| title = Sequoyah Nuclear Plants, Units 1 and 2 Technical Specifications Conversion to NUREG-1431, Rev. 4.0 (SQN-TS-11-10) - Supplement 2. Part 2 of 8

{{#Wiki_filter:Licensee Response/NRC Response/NRC Question Closure Id 16NRC Question Number CSS-001Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation. Follow-up question is KAB001.Question Closure Date 4/24/2014Notification Scott BowmanKristy BucholtzMichelle ConnerRobert Elliott Khadijah Hemphill Lynn MynattLisa RegnerCarl SchultenRoger Scott Added By Khadijah Hemphill Date Added 4/24/2014 3:59 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

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Licensee Response/NRC Response/NRC Question Closure Id 94NRC Question Number CSS-002Select Application Licensee ResponseAttachment 1 Attachment 1 draft revised 3.0.9 DOC L01.pdf (17KB)Attachment 2 Response Statement SQN is adopting TSTF-427, Revision 2, as incorporated in NUREG-1431, Revision 4, with no deviations from Specification LCO 3.0.9.TVA has reviewed the TSTF-427 documentation and the technical justifications presented in the model application safety evaluation prepared by the NRC staff and find that the technical justifications presented are applicable to SQN Units 1 and 2.In addi tion, TVA will be adopti ng the LCO 3.0.9 Bases, as indicated in the ITS conversion su bmittal. The only deviations to the LCO 3.0.9 Bases have been made for cl arity and are justif ied in the Bases Justification for Deviations. , Regulatory Commitments, of the ITS subm ittal contains commitments associated with TSTF-427, as required by the Reviewer's Note in NUREG-1431 Bases for LCO 3.0.9.The tw o commitments included within Enclosure 8 for adoption of TSTF-427 are:7.Sequoyah Unit 1 & Unit 2 will incorporate the guidance of NUMARC 93-01 Section 11, which provides guid ance and details on the assessment of risk during maintenance.

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SQN Units 1 and 2.In addi tion, TVA will be adopti ng the LCO 3.0.9 Bases, as indicated in the ITS conversion su bmittal. The only deviations to the LCO 3.0.9 Bases have been made for cl arity and are justif ied in the Bases Justification for Deviations.See Attachment 1 for th e draft revised DOC L01.Response Date/Time 6/5/2014 4:00 PMClosure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonRay SchieleCarl SchultenAdded By Scott BowmanDate Added 6/5/2014 3:01 PMDate Modified Modified By Page 2of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

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L01 CTS Section 3.0 does not contain an allowance when barriers cannot support their support function. The proposed change to CTS 3.0, "LCO Applicability" adds a new LCO 3.0.9. The addition of LCO 3.0.9 to the CTS is to address barriers which cannot perform their related support function for Technical Specification systems. ITS LCO 3.0.9 allows barriers to be able to not perform their safety function for up to 30 days before declaring the supported system inoperable. Furthermore, due to this addition, an allowance is also needed in LCO 3.0.1. This allowance has been added.

Barriers are defined as doors, walls, floor plugs, curbs, hatches, installed structures or components, or other devices, not explicitly described in Technical Specifications, which are designed to provide for the performance of the safety function for the Technical Specification system after the occurrence of one or

more initiating events.  

The barrier which cannot perform its related support function will be evaluated and managed under the Maintenance Rule plant configuration control requirement, 10 CFR 50.65(a)(4), and the associated industry guidance (NUMARC 93-01, Revision 3). This provision is applicable whether the barrier is affected due to planned maintenance or due to a discovered condition. Should the risk assessment and risk management actions for a specific plant configuration or emergent condition not support the 30 day allowed time, the Maintenance Rule risk management determined allowed time and actions must be implemented or the supported system's LCO be considered not met.

Application of LCO 3.0.9 is dependent on the OPERABILITY of at least one train or subsystem of the supported Technical Specification system and the system's ability to mitigate the consequences of the specified initiating events. However, during the 30 day period allowed by LCO 3.0.9, there exists the possibility that the train or subsystem required to be OPERABLE will unexpectedly become inoperable. Absent any further consideration, this would likely result in both trains of a Technical Specification required system being declared inoperable DISCUSSION OF CHANGES ITS 3.0, LCO AND SR APPLICABILITY Sequoyah Unit 1 and 2 Page 10 of 10 (i.e., the train supported by the barriers to which LCO 3.0.9 was being applied and the emergent condition of the inoperable train). This would likely result in entering LCO 3.0.3 and a rapid plant shutdown. While this scenario is of low likelihood, it is of very high consequence to the licensee and, therefore, should be avoided unless necessary to avoid an actual plant risk. As a result, LCO 3.0.9 contains a provision which addresses the emergent condition of the required OPERABLE train or subsystem becoming inoperable while LCO 3.0.9 is being used. LCO 3.0.9 provides 24 hours to either restore the inoperable train or subsystem or to cease relying on the provisions of LCO 3.0.9 to consider the train or subsystem supported by the affected barrier(s) OPERABLE. This 24 hour period is not based on a generic risk evaluation, as it would be difficