-23-04 04-01-04 05-21-04 03-0s-05 03-22-05 Watts Bar-Unit 1 xxt Revision 68 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REV!SIONS ISSUED SUBJECT Revision 68 (Amendment 55 and 56)Revision 69 (Amendment 54)Revision 70 (Amendment 58)Revision 7 1 (Amendment 59)Revision 72 Revision 73 Revision 74 Revision 75 (Amendment 45)03-22-05 04-04-05 1 0-17 -05 02-01-06 08-31-06 09-1 1-06 09-16-06 09-18-06 Change MSLB primary to secondary leakage from 1 gpm to 3 gpm (WBN-TS 14).Revised the use of the terms inter-tier and inter-rack in the Bases for SR 3.8.4.10.Alternate monitoring process for a failed Rod Position lndicator (RPl) (TS-03-1 2).Temporary Use of Penetrations in Shield Building Dome During Modes 1-4 (WBN-TS-04 -17)M inor Revision (Corrects Typographical Error) - Changed LCO Bases Section 3.4.6 which incorrectly referred to Surveillance Requirement 3 .4.6.2 rather than correctly identifying Surveillance Requirement 3.4.6.3.Updated the Bases for LCO 3.9.4 to clarify that penetration flow paths through containment to the outside atmosphere must be limited to less than the ABSCE breach allowance.

AIso administratively removed from the Bases for LCO 3 .9.4 a statement on core alterations that should have been removed as part of Amendment 35.For the LCO section of the Bases for LCO 3.9.4, adrninistratively removed the change made by Revision 73 to the discussion of an LCO note and placed the change in another area of the LCO section.Revised the Bases for LCOs 3.8.7, 3.8.8 and 3.8.9 to incorporate a spare inverter for Channel 1-ll of the Vital lnverters (DCN 51370).Watts Bar-Unit 1 xxii Revision 75 TECHNICAL SPECIFICATION BASES . REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT Revision 76 (Amendment 45)09-22-06 Revis ton 77 (Amendment 45)Revision 78 (Amendment 45)Revision 79 (Amendment 60, 61 64)Revision 80 Revision 81 (Amendment 62)Revision 82 (Amendment 65)Revision 83 Revision 84 Revision 85 and 10-10-06 10-13-06 1 1-03-06 1 1-08-06 11-15-06 11-17-06 11-20-06 1 1-30-06 03-22-07 Revised the Bases for LCOs 3.8.7, 3.8.8 and 3.8.9 to incorporate a spare inverter for Channel 1-lV of the Vital lnverters (DCN 51370).Revised the Bases for LCOs 3.8.7, 3.8.8 and 3.8.9 to incorporate a spare inverter for Channel 1-l of the Vital lnverters (DCN 51370).Revised the Bases for LCOs 3.8.7, 3.8.8 and 3.8.9 to incorporate a spare inverter for each of the Vital lnverters (DCN 51370).Steam Generator Narrow Range Level lndication lncreased from 6a/o to 32% (WBN-T5-05-06)

Bases Sections 3.4.5, 3.4.6, and 3.4.7.Revised the Bases for SR 3.5.2.8 to clarify that inspection of the containment sump strainer constitutes inspection of the trash rack and the screen functions.

Revised the Bases for SR 3.6. 11.2, 3.6.11.3, and 3.6.11.4 to address the lncrease lce Weight in lce Condenser to Support Replacement Steam Generators (WBN-TS-05-0e) [sGRP]Steam Generator (SG) Tube lntegrity (wBN-rs-05-1  

: 0) [SGRP]Updated Surveillance Requirement (SR)3.6.6.5 to clarify that the number of unobstructed spray nozzles is defined in the design bases.Revised Bases 3.6.9 and 3.6.15 to show the operation of the EGTS when annulus pressure is not within limits.Revised Bases 3.6.9 and 3.6.15 in accordance with TACF 1-07-0002-065 to clarify the operation of the EGTS.Watts Bar-Unit 1 xxiii Revision 85 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT 01-31-08 Revision 86 Revision 87 Revision 88 (Amendment 67)Revision 89 (Amendment 66)Revision 90 (Amendment 68)Revision 91 (Amendment 70)Revision 92 (Amendment 71)Revision 93 (Amendment 74)Revision 94 (Amendment 72)02-12-08 03-06-08 05-01-08 10-02-08 11-25-2008 11-26-2008 02-09-2009 02-23-2009 Figure 3.7.15-1 was deleted as part of Amendment

: 40. A reference to the figure in the Bases for LCO 3.9.9 was not deleted at the time Amendment 40 was incorporated into the Technical Specifications.

Bases Revision 86 corrected this error (refer to PER 130e44).lmplemented Bases change package TS-07-13 for DCN 52220-A. This DCN ties the ABI and CVI signals together so that either signal initiates the other signal.Technical Specification Amendment 67 increased the number of TPBARs from 240 to 400.Update of Bases to be consistent with the changes made to Section 5.7 .2.11 of the Technical Specifications to reference the ASME Operation and Maintenance Code lssuance of amendment regarding Reactor Trip System and Engineered Safety Features Actuation System completion times, bypass test times, and su rveillance test intervals The Bases for TS 3.7.10, "Control Room Emergency Ventilation System (CREVS)" were revised to address control room envelope habitabi I ity.The Bases for TS 3.4.1 5, "RCS Leakage Detection lnstrumentation" were revised to remove the requirement for the atmospheric gaseous radiation monitor as one of the means for detecting a one gpm leak within one hour.Updates the discussion of the Allowable Values associated with the Containment Purge Radiation Monitors in the LCO section of the Bases for LCO 3.3.6.Bases Revision 94 [Technical Specification (TSX Amendment 72 deleted the Hydrogen Recombiners (LCO 3.6.7) from the TS and moved the requirements to the Technical Requirements Manual.Watts Bar-Unit 1 xxiv Revision 94 TECHNICAL SPECIFICATION BASES . REVISION LISTING (This listing is an administratave tool maintained by WBN Lacensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT Revision 95 03-05-2009 Corrected an error in SR 3.3.2.6 which referenced Function 6.9 of TS Table 3.3.2-1.This function was deleted from the TS by Amendment 1.Revision 96 (Amendment  

: 75) 06-19-2009 Modified Mode 1 and 2 applicability for Function 6.e of TS Table 3.3.2-1 , Engineered Safety Feature Actuation System lnstrumentation." This is associated with AFW automatic start on trip of all main feedwater pumps. ln addition, revised LCO 3.3.2, Condition J, to be consistent with WBN Unit 1 design bases.Revision 97 (Amendment  

: 76) 09-23-2009 Amendment 76 updates LCO 3.8.7,"lnverters - Operating" to reflect the installation of the Unit 2 inverters.

Revision 98 (Amendments 77, 79, & 10-05-2009 Amendment 77 revised the number of 81) TPBARS that may be loaded in the core from 4OO to 704.Amendment 79 revised LCO 3.6.3 to allow verification by administrative means isolation devices that are locked, sealed, or otherwise secured.Amendment 81 revised the allowed outage time of Action B of LCO 3.5.1 from t hour to 24 hours.Revision 99 10-09-2009 Bases Revision 99 incorporated Westinghouse Technical Bulletin (TB) 08-04.Revision 100 11-17-2009 Bases Revision 100 revises the LCO description of the Containment Spray System to clarify that transfer to the containment sump is accomplished by manualactions.

Revision 101 02-09-2010 Bases Revision 101 implemented DCN 52216-A that will place both trains of the EGTS pressure controlvalve's hand switches in A-AUTO and will result in the valves opening upon initiation of the Containment lsolation phase A (ClA) signal.They will remain open independent of the annulus pressure and reset of the ClA.Revision 102 03-01-2010 Bases Revision 102 implemented EDC 52564-A which addresses a new single failure scenario relative to operation of the EGTS post LOCA.Watts Bar-Unit 1 Revision 102 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS ISSUED SUBJECT Revision 103 Revision 104 (Amendment 82)Revision 105 Revision 106 Revision 107 (Amendment 85)Revision 108 Revision 109 Revision 1 10 04-05-2010 09-20-2010 10-28-2A10 01-20-2011 02-24-2011 03-07-2011 04-06-2011 04-19-2011 Bases Revision 103 implemented NRC guidance "Application of Generic Letter 80-30" which allows a departure from the single failure criterion where a non-TS support system has two 100% capacity subsysteffis, each capable of supporting the design heat load of the area containing the TS equipment.

Bases Revision 104 implemented License Amendment No. 82, which approved the BEACON-TSM application of the Power Distributing System. The PDMS requirements reside in the TRM.DCN 53437 added spare chargers 8-S and 9-S which increased the total of 125 VDC Vital Battery Chargers to eight (8)Revised SR 3.8.3.6 to clarify that identified fuel oil leakage does not constitute failure of the surveillance.

Amendment 85 revises TS 3.7.11, "Control Room Emergency Air Temperature Control System (CREATCS).

Specifically, the proposed change will only be applicable during plant modifications to upgrade the CREATCS chillers.

This "one-time" TS change will be implemented during Watts Bar Nuclear Plant, Unit 1 Cycles 10 and 1 1 beginning March 1,2A1 1, and ending April 30,2012.Bases Revision 108 deletes reference to NSRB to be notified of violation of a safety limit within 24 hours in TSB 2.2.4. Also, corrected error in SR 3.3.2.4 in the reference to Table 3.3.1-1 . lt should be Table 3.3.2-1 .Bases Revision 109 clarifies that during plant startup in Mode 2 the AFW anticipatory auto-start signal need not be OPERABLE if the AFW system is in service. PER 287712 was identified by NRC to provide clarification to TS Bases 3.3.2, Function 6.e, Trip of All Turbine Driven Main Feedwater Pumps.Clarified the text associated with the interconnection of the ABI and CVI functions in the bases for LCO 3.3.6, 3.3.8, 3 .7.12 and 3 9.8.xxvi Watts Bar-Unit 1 Revision 1 10 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS Revision 11 1 Revision 112 Revision 1 13 Revision 114 Revision 1 15 Revision 1 16 Revision 117 Revision 1 18 Revision 1 19 ISSUED 05-05-2011 05-24-2011 06-24-2011 12-12-2011 12-21-2011 06-27-2012 07 2012 01-30-2013 08-17 -2013 SUBJECT Added text to several sections of the Bases for LCO 3.4.16 to clarify that the actual transient limit for l-131 is 14 pCilgm and refers to the controls being placed in AOI-28.DCN 55076 replaces the existing four 125-Vdc DG Battery Chargers with four sets of redundant new battery charger assemblies.

Final stage implementation of DCN 55076 which replaced the existing four 125-Ydc DG Battery Chargers with four sets of redundant new battery charger assemblies.

Clarifies the acceptability of periodically using a portion of the 25o/o grace period in SR 3.0.2 to facilitate 13 week maintenance work schedules.

Revises several surveillance requirements notes in TS 3.8.1 to allow performance of surveillances on WBN Unit 2 6.9 kV shutdown boards and associated diesel generators while WBN Unit 1 is operating in MODES 1, 2,3, or 4 Revises TS Bases 3.8.1 , AC Sources -Operating, to make the TS Bases consistent with TS 3.8.1, Condition D Revises TS Bases 3.7 .1 0, Control Room Emergency Ventilation System (CREVS), to make the TS Bases consistent with TS 3 .7.10, Condition E Revises TS Bases 3.4.16, Reactor Coolant System (RCS) to change the dose equivalent l-1 31 spike limit and the allowable value for control room air intake radiation monitors.Revises TS Bases 3.3.6, 3.3.8, 3.7.12, 3.7 .1 3, 3 .9.4,3.9.7 , 3.9.8, and adds TS Bases 3.9.10 to reflect selective implementation of the Alternate Source Term methodology for the analysis of Fuel Handling Accidents (FHAs) and make TS Bases consistent with the revised FHA dose analysis.Watts Bar-Unit 1 xxvii Revision 1 19 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS Revision 120 Revision 121 Revision 122 (Amendment 94)Revision 123 (Amendment 104)Revision 124 Revision 125 (Amendment 84, 102, 1 03)Revision 126 Revision 127 ISSUED 01-23-2014 08-04-2014 01-1 4-2014 03-16-2016 02-12-2016 03-16-2016 03-18-2016 04-1 8-2016 SUBJECT Revised the References to TS Bases 3.1.9, PHYSICS TESTS Exceptions - Model , to document NRC approval of WCAP 12472-P-A. Addendum 1-A and 4-4., Addendum 1-A approved the use of the Advance Nodal Code (ANC-Phoenix_

in the BEACON system as the neutronic code for measuring core power distribution.

ls also approved the use of fixed incore self-powered neutron detectors (SPD) to calibrate the BEACON system in lieu of incore and excore neutron detectors and core exit thermocouples (CET). For plants that do not have SPDs Addendum 4-A approved Westinghouse methodology that allow the BEACON system to calculate CET uncertainty as a function of reactor power on a plant cycle basis during power ascension following a refueling outage.Revises references in TS Bases 3.7.1 for consistency with changes to the TS Bases 3.7.1 references approved in Revision 89.Revises TS Bases 3.7 .1 0, Control Room Emergency Ventilation System (CREVS) to make the TS Bases consistent with TS 3.7 .1 0, Actions E, F, G, and H.Amendment 104, TSB Revision 123 adds TS 83.7.16, "Component Cooling System (CCS) - Shutdown" and adds TS 83.7.17,"Essential Raw Cooling Water (ERCW)System - Shutdown.Revises TS Bases Table 83.8.9-1 , "AC and DC Electrical Power Distribution Systems," the second Note.Revises TS Bases Section 83.8-1 , "AC Sou rces-Operating.  

" Revises TS Bases Section 83 .7.7,"Component Cooling System" the 1B and 28 surge tank sections.Revises TS Bases Section B 3.6.4,"Containment Pressure" and 83.6.6,"Containment Spray System to change the maximum peak pressure from a LOCA of 9.36 psig.Watts Bar-Unit 1 xxvill Revision 127 TECHNICAL SPECIFICATION BASES - REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

REVISIONS Revision 128 Revision 129 Revision 130 Revision 131 (Amendment 107)Revision 132 (Amendment 1 10)Revision 133 (Amendment 111)Revision 134 (Amendment 112)Revision 135 Revision 136 (Amendment 1 13)Revision 137 (Arnendment 114)ISSUED 06-27 -16 08-1 9-16 12-22-16 01-1 3-17 01-17-17 03-1 3-17 04-25-17 05-1 7 -17 05- 17 -17 07 17 SUBJECT Revises TS Bases Section 83.6.8,"Hydrogen Mitigation System (HMS)", to delete sentence regarding Hydrogen Recombiners that are abandoned.

Revises TS Bases Section 3.6.15, "Shield Building," to clarify the use of the Condition B note.Revises TS Bases Sections 3.6.1, 3.6.2, and 3.6.3 to reflect the deletion of TS 3.9.4 in WBN Unit 1 TS Amendment 92.Revises TS Bases Section 3.5.4, " Refueling Water Storage Tank (RWST), Applicable Safety Analyses" Revises TS Bases Section 3.8.1 , 'AC Sources -Operating" Adds TS Bases Section 3.0.8 for I noperability of Snubbers.Revise TS Bases Section 3.7.11Action A.1 regarding CREATCS.Revises TS Bases Section 83.3.3, "PAM lnstrumentation" Revises TS Bases Section 83 .7.7 "CCS'Revises TS Bases Section B SR 3 .0.2 to add a one-time extension for the surveillance interval.Watts Bar-Unit 1 xxtx Revision 137 TECHNICAL SPECIFICATION BASES . REVISION LISTING (This listing is an administrative tool maintained by WBN Licensing and may be updated without formally revising the Technical Specification Bases Table-of-Contents)

Watts Bar-Unit 1 ENCLOSURE 2 WBN UNIT 1 TECHNIGAL SPECIFICATION BASES CHANGED PAGES E-2 LCO Applicability B30 B 3.0 LTMTTTNG CONDTTTON FOR OPERATTON (tCO) APPLlCABlLTTY BASES LCOs LCO 3.0.1 through LCO 3.0.8 establish the general requirements applicable to all I Specifications and apply at all times, unless otherwise stated.LCO 3.0.1 LCO 3.0.1 establishes the Applicability statement within each individual Specification as the requirement for when the LCO is required to be met (i.e., when the unit is in the MODES or other specified conditions of the Applicability statement of each Specification).

LCO 3.0.2 LCO 3.0.2 establishes that upon discovery of a failure to meet an LCO, the associated ACTIONS shall be met. The Completion Time of each Required Action for an ACTIONS Condition is applicable from the point in time that an ACTIONS Condition is entered. The Required Actions establish those remedial measures that must be taken within specified Completion Times when the requirements of an LCO are not met. This Specification establishes that: a. Completion of the Required Actions within the specified Completion Times constitutes compliance with a Specification; and b. Completion of the Required Actions is not required when an LCO is met within the specified Completion Time, unless otherwise specified.

There are two basic types of Required Actions. The first type of Required Action specifies a time limit in which the LCO must be met. This time limit is the Completion Time to restore an inoperable system or component to OPEMBLE status or to restore variables to within specified limits. lf this type of Required Action is not completed within the specified Completion Time, a shutdown may be required to place the unit in a MODE or condition in which the Specification is not applicable. (Whether stated as a Required Action or not, correction of the entered Condition is an action that may always be considered upon entering ACTIONS.)

The second type of Required Action specifies the remedial measures that permit continued operation of the unit that is not further restricted by the Completion Time. ln this case, compliance with the Required Actions provides an acceptable level of safety for continued operation.(continued)

Revision 133 Amendment 111 Watts Bar-Unit 1 B 3.0-1 LCO Applicability B30 BASES LCO 3.0.7 There are certain specialtests and operations required to be performed at various times over the life of the plant. These special tests and operations are necessary to demonstrate select plant performance characteristics, to perform special maintenance activities, and to perform special evolutions.

Test Exception LCOs 3. 1 .9 and 3.1 . 1 0 allow specified Technical Specification (TS) requirements to be changed to permit performances of these special tests and operations, which otherwise could not be performed if required to comply with the requirements of these TS. Unless othenrvise specified, all the other TS requirements remain unchanged.

This willensure allappropriate requirements of the MODE or other specified condition not directly associated with or required to be changed to perform the special test or operation will remain in effect.The Applicability of a Test Exception LCO represents a condition not necessarily in compliance with the normal requirements of the TS. Compliance with Test Exception LCOs is optional.

A special operation may be performed either under the provisions of the appropriate Test Exception LCO or under the other applicable TS requirements.

lf it is desired to perform the special operation under the provisions of the Test Exception LCO, the requirements of the Test Exception LCO shall be followed.LCO 3.0.8 LCO 3.0.8 establishes conditions under which systems are considered to remain capable of performing their intended safety function when associated snubbers are not capable of providing their associated support function(s).

This LCO states that the supported system is not considered to be inoperable solely due to one or more snubbers not capable of performing their associated support function(s).

This is appropriate because a limited length of time is allowed for maintenance, testing, or repair of one or more snubbers not capable of performing their associated support function(s) and appropriate compensatory measures are specified in the snubber requirements, which are located outside of the Technical Specifications (TS) under licensee control. LCO 3.0.8 applies to snubbers that only have seismic function.

lt does not apply to snubbers that also have design functions to mitigate steam/water hammer or other transient loads. The snubber requirements do not meet the criteria in 10 CFR 50.36(c)(2)(ii), and, as such, are appropriate for control by the licensee.When applying LCO 3.0.8.a, at least one train of Auxiliary Feedwater (AFW)system must be OPEMBLE during MODES when AFW is required to be OPERABLE.

When applying LCO 3.0.8.a during MODES when AFW is not required to be OPERABLE, a core cooling method (such as Decay Heat Removal(DHR) system) must be available.

When applying LCO 3.0.8.b, a means of core cooling must remain available (AFW, DHR, equipment necessary for feed and bleed operations, etc.). Reliance on availabitity of a core cooling source during modes where AFW is not required by TSs provides an equivalent safety margin for plant operations were LCO 3.0.8 not applied and meets the intent of Technical Specification Task Force Change Traveler TSTF-372, Revision 4, 'Addition of LCO 3.0.8, lnoperability of Snubbers." Revision 133 Amendment 111 Watts Bar-Unit 1 B 3.0-9 LCO Applicability B30 BASES LCO 3.0.8 (continued)

When a snubber is to be rendered incapable of performing its related support function (i.e., nonfunctional) for testing or maintenance or is discovered to not be functional, it must be determined whether any system(s) require the affected snubbe(s) for system OPEMBLILITY, and whether the plant is in a MODE or specified condition in the Applicability that requires the supported system(s) to be OPERABLE.lf an analysis determines that the supported system(s) do not require the snubber(s) to be functional in order to support the OPERABILITY of the system(s), LCO 3.0.8 is not needed. lf the LCO(S) associated with any supported system(s) are not currently applicable (i.e., the plant is not in a MODE or other specified condition in the Applicability of the LCO), LCO 3.0.8 is not needed. lf the supported system(s) are inoperable for reasons other than snubbers, LCO 3.0.8 cannot be used. LCO 3.0.8 is an allowance, not a requirement.

When a snubber is nonfunctional, any supported system(s) may be declared inoperable instead of using LCO 3.0.8.Every time the provisions of LCO 3.0.8 are used, WBN Unit 1 willconfirm that at least one train (or subsystem) of systems supported by the inoperable snubbers will remain capable of performing their required safety or support functions for postulated design loads other than seismic loads. A record of the design function CNL-16-061 Page E-23 of 30 of the inoperable snubber (i.e., seismic vs. non-seismic) and the associated plant configuration willbe available on a recoverable basis for NRC staff inspection.

The provisions of LCO 3.0.8 are not to be applied to supported TS systems unless the supported systems would remain capable of performing their required safety or support functions for postulated design loads other than seismic loads. The risk impact of dynamic loadings other than seismic loads was not assessed as part of the development of LCO 3.0.8. These shocktype loads include thrust loads, blowdown loads, water-hammer loads, steam-hammer loads, LOCA loads and pipe rupture loads.However, there are some important distinctions between non-seismic (shocktype) loads and seismic loads which indicate that, in general, the risk impact of the out-of-service snubbers is smaller for non-seismic loads than for seismic loads. First, while a seismic load affects the entire plant, the impact of a nonseismic load is localized to a certain system or area of the plant. Second, although non-seismic shock loads may be higher in totalforce and the impact could be as much or more than seismic loads, generally they are of much shorter duration than seismic loads. Third, the impact of non-seismic loads is more plant specific, and thus harder to analyze generically, than for seismic loads. For these reasons, every time LCO 3.0.8 is applied, at least one train of each system that is supported by the inoperable snubber(s) should remain capable of performing their required safety or support functions for postulated design loads other than seismic loads.lf the allowed time expires and the snubber(s) are unable to perform their associated support function(s), the affected supported system's LCO(s) must be declared not met and the Conditions and Required Actions entered in accordance with LCO 3.0.2.Revision 133 Amendment 111 Watts Bar-Unit 1 B 3.0-9a LCO Applicability B30 BASES LCO 3.0.8 (continued)

LCO 3.0.8.a applies when one or more snubbers are not capable of providing their associated support function(s) to a single train or subsystem of a multiple train or subsystem supported system or to a single train or subsystem supported system. LCO 3.0.8.a allows 72 hours to restore the snubber(s) before declaring the supported system inoperable.

The72 hour Completion Time is reasonable based on the low probability of a seismic event concurrent with an event that would require operation of the supported system occurring while the snubbe(s)are not capable of performing their associated support function and due to the availability of the redundant train of the supported system.LCO 3.0.8.b applies when one or more snubbers are not capable of providing their associated support function(s) to more than one train or subsystem of a multiple train or subsystem supported system. LCO 3.0.8.b allows 12 hours to restore the snubber(s) before declaring the supported system inoperable.

The 12 hour Completion Time is reasonable based on the low probability of a seismic event concurrent with an event that would require operation of the supported system occurring while the snubbe(s) are not capable of performing their associated support function.LCO 3.0.8 requires that risk be assessed and managed. lndustry and NRC guidance on the implementation of 10 CFR 50.65(aX4) (the Maintenance Rule)does not address seismic risk. However, use of LCO 3.0.8 should be considered with respect to other plant maintenance activities, and integrated into the existing Maintenance Rule process to the extent possible so that maintenance on any unaffected train or subsystem is properly controlled, and emergent issues are properly addressed.

The risk assessment need not be quantified, but may be a qualitative awareness of the vulnerability of systems and components when one or more snubbers are not able to perform their associated support function.Revision 133 Amendment 111 Watts Bar-Unit 1 B 3.0-9b SR Applicability B 3.0 BASES (continued)

SR 3.0.2 SR 3.0.2 establishes the requirements for meeting the specified Frequency for Surveillances and any Required Action with a Completion Time that requires the periodic performance of the Required Action on a "once per . . ." interval.SR 3.0.2 permits a 25o/o extension of the interval specified in the Frequency.

This extension facilitates Surveillance scheduling and considers plant operating conditions that may not be suitable for conducting the Surveillance (e.9., transient conditions or other ongoing Surveillance or maintenance activities).

On a one-time basis the surveillance interval for those surveillances listed in TS Table 3.0.2-1 are allowed to be extended as identified on Table SR 3.0.2-1. The one-time surveillance interval extensions expires on November 30,2017.The 25o/o extension does not significantly degrade the reliability that results from performing the Surveillance at its specified Frequency.

This is based on the recognition that the most probable result of any particular Surveillance being performed is the verification of conformance with the SRs. The exceptions to SR 3.0.2 are those Surveillances for which lhe 25o/o extension of the interval specified in the Frequency does not apply. These exceptions are stated in the individual Specifications.

The requirements of regulations take precedence over the TS. Therefore, when a test interval is specified in the regulations, the test interval cannot be extended by the TS, and the surveillance requirement will include a note in the frequency stating, "SR 3.0.2 does not apply." An example of an exception when the test interval is not specified in the regulations, is the discussion in the Containment Leakage Rate Testing Program, that SR 3.0.2 does not apply. This exception is provided because the program already includes extension of test intervals.

As stated in SR 3.0.2, the 25o/o extension also does not apply to the initial portion of a periodic Completion Time that requires performance on a "once per . . ." basis. The 25% extension applies to each performance after the initial performance.

The initial performance of the Required Action, whether it is a particular Surveillance or some other remedial action, is considered a single action with a single Completion Time. One reason for not allowing lhe 25o/o extension to this Completion Time is that such an action usually verifies that no loss of function has occurred by checking the status of redundant or diverse components or accomplishes the function of the inoperable equipment in an alternative manner.The provisions of SR 3.0.2 are not intended to be used repeatedly merely as an operational convenience to extend Surveillance intervals (other than those consistent with refueling intervals) or periodic Completion Time intervals beyond those specified, with the exception of surveillances required to be performed on a 31-day frequency.

For surveillances performed on a 31-day frequency, the normal surveillance interval may be extended in accordance with Specification 3.0.2 cyclically as required to remain synchronized to the 13-week maintenance work schedules.

This practice is acceptable based on the results of an evaluation of 31-day frequency surveillance test histories that demonstrate that no adverse failure rate changes have occurred nor would be expected to develop as a result of cyclical use of surveillance interval extensions and the fact that the total number of 31-day frequency surveillances performed in any one-year period remains unchanged.(continued)

Revision 10, 114, 137 Amendment 5, 114 Watts Bar-Unit 1 B 3.0-1 1 PAM lnstrumentation B 3.3.3 BASES LCO (continued)

: 23. Refuelino Water Storaoe Tank Level RWST water level is used to verify the water source availability to the ECCS and Containment Spray (CS) Systems. lt alerts the operator to manually switch the CS suction from the RWST to the containment sump. lt may also provide an indication of time for initiating cold leg recirculation from the sump following a LOCA.24. Steam Generator Pressure Steam pressure is used to determine if a high energy secondary line rupture has occurred and the availability of the steam generators as a heat sink. lt is also used to verifu that a faulted steam generator is isolated.

Steam pressure may be used to ensure proper cooldown rates or to provide a diverse indication for natural circulation cooldown.25. Auxiliarv Buildino Passive Sumo Level Auxiliary Building Passive Sump Level, a non-Type A Category 1 variable, monitors the sump level in the auxiliary building.

The two functions of this indication are to monitor for a major breach of the spent fuel pit and to monitor for an RCS breach in the auxiliary building (i.e., an RHR or CVCS line break). The purpose is to verify that radioactive water does not leak to the auxiliary building.

The Auxiliary Building Passive Sump Level monitor consists of two channels on separate power supply.Both channels provide inputs to lCS. The calibrated range of the two I monitors are 12.5" to72.5".(continued)

Revision 135 Watts Bar-Unit 1 B 3 3-134 RWST B 3.5.4 BASES APPLICABLE SAFETY ANALYSES (continued) volume. The deliverable volume limit is set by the LOCA and containment analyses.

For the RWST, the deliverable volume is different from the total volume contained since, due to the design of the tank, more water can be contained than can be delivered.

The minimum boron concentration is an explicit assumption in the main steam line break (MSLB) analysis to ensure the required shutdown capability.

The maximum boron concentration is an explicit assumption in the inadvertent ECCS actuation analysis, although it is typically a nonlimiting event and the results are very insensitive to boron concentrations.

The maximum temperature ensures that the amount of cooling provided from the RWST during the heatup phase of a feedline break is consistent with safety analysis assumptions;the minimum is an assumption in both the MSLB and inadvertent ECCS actuation analyses, although the inadvertent ECCS actuation event is typically nonlimiting.

The MSLB analysis has considered a delay associated with the interlock between the VCT and RWST isolation valves, and the results show that the departure from nucleate boiling design basis is met. The delay has been established as 27 seconds, with offsite power available, or 37 seconds without offsite power.For a large break LOCA Analysis, the minimum water volume limit of 370,000 gallons and the minimum boron concentration limit is used to compute the post LOCA sump boron concentration necessary to assure subcriticality.(continued)

Revision 13, 61 , 88, 98 , 131 Amendment 7 , 40, 48, 67 ,77 , 1A7 Watts Bar-Unit 1 B 3 5-26 RWST B3.54 BASES APPLICABLE SAFETY ANALYSES (continued)

The large break LOCA is the limiting case since the safety analysis assumes least negative reactivity insertion.

The upper limit on boron concentration of 3300 ppm is used to determine the maximum allowable time to switch to hot leg recirculation following a LOCA. The purpose of switching from cold leg to hot leg injection is to avoid boron precipitation in the core following the accident.ln the ECCS analysis, the containment spray temperature is assumed to be equal to the RWST lower temperature limit of 60"F. lf the lower temperature limit is violated, the containment spray further reduces containment pressure, which decreases the rate at which steam can be vented out the break and increases peak clad temperature.

The acceptable temperature range of 60'F to 105'F is assumed in the large break LOCA analysis, and the small break analysis value bounds the upper temperature limit of 105'F. The upper temperature limit of 105'F is also used in the containment OPEMBILITY analysis.

Exceeding the upper temperature limit will result in a higher peak clad temperature, because there is less heat transfer from the core to the injected water following a LOCA and higher containment pressures due to reduced containment spray cooling capacity.

For the containment response following an MSLB, the lower limit on boron concentration and the upper limit on RWST water temperature are used to maximize the total energy release to containment.

LCO The RWST ensures that an adequate supply of borated water is available to cool and depressurize the containment in the event of a Design Basis Accident (DBA), to cool and cover the core in the event of a LOCA, to maintain the reactor subcritical following a DBA, and to ensure adequate level in the containment sump to support ECCS and Containment Spray System pump operation in the recirculation mode.To be considered OPERABLE, the RWST must meet the water volume, boron concentration, and temperature limits established in the SRs.(continued)

Revision 13, 61 , 131 Amendment 7, 40, 48, 107 Watts Bar-Unit 1 B 3.5-27 Containment B 3.6.1 BASES APPLICABLE Satisfactory leakage rate test results are a requirement for SAFETY ANALYSES the establishment of containment OPERABILIry.(continued)

LCO Containment OPEMBILITY is maintained by limiting leakage to < 1.0 L", except prior to the first start up after performing a required Containment Leakage Rate Testing Program leakage test. At this time, applicable leakage limits must be met.Compliance with this LCO will ensure a containment configuration, including equipment hatches, that is structurally sound and that will limit leakage to those leakage rates assumed in the safety analysis.lndividual leakage rates specified for the containment air lock (LCO 3.6.2), purge valves with resilient seals, and Shield Building containment bypass leakage (LCO 3.6.3) are not specifically part of the acceptance criteria of '10 CFR 50, Appendix J, Option B. Therefore, leakage rates exceeding these individual limits only result in the containment being inoperable when the leakage results in exceeding the acceptance criteria of Appendix J, Option B.APPLICABILITY ln MODES 1, 2, 3, and 4, a DBA could cause a release of radioactive material into containment.

ln MODES 5 and 6, the probability and consequences of these events are reduced due to the pressure and temperature limitations of these MODES. Therefore, containment is not required to be OPERABLE in MODES 5 and 6 to prevent leakage of radioactive material from containment.(continued)

Revision 10, 130 Amendment 5 Watts Bar-Unit 1 B 3.6-3 Containment Air Locks B3.62 BASES (continued)

APPLICABILITY ln MODES 1,2, 3, and 4, a DBA could cause a release of radioactive material to containment.

ln MODES 5 and 6, the probability and consequences of these events are reduced due to the pressure and temperature limitations of these MODES. Therefore, the containment air locks are not required in MODES 5 and 6 to prevent leakage of radioactive materialfrom containment.

ACTIONS The ACTIONS are modified by a Note that allows entry and exit to perform repairs on the affected air lock component.

lf the outer door is inoperable, then it may be easily accessed for most repairs. lt is preferred that the air lock be accessed from inside containment by entering through the other OPEMBLE air lock. However, if this is not practicable, or if repairs on either door must be performed from the barrel side of the door then it is permissible to enter the air lock through the OPERABLE door which means there is a short time during which the containment boundary is not intact (during access through the OPERABLE door). The ability to open the OPERABLE door, even if it means the containment boundary is temporarily not intact, is acceptable due to the low probability of an event that could pressurize the containment during the short time in which the OPERABLE door is expected to be open. After each entry and exit, the OPERABLE door must be immediately closed.A second Note has been added to provide clarification that, for this LCO, separate Condition entry is allowed for each air lock. This is acceptable, since the Required Actions for each Condition provide appropriate compensatory actions for each inoperable air lock. Complying with the Required Actions may allow for continued operation, and a subsequent inoperable air lock is governed by subsequent Condition entry and application of associated Required Actions.ln the event the air lock leakage results in exceeding the overall containment leakage rate, Note 3 directs entry into the applicable Conditions and Required Actions of LCO 3.6.1, "Containment." (continued)

Watts Bar-Unit 1 B 3.6-8 Revision 130 Containment lsolation Valves B 3.6.3 BASES LCO (continued) times in the FSAR (Ref. 2).The normally closed containment isolation valves are considered OPERABLE when manual valves are closed, automatic valves are de-activated and secured in their closed position, blind flanges are in place, and closed systems are intact. These passive isolation valves/devices are those listed in Reference 2.Purge valves with resilient seals and shield building bypass valves meet additional leakage rate requirements.

The other containment isolation valve leakage rates are addressed by LCO 3.6.1, "Containment," as Type C testing.This LCO provides assurance that the containment isolation valves will perform their designed safety functions to minimize the loss of reactor coolant inventory and establish the containment boundary during accidents.

APPLICABILITY ln MODES 1,2,3, and 4, a DBA could cause a release of radioactive material to containment.

ln MODES 5 and 6, the probability and consequences of these events are reduced due to the pressure and temperature limitations of these MODES. Therefore, the containment isolation valves are not required to be OPERABLE in MODES 5 and 6.ACTIONS The ACTIONS are modified by a Note allowing penetration flow paths, to be unisolated intermittently under administrative controls.

These administrative controls consist of stationing a dedicated operator (licensed or unlicensed) at the valve controls, who is in continuous communication with the control room. ln this way, the penetration can be rapidly isolated when a need for containment isolation is indicated.

For valve controls located in the control room, an operator (other than the Shift Operations Supervisor (SOS), ASOS, or the Operator at the Controls) may monitor containment isolation signal status rather than be stationed at the valve controls.

Other secondary responsibilities which do not prevent adequate monitoring of containment isolation signal status may be performed by the operator provided his/her primary responsibility is rapid isolation of the penetration when needed for containment isolation.

Use of the Unit Control Room Operator (CRO) to perform this function should be limited to those situations where no other operator is available.

A second Note has been added to provide clarification that, for this LCO, separate Condition entry is allowed for each penetration flow path. This is acceptable, since the Required Actions for each Condition provide appropriate (continued)

Watts Bar-Unit 1 B 3.6-17 Revision 130 Containment Pressure B 3.6.4 B 3 6 CONTAINMENT SYSTEMS B 3.6.4 Containment Pressure BASES BACKGROUND The containment pressure is limited during normal operation to preserve the initial conditions assumed in the accident analyses for a loss of coolant accident (LOCA) or steam line break (SLB). These limits also prevent the containment pressure from exceeding the containment design negative pressure differential

(-2.0 psid) with respect to the Shield Building annulus atmosphere in the event of inadvertent actuation of the Containment Spray System or Air Return Fans.Containment pressure is a process variable that is monitored and controlled.

The containment pressure limits are derived from the input conditions used in the containment functional analyses and the containment structure external pressure analysis.

Should operation occur outside these limits coincident with a Design Basis Accident (DBA), post accident containment pressures could exceed calculated values.APPLICABLE SAFEry ANALYSES Containment internal pressure is an initialcondition used in the DBA analyses to establish the maximum peak containment internal pressure.

The limiting DBAs considered, relative to containment pressure, are the LOCA and SLB, which are analyzed using computer pressure transients.

The worst case LOCA generates larger mass and energy release than the worst case SLB.Thus, the LOCA event bounds the SLB event from the containment peak pressure standpoint (Ref. 1).The initial pressure condition used in the containment analysis was 15.0 psia.This resulted in a maximum peak pressure from a LOCA of 9.36 psig. The containment analysis (Ref. 1) shows that the maximum allowable internal containment pressure, P" (15.0 psig), bounds the calculated results from the limiting LOCA. The maximum containment pressure resulting from the worst case LOCA, does not exceed the containment design pressure, 13.5 psig.(continued)

Revision 44, 55 ,76, 127 Amendment 33 Watts Bar-Unit 1 B 3.6-28 Containment Spray System B3.66 BASES BACKGROUND (continued)

The operation of the ice condenser, is adequate to assure pressure suppression during the initial blowdown of steam and water from a DBA. During the post blowdown period, the Air Return System (ARS) is automatically started. The ARS returns upper compartment air through the divider barrier to the lower compartment.

This seryes to equalize pressures in containment and to continue circulating heated air and steam through the ice condenser, where heat is removed by the remaining ice and by the Containment Spray System after the ice has melted.The Containment Spray System limits the temperature and pressure that could be expected following a DBA. Protection of containment integrity limits leakage of fission product radioactivity from containment to the environment.

APPLICABLE SAFETY ANALYSES The limiting DBAs considered relative to containment OPERABILITY are the loss of coolant accident (LOCA) and the steam line break (SLB). The DBA LOCA and SLB are analyzed using computer codes designed to predict the resultant containment pressure and temperature transients.

No two DBAs are assumed to occur simultaneously or consecutively.

The postulated DBAs are analyzed, in regard to containment ESF systems, assuming the loss of one ESF bus, which is the worst case single active failure, resulting in one train of the Containment Spray System, the RHR System, and the ARS being rendered inoperable (Ref. 2).The DBA analyses show that the maximum peak containment pressure of 9.36 psig results from the LOCA analysis, and is calculated to be less than the containment design pressure.

Revision 44, 55, 76, 127 Amendment 33 Watts Bar-Unit 1 B 3.6-37 HMS B 3.6.8 BASES BACKGROUND (continued)

When the HMS is initiated, the ignitor elements are energized and heat up to a surface temperature  

> 't700"F. At this temperature, they ignite the hydrogen gas that is present in the airspace in the vicinity of the ignitor. The HMS depends on the dispersed location of the ignitors so that local pockets of hydrogen at increased concentrations would burn before reaching a hydrogen concentration significantly higher than the lower flammability limit. Hydrogen ignition in the vicinity of the ignitors is assumed to occur when the local hydrogen concentration reaches a minimum 5.0 volume percent (v/o).APPLICABLE SAFETY ANALYSES The HMS causes hydrogen in containment to burn in a controlled manner as it accumulates following a degraded core accident (Ref. 3). Burning occurs at the lower flammability concentration, where the resulting temperatures and pressures are relatively benign. Without the system, hydrogen could build up to higher concentrations that could result in a violent reaction if ignited by a random ignition source after such a buildup.The hydrogen ignitors have been shown by probabilistic risk analysis to be a significant contributor to limiting the severity of accident sequences that are commonly found to dominate risk for plants with ice condenser containments.

As such, the hydrogen ignitors are considered to be risk significant in accordance with the NRC Policy Statement.

LCO Two HMS trains must be OPERABLE with power from two independent, safety related power supplies.

For this plant, an OPERABLE HMS train consists of 33 of 34 ignitors energized on the train.(continued)

Watts Bar-Unit 1 B 3.6-50 Revision 128 Shield Building B 3.6.1 5 B 3.6 CONTAINMENT SYSTEMS B 3.6.15 Shield Building BASES BACKGROUND The shield building is a concrete structure that surrounds the steel containment vessel. Between the containment vessel and the shield building inner wall is an annular space that collects containment leakage that may occur following a loss of coolant accident (LOCA) as well as other design basis accidents (DBAs) that release radioactive material.

This space also allows for periodic inspection of the outer surface of the steel containment vessel.During normal operations when containment integrity is required, annulus vacuum is established and maintained by the annulus vacuum control subsystem.

ln emergencies, in which containment isolation is required, this subsystem is isolated and shut down because it performs no safety-related function (Ref.4).The nominal negative pressure for the annulus vacuum control equipment is 5-inches of water gauge. This negative pressure level, chosen for normal operation, ensures that the annulus pressure will not reach positive values during the annulus pressure surge produced by a LOCA in the primary containment.

The annulus vacuum control subsystem also aids in containment pressure relief by exhausting to the auxiliary building exhaust stack the containment vent air that goes through the containment vent air clean up units and is discharged into the annulus.During an emergency, the Emergency Gas Treatment System (EGTS)establishes a negative pressure in the annulus between the shield building and the steel containment vessel. Filters in the system then controlthe release of radioactive contaminants to the environment.

The shield building is required to be OPEMBLE to ensure retention of containment leakage and proper operation of the EGTS.Several normal plant evolutions can cause the annulus pressure to exceed its limits briefly; containment venting, both the normal or alternate method, testing of the EGTS, annulus entries, and auxiliary building isolations.

These activities cause an inrush of air into the annulus, lowering in the annulus vacuum until the annulus vacuum control fans can return annulus vacuum to within limits.The containment vent system is a non-safety related system, which provides continuous pressure relief during normal operation, by allowing containment air outflow through the 8-inch containment penetration through two 100% redundant air cleanup units (ACUs), containing HEPA/charcoalfilters, into the annulus with the motive force being the pressure differential between the containment and the annulus. Depending on the inflow into the annulus when containment vent is initiated, annulus pressure may not be within limits untilthe annulus vacuum (continued)

Revision 129 Watts Bar-Unit 1 B 3.6-95 Shield Building B 3.6.15 BASES BACKGROUND (continued) control system can recover the annulus vacuum.An alternate containment pressure relief function (containment vent) is provided by way of a configuration alignment in the reactor building purge ventilating system. This function is accomplished by opening lower compartment purge lines (one supply and one exhaust) or one of the two pairs of lines (one supply and one exhaust) in the upper compartment.

To prevent inadvertent pressurization of containment due to supply and exhaust side ductwork flow imbalances, the supply ductwork airflow may be temporarily throttled as needed (Ref.5).During resting of the EGTS, alignment of the system to the annulus for the test causes an inrush of air from the EGTS ducting increasing annulus pressure.

This inrush of air can cause annulus pressure to exceed the annulus pressure limit untilthe EGTS fan is started, stopping the inrush allowing the annulus vacuum control fan to restore annulus pressure to within limits.APPLICABLE SAFETY ANALYSES The design basis for shield building OPERABILITY is a LOCA.Maintaining shield building OPERABILITY ensures that the release of radioactive materialfrom the containment atmosphere is restricted to those leakage paths and associated leakage rates assumed in the accident analyses.The shield building satisfies Criterion 3 of the NRC Policy Statement.

LCO Shield building OPERABILITY must be maintained to ensure proper operation of the EGTS and to limit radioactive leakage from the containment to those paths and leakage rates assumed in the accident analyses.APPLICABILITY Maintaining shield building OPEMBILITY prevents leakage of radioactive material from the shield building.

Radioactive material may enter the shield building from the containment following a DBA. Therefore, shield building OPERABILIW is required in MODES 1,2,3, and 4 when DBAs could release radioactive material to the containment atmosphere.

ln MODES 5 and 6, the probability and consequences of these events are low due to the Reactor Coolant System temperature and pressure limitations in these MODES. Therefore, shield building OPERABILITY is not required in MODE 5 or 6.(continued)

Watts Bar-Unit 1 B 3.6-96 Revision 129 Shield Building B 3.6.15 BASES ACTIONS Note: The highlighted text on this page and the following page was incorporated as part of Amendment

: 59. This amendment also added a series of notes to Technical Specification 3.6.15. As stated in NRC's Safety Evaluation for Amendment 59 (NRC's letter dated January 6, 2006), these controls were only applicable until WBN Unit 1 entered Mode 5 at the start of the Cycle 7 refueling outage. The highlighted text in this Bases section and the notes in Technical Specification 3.6.15 will be deleted via a future amendment to the Tech n ica I Specifications.

4.1 ln the event shield building OPERABILITY is not maintained, shield building OPEMBILITY must be restored within 24 hours. Twenty-four hours is a reasonable Completion Time considering the limited leakage design of containment and the low probability of a Design Basis Accident occurring during this time period.8.1 The Completion Time of 8 hours is based on engineering judgment.

The normal alignment for both EGTS control loops is the A-Auto position.

With both EGTS control loops in A-Auto, both trains will function upon initiation of a Containment lsolation Phase A (ClA) signal. ln the event of a LOCA, the annulus vacuum control system isolates and both trains of the EGTS p.essure control loops will be placed in service to maintain the required negative pressure.

lf annulus vacuum is lost during normal operations, the A-Auto position is unaffected by the loss of vacuum. This operational configuration is acceptable because the accident dose analysis conservatively assumes the annulus is at atmospheric pressure at event initiation. (Ref. 3)A Note has been provided which makes the requirement to maintain the annulus pressure within limits not applicable for a maximum of t hour during: Ventilating operations, Required annulus entries, or Auxiliary Building isolations.

Ventilating operations include containment venting, the Reactor Building Purge Ventilating System alternate containment pressure relief function, and testing of the Emergency Gas Treatment system. ln addition to Note makes the requirement to maintaintheannulusDressurewithinlimitsnotapplicabteffif;fi (continued)

Watts Bar-Unit 1 B 3.6-97 Revision 15 ,29, 101 , 129 Shield Building B 3 6 15 BASES ACTIONS B.1 (continued)

C.1 and C.2 lf the shield building cannot be restored to OPEMBLE status within the required Completion Time, the plant must be brought to a MODE in which the LCO does not apply. To achieve this status, the plant must be brought to at least MODE 3 within 6 hours and to MODE 5 within 36 hours. The allowed Completion Times are reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems.SURVEILLANCE REQUIREMENTS sR 3.6.15.1 Verifying that shield building annulus negative pressure is within limit (equal to or more negative than - 5 inches water gauge, value does not account for instrument error, Ref. 2) ensures that operation remains within the limit assumed in the containment analysis.

The 12 hour Frequency of this SR was developed considering operating experience related to shield building annulus pressure variations and pressure instrument drift during the applicable MODES.sR 3.6.15.2 Maintaining shield building OPERABILITY requires maintaining each door in the access opening closed, except when the access opening is being used for normal transient entry and exit. The 31 day Frequency of this SR is based on engineering judgment and is considered adequate in view of the other indications Watts Bar-Unit 1 B 3.6-98 Revision 15 , 29, 101 , 129 Shield Building B 3.6.1 5 BASES of door status that are available to the operator.SURVEILLANCE SR 3.6.15.3 REQUIREMENTS (continued)

This SR would give advance indication of gross deterioration of the concrete structural integrity of the shield building.

The Frequency of this SR is the same as that of SR 3.6.1.1. The verification is done during shutdown.sR 3.6.15.4 The EGTS is required to maintain a pressure equal to or more negative than-0.50 inches of water gauge ("wg) in the annulus at an elevation equivalent to the top of the Auxiliary Building.

At elevations higher than the Auxiliary Building, the EGTS is required to maintain a pressure equalto or more negative than -0.25"wg. The low pressure sense line for the pressure controller is located in the annulus at elevation 783. By verifying that the annulus pressure is equal to or more negative than -0.61 "wg at elevation 783, the annulus pressurization requirements stated above are met. The ability of a EGTS train with final flow >3600 and s 4400 cfm to produce the required negative pressure during the test operation provides assurance that the building is adequately sealed. The negative pressure prevents leakage from the building, since outside air will be drawn in by the low pressure at a maximum rate < 250 cfm. The 18 month Frequency on a STAGGERED TEST BASIS is consistent with Regulatory Guide 1.52 (Ref. 1) guidance for functional testing.REFERENCES  

: 1. Regulatory Guide 1.52, Revision 2, "Design, Testing and Maintenance C riteria for Post Accident Engineered-Safety-Featu re Atmospheric Cleanup System Air Filtration and Adsorption Units of Light-Water Cooled Nuclear Power Plants." 2. Watts Bar Drawing 147W605-242, "ElectricalTech Spec Compliance Tables." 3. DCN 52216-A, "Elimination of A-AUTO STANDBY Hand Switch Position for EGTS Pressure Control Loops." 4. WBN UFSAR Section 6.2.3.2.2, "Emergency Gas Treatment System (EGrS).', 5. WBN UFSAR Section 9.4.6, "Reactor Building Purge Ventilating System (RBPVS).', Watts Bar-Unit 1 B 3.6-99 Revision 15, 29, 101 , 129 CCS B 3.7.7 B 3.7 PLANT SYSTEMS B 3.7.7 Component Cooling System (CCS)BASES BACKGROUND The CCS provides a heat sink for the removal of process and operating heat from safety related components during a Design Basis Accident (DBA) or transient.

During normal operation, the CCS also provides this function for various nonessential components, as well as the spent fuel storage pool. The CCS serves as a barrier to the release of radioactive byproducts between potentially radioactive systems and the Essential Raw Cooling Water (ERCW) System, and thus to the environment.

The CCS is arranged as two independent, full-capacity cooling trains, Train A and B. Train A in unit 1 is served by CCS Hx A and CCS pump 1A-A. Pump 1B-B, which is actually Train B equipment, is also normally aligned to the Train A header in unit 1. However, pump 1B-B can be realigned to Train B on loss of Train A.Train B is served by CCS Hx C. Normally, only CCS pump C-S is aligned to the Train B header since few nonessential, normally-operating loads are assigned to Train B. However, pump 1B-B can be realigned to the Train B header on a loss of the C-S pump.ln addition, CCS Pump 2B-B may be substituted for CCS Pump C-S supplying the CCS Train B header provided the OPERABILITY requirements for the pump are met and the pump is in operation.

CCS Pump 2B-B only receives a safety injection (Sl) actuation signal from Unit 2. The presence of a Unit 1 Sl signal will have no effect on CCS Pump 2B-B. lf CCS Pump 2B-B is aligned as a substitute for CCS Pump C-S, then Unit 1 CCS Train B would not be OPERABLE because CCS pump 2B-B does not start if a Unit 1 Sl signal is generated.

However, if CCS Pump 2B-B pump is in operation, and an Sl Signal is generated, it will continue to operate. ln the event of a loss of offsite power, with or without an Sl signal present, CCS pump 2B-B will be automatically sequenced onto its respective diesel and continue to perform its required safety function.Each safety related train is powered from a separate bus. An open surge tank in the system provides pump trip protective functions to ensure that sufficient net positive suction head is available.

lt is preferred that the 1B and 28 surge tank sections be aligned o the associated operable CCS pump(s); however, aligning a single 1B or 28 surge tank section provides an operable surge tank for the associated pump(s).The pump in each train is automatically started on receipt of a Sl signal, and all nonessential components will be manually isolated.(continued)

Revision 136 Amendment 113 Watts Bar-Unit 1 B 3.7-38 CCS B 3.7.7 BASES LCO (continued)

CCS Train B is also considered OPEMBLE when: a. Pump 2B-B and associated surge tank are OPEMBLE; and b. Pump 2B-B is in operation; and c. The associated piping, valves, heat exchanger, and instrumentation and controls required to perform the safety related function are OPERABLE.The isolation of CCS from other components or systems not required for safety may render those components or systems inoperable but does not affect the OPERABILITY of the CCS.APPLICABILITY ln MODES 1,2,3, and 4, the CCS is a normally operating system, which must be prepared to perform its post accident safety functions, primarily RCS heat removal, which is achieved by cooling the RHR heat exchanger.

ln MODE 5 or 6, the OPERABILITY requirements of the CCS are determined by the systems it supports.ACTIONS A.1 Required Action A.1 is modified by a Note indicating that the applicable Conditions and Required Actions of LCO 3.4.6, "RCS Loops-MODE 4," be entered if an inoperable CCS train results in an inoperable RHR loop. This is an exception to LCO 3.0.6 and ensures the proper actions are taken for these components.

lf one CCS train is inoperable, action must be taken to restore OPEMBLE status within 72 hours. ln this Condition, the remaining OPERABLE CCS train is adequate to perform the heat removalfunction.

The72 hour Completion Time is reasonable, based on the redundant capabilities afforded by the OPEMBLE train, and the low probability of a DBA occurring during this period.B.1 and B.2 lf the CCS train cannot be restored to OPERABLE status within the associated Completion Time, the plant must be placed in a MODE in which the LCO does not apply. To achieve this status, the plant must be placed in at least MODE 3 within 6 hours and in MODE 5 within 36 hours. The allowed Completion Times are reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems.(continued)

Revision 136 Amendment 113 Watts Bar-Unit 1 B 3.740 CCS B 3.7.7 BASES SURVEILLANCE REQUIREMENTS sR 3.7.7.1 This SR verifies that the C-S pump is powered from the normal power source when it is aligned for OPERABLE status. Verification of the correct power alignment ensures that the two CCS trains remain independent.

The 7-day Frequency is based on engineering judgment, is consistent with procedural controls governing breaker operation, and ensures correct breaker position.sR 3.7.7.2 This SR is modified by a Note indicating that the isolation of the CCS flow to individual components may render those components inoperable but does not affect the OPERABILITY of the CCS.Verifying the correct alignment for manual, power operated, and automatic valves in the CCS flow path provides assurance that the proper flow paths exist for CCS operation.

This SR does not apply to valves that are locked, sealed, or otherwise secured in position, since these valves are verified to be in the correct position prior to locking, sealing, or securing.

This SR also does not apply to valves that cannot be inadvertently misaligned, such as check valves. This Surveillance does not require any testing or valve manipulation; rather, it involves verification that those valves capable of being mispositioned are in the correct position.The 31 day Frequency is based on engineering judgment, is consistent with the procedural controls governing valve operation, and ensures correct valve positions.

sR 3.7.7.3 This SR verifies proper automatic operation of the CCS valves on an actual or simulated actuation signal. The CCS is a normally operating system that cannot be fully actuated as part of routine testing during normal operation.

This Surveillance is not required for valves that are locked, sealed, or otherwise secured in the required position under administrative control. The 18 month Frequency is based on the need to perform this Surveillance under the conditions that apply during a unit outage and the potential for an unplanned transient if the Surveillance were performed with the reactor at power. Operating experience has shown that these components usually pass the Surveillance when performed at the 18 month Frequency.

Therefore, the Frequency is acceptable from a reliability standpoint.

sR 3.7.7.4 This SR verifies proper automatic operation of the CCS pumps on an actual or simulated actuation signal. The CCS is a normally operating system that cannot be fully actuated as part of routine testing during normal operation.

The 18 month Frequency is based on the need to perform this Surveillance under the conditions that apply during a unit outage and the potential for an unplanned transient if the Surveillance were performed with the reactor at power. Operating experience has shown that these components usually pass the Surveillance when performed Revision 136 Amendment 113 Watts Bar-Unit 1 B 3.741 CCS B 3.7.7 BASES SURVEILLANCE SR 3.7.7.4 (continued)

Therefore, the Frequency is acceptable from reliability standpoint.

The SR is modified by a Note that eliminates the requirement to verify CCS pump 2B-B starts automatically on an actual or simulated Unit 1 Sl actuation signal.Because CCS pump 2B-B is supporting Unit 1 operation and the pump does not receive a Unit 1 Sl actuation signal, ensuring CSS pump 2B-B is in operation ensures the pump will continue to operate if a condition requiring a Unit 1 Sl actuation signal exists. lf a LOOP occurs, the SR continues to require verification of an automatic start on a simulated or actual loss of offsite power actuation signal.sR 3.7.7.5 This SR assures the operability of Unit 1 CCS Train B when CCS Pump 2B-B is substituted for CCS Pump C-S. Because CCS Pump 2B-B does not receive a Sl actuation signal from Unit 1, by verifying the pump is aligned and in operation, assurance is provided that Unit 2 CCS Train B will be operable in the event of a Unit 2 Sl actuation with a loss of CCS Train A.This SR is modified by a Note that states the alignment and operating verification requirement is only required to be met when CCS pump 2B-B is being used to support the OPERABILITY of CCS Train B. When CCS pump 2B-B is not supporting the OPERABILITY of CCS Train B the other SRs provide the necessary and appropriate verifications of the CCS Train OPERABILITY.

The Frequency of 12 hours is sufficient considering other indications and alarms avaihbb to the operator in the control room to monitor CCS performance.

: 1. Watts Bar FSAR, Section 9.2.2, "Component Cooling System." 2. Watts Bar Component Cooling System Description, N3-70-4002.

Revision 136 Amendment 1 13 Watts Bar-Unit 1 B 3.742 CREATCS B 3.7.11 BASES ACT!ONS (continued)

A.1 DELETED (continued)

Revision 64, 107, 134 Amendment 50, 85, 112 Watts Bar-Unit 1 B 3.7-59a AC Sources - Operating B381 BASES BACKGROUND A single offsite circuit is capable of providing the ESF loads. Two of these (continued) circuits are required to meet the Limiting Condition for Operation.

These same DGs will be shared for Unit 2 operation.

A DG starts automatically on a safety injection (Sl) signal I (i.e., low pressurizer pressure or high containment pressure signals) or on an 6.9 kV shutdown board degraded voltage or loss-of-voltage signal (refer to LCO 3.3.5, "Loss of Power (LOP) DieselGenerator (DG) Start lnstrumentation").

After the DG has started, it will automatically tie to its respective 6.9 kV shutdown board after offsite power is tripped as a consequence of 6.9 kV shutdown board loss-of-voltage or degraded voltage, independent of or coincident with an Sl signal. The DGs will also start and operate in the standby mode without tying to the 6.9 kV shutdown board on an Sl signal alone. Following the trip of offsite power, a loss-of-voltage signal strips all nonpermanent loads from the 6.9 kV shutdown board. When the DG is tied to the 6.9 kV shutdown board, loads are then sequentially connected to its respective 6.9 kV shutdown board by the automatic sequencer.

The sequencing logic controls the permissive and starting signals to motor breakers to prevent overloading the DG by automatic load application.

ln the event of a loss of preferred power, the 6.9 kV shutdown boards are automatically connected to the DGs in sufficient time to provide for safe reactor shutdown and to mitigate the consequences of a Design Basis Accident (DBA)such as a LOCA.Certain required plant loads are returned to service in a predetermined sequence in order to prevent overloading the DG in the process. Within the required interval (FSAR Table 8.3-3) after the initiating signal is received, all automatic and permanently connected loads needed to recover the plant or maintain it in a safe condition are returned to service.Ratings for Train 1A, 18, 2A and 28 DGs satisfy the requirements of Regulatory Guide 1.9 (Ref. 3). The continuous service rating of each DG is 21400 kW with 10olo overload permissible for up to 2 hours in any 24 hour period. The ESF loads that are powered from the 6.9 kV shutdown boards are listed in Reference 2.The capability is provided to connect a 6.9 kV FLEXS DG to supply power to any of the four 6.9 kV shutdown boards. The 6.9 kV FLEX DG is commercial-grade and not designed to meet Class 1E requirements.

The FLEX DG is made available to support extended Completion Times in the event of an inoperable DG. The FLEX DG is made available as a defense-in-depth alternate source of AC power to mitigate a loss of offsite power event. The FLEX DG would remain disconnected rom the Class 1E distribution system unless required during a loss of offsite power.(continued)

Revision 125,132 Amendment 84, 103, 1 10 Watts Bar-Unit 1 B 3.8-2 AC Sources - Operating B 3.8.1 BASES (continued)

APPLICABLE The initial conditions of DBA and transient analyses in the SAFEry ANALYSES FSAR, Section 6 (Ref. 4) and Section 15 (Ref. 5), assume ESF systems are OPERABLE.

The AC electrical power sources are designed to provide sufficient capacity, capability, redundancy, and reliability to ensure the availability of necessary power to ESF systems so that the fuel, Reactor Coolant System (RCS), and containment design limits are not exceeded.

These limits are discussed in more detail in the Bases for Section 3.2, Power Distribution Limits;Section 3.4, Reactor Goolant System (RCS); and Section 3.6, Containment Systems.The OPEMBILITY of the AC electrical power sources is consistent with the initial assumptions of the Accident analyses and is based upon meeting the design basis of the plant. This results in maintaining at least two DG's associated with one load group or one offsite circuit OPERABLE during Accident conditions in the event of: a. An assumed loss of all offsite power or all onsite AC power; and b. A worst case single failure.The AC sources satisfy Criterion 3 of 10 CFR 50.36(c)(2xii).

LCO Two qualified circuits between the Watts Bar Hydro 161 kV switchyard and the onsite Class 1E Electrical Power System and separate and independent DGs for each train ensure availability of the required power to shut down the reactor and maintain it in a safe shutdown condition after an anticipated operational occurrence (AOO) or a postulated DBA.Qualified offsite circuits are those that are described in the FSAR and are part of the licensing basis for the plant.Each offsite circuit must be capable of maintaining acceptable frequency and voltage, and accepting required loads during an accident, while connected to the 6.9 kV shutdoup boards.Offsite power from the Watts Bar Hydro 161 kV switchyard to the onsite Class 1E distribution system is from two independent immediate access circuits.

Each of the two required circuits are routed from the switchyard through a 161 kV transmission line and one of four 161 to 6.9 kV transformers (common station service transformers (CSSTs)) to the onsite Class '1E distribution system.Normally the two required circuits are aligned to power the 6.9 kV shutdown boards through CSST C and CSST D. However, one of the two required circuits may also be aligned to power two shutdown boards in the same load group through either CSST A or CSST B and its associated Unit Boards, either directly from the CSST through the Unit Board or by automatic transfer from the Unit Station Service Transformer (USST) to the CSST. Use of CSST A or B as an (continued)

Revision 125, 132 Amendment 103, 1 10 Watts Bar-Unit 1 B38-3 AC Sources - Operating B 3.8.1 BASES ACTIONS (continued)

A.3 According to Regulatory Guide 1.93 (Ref. 6), operation may continue in Condition A for a period that should not exceed 72 hours. With one required offsite circuit inoperable, the reliability of the offsite system is degraded, and the potential for a loss of offsite power is increased, with attendant potential for a challenge to the plant safety systems. ln this Condition, however, the remaining OPERABLE offsite circuit and DGs are adequate to supply electrical power to the onsite Class 1E Distribution System.The72 hour Completion Time takes into account the capacity and capability of the remaining AC sources, a reasonable time for repairs, and the low probability of a DBA occurring during this period.The second Completion Time for Required Action A.3 establishes a limit on the maximum time allowed for any combination of required AC power sources to be inoperable during any single contiguous occurrence of failing to meet the LCO. lf Condition A is entered while, for instance, a DG is inoperable and that DG is subsequently returned OPERABLE, the LCO may already have been not met for up to 10 days. This could lead to a total of 13 days, since initial failure to meet the LCO, to restore the offsite circuit. At this time, a DG could again become inoperable, the circuit restored OPEMBLE, and an additional 10 days (for a total of 23 days) allowed prior to complete restoration of the LCO. The 13 day Completion Time provides a limit on the time allowed in a specified condition after discovery of failure to meet the LCO. This limit is considered reasonable for situations in which Conditions A and B are entered concurrently.

The'AND" connector between the 72 hour and 13 day Completion Times means that both Completion Times apply simultaneously, and the more restrictive Completion Time must be met.As in Required Action A.2, the Completion Time allows for an exception to the normal "time zero" for beginning the allowed outage time "clock.' This will result in establishing the'timE zero" althe time that the LCO was initially not met, instead of at the time Condition A was entered.(continued)

Revision 125, 132 Amendment 103, 1 10 Watts Bar-Unit 1 B 3.8-7 AC Sources - Operating B 3.8.1 BASES ACTIONS B.1 and C.1 (continued)

To ensure a highly reliable power source remains with one or more DGs inoperable in Train A OR with one or more DGs inoperable in Train B, it is necessary to verify the availability of the required offsite circuits on a more frequent basis. Since the Required Action only specifies "perform," a failure of SR 3.8.1.1 acceptance criteria does not result in a Required Action being not met.However, if a circuit fails to pass SR 3.8.1.1, it is inoperable.

Upon required offsite circuit inoperability, additional Conditions and Required Actions must then be entered.8.2 ln order to extend the Required Action B.5 Completion Time for an inoperable DG lrom 72 hours to 1 0 days, it is necessary to evaluate the availability of the 6.9 kV FLEX DG within 2 hours upon entry into LCO 3.8.1 and every 12 hours thereafter.

Since Required Action B.2 only specifies "evaluate," discovering the 6.9 kV FLEX DG unavailable does not result in the Required Action being not met (i.e., the evaluation is performed).

However, on discovery of an unavailable 6.9 kV FLEX DG, the Completion Time for Required Action B.5 starts lhe72 hour and/or 24 hour clock.6.9 kV FLEX DG availability requires that: 1) 6.9 kV FLEX DG fuel tank level is verified locally to be ) 8-hour supply; and 2) 6.9 kV FLEX DG supporting system parameters for starting and operating are verified to be within required limits for functional availability (e.9., batter state of charge).The 6.9 kV FLEX DG is not used to extend the Completion Time for more than one inoperable DG at any one time.8.3 and C.2 Required Actions 8.3 and C.2 are intended to provide assurance that a loss of offsite power, during the period that a DG is inoperable, does not result in a complete loss of safety function of critical systems. These features are designed with redundant safety related trains. This includes motor driven auxiliary feedwater pumps. Single train systems, such as the turbine driven auxiliary feedwater pump, are not included.

Redundant required feature failures consist of inoperable features associated with a train, redundant to the train that has inoperable DG(s).The Completion Time for Required Actions B.3 and C.2 are intended to allow the operator time to evaluate and repair any discovered inoperabilities.

This Completion Time also allows for an exception to the normal 'time zero" for beginning the allowed outage time "clock." ln this Required Action, the Completion Time only begins on discovery that both: (continued)

Revision 50, 125, 132 Amendment 39, 84, 103 , 110 Watts Bar-Unit 1 B 3.8-8 AC Sources - Operating B 3.8.1 BASES ACTIONS 8.3 and C.2 (continued)

: a. An inoperable DG exists; and b. A required feature on the other train (Train A or Train B) is inoperable.

lf at any time during the existence of this Condition (one or more DGs inoperable) a required feature subsequently becomes inoperable, this Completion Time would begin to be tracked.Discovering one or more required DGs in Train A or one or more DGs in Train B inoperable coincident with one or more inoperable required support or supported features, or both, that are associated with the OPERABLE DGs, results in starting the Completion Time for the Required Action. Four hours from the discovery of these events existing concurrently is Acceptable because it minimizes risk while allowing time for restoration before subjecting the plant to transients associated with shutdown.(continued)

Revision 132 Amendment 1 10 Watts Bar-Unit 1 B 3.8-8a AC Sources - Operating B 3.8.1 BASES ACTIONS B.3 and C.2 (continued) ln this Condition, the remaining OPERABLE DGs and offsite circuits are adequate to supply electrical power to the onsite Class '1E Distribution System.Thus, on a component basis, single failure protection for the required feature's function may have been lost; however, function has not been lost. The 4 hour Completion Time takes into account the OPEMBILITY of the redundant counterpart to the inoperable required feature. Additionally, the 4 hour Completion Time takes into account the capacity and capability of the remaining AC sources, a reasonable time for repairs, and the low probability of a DBA occurring during this period.8.4.1.8.4.2.

C.3.1 and C.3.2 Required Actions B.4.1 and C.3.1 provide an allowance to avoid unnecessary testing of OPERABLE DG. lf it can be determined that the cause of the inoperable DG(s) does not exist on the OPERABLE DG(s), SR 3.8.1.2 does not have to be performed.

For the performance of a Surveillance, Required Action B.4.1 is considered satisfied since the cause of the DG(s) being inoperable is apparent.

lf the cause of inoperability exists on other DG(s), the other DG(s)would be declared inoperable upon discovery and Condition F of LCO 3.8.1 would be entered if the other inoperable DGs are not on the same train, otherwise, if the other inoperable DGs are on the same train, the unit is in Condition C. Once the failure is repaired, the common cause failure no longer exists, and Required Actions B.4.1 and 8..2 are satisfied.

lf the cause of the initial inoperable DG cannot be confirmed not to exist on the remaining DG(s), performance of SR 3.8.1.2 suffices to provide assurance of continued OPEMBILITY of that DG(s).ln the event the inoperable DG(s) is restored to OPERABLE status prior to completing either 8.4.'1 ,8.4.2, C.3.1 or C.3.2, the corrective action program will continue to evaluate the common cause possibility.

This continued evaluation, however, is no longer under the 24 hour constraint imposed while in Condition B or C.According to Generic Letter 84-15 (Ref. 11), 24 hours is reasonable to confirm that the OPERABLE DG(s) is not affected by the same problem as the inoperable DG(s).B.5 ln Condition B, the remaining OPERABLE DGs and offsite circuits are adequate to supply electrical power to the onsite Class 1E Distribution System. The 1O-day Completion Time takes into account the capacity and capability of the remaining AC sources (including the 6.9 kV FLEX DG), a reasonable time for repairs, and the low probability of a DBA occurring during this period.(continued)

Revision 50, 125, 132 Amendment 39, 84, 103 , 110 Watts Bar-Unit 1 B 3.8-9 AC Sources - Operating B 3.8.1 BASES ACTIONS B.5 (continued) lf the 6.9 kV FLEX DG is or becomes unavailable with an inoperable DG, then action is required to restore the 6.9 kV FLEX DG to available status or to restore the DG to OPERABLE status within 72 hours from discovery of an unavailable 6.9 kV FLEX DG. However, if the 6.9 kV FLEX DG unavailability occurs sometime after 48 hours of continuous DG inoperability, then the remaining time to restore the 6.9 kV FLEX DG to available status or to restore the DG to OPERABLE status is limited to 24 hours.The72 hour and 24 hour Completion Times allow for an exception to the normal"time zero" for beginning the allowed outage time "clock.' The 72 hour Completion Time only begins on discovery that both an inoperable DG exists and the 6.9 kV FLEX DG is unavailable.

The 24 hour Completion Time only begins on discovery that an inoperable DG exists for 2 48 hours and the 6.9 kV FLEX DG is unavailable.

Therefore, when on DG is inoperable due to either preplanned maintenance (Preventive or corrective) or unplanned corrective maintenance work, the Completion Time can be extended from72 hours to 10 days if the 6.9 kV FLEX DG is verified available for backup operation.

The Fourth Completion Time for Required Action B.5 establishes a limit on the maximum time allowed for any combination of required AC power sources to be inoperable during any single contiguous occurrence of failing to meet the LCO. lf Condition B is entered while, for instance, an offsite circuit is inoperable and that circuit is subsequently restored OPERABLE, the LCO may already have been not met for up to 3 days. This could lead to a total of 13 days, since initial failure to meet the LCO, to restore the DGs. At this Time, an offsite circuit could again become inoperable, the DGs restored OPERABLE, and an additionalT2 hours (for a total of 20 days) allowed prior to complete restoration of the LCO. The 13-day Completion Time provides a limit on time allowed in a specified condition after discovery of failure to meet the LCO. This limit is considered reasonable for situations in which Conditions A and B are entered concurrently.

THE "AND'connector between the 1O-day and 13-day Completion Times mean that both Completion Times apply simultaneously, and the more restrictive Completion Time must be met.(continued)

Revision 50, 65, 125, 132 Amendment 39, 84, 110 Watts Bar-Unit 1 B 3.8-10 AC Sources - Operating B 3.8.1 BASES ACTIONS B.5 (continued)

Compliance with the contingency actions listed in Bases Table 3.8.1-2 is required whenever Condition B is entered for a planned or unplanned outage that will extend beyond 72 hours. lf Condition B is entered initially for an activity intended to last less than 72 hours or for an unplanned outage, the contingency actions should be invoked as soon as it is established that the outage period will be longer than72 hours.As in Required Action B.3, the Completion Time allows for an exception to the normal "Time zero" for beginning the allowed outage time "clock." This will result in establishing the "time zeto" atthe time that the LCO was initially not met, instead of at the time Condition B was entered.(continued)

Revision 132 Amendment 1 10 Watts Bar-Unit 1 B 3.8-10a AC Sources - Operating B 3.8.1 BASES ACTIONS (continued) c.4 According to Regulatory Guide 1.93, (Ref. 6), operation may continue in Condition C for a period that should not exceed 72 hours.ln Condition C, the remaining OPERABLE DGs and offsite circuits are adequate to supply electrical power to the onsite Class 1E Distribution System. The 72hour Completion Time takes into account the capacity and capability of the remaining AC sources, a reasonable time for repairs, and the low probability of a DBA occurring during this period. Restoration of at least on DG within 72 hours results in reverting back under Condition B and continuing to track the "time zero" Completion Time for one DG inoperable.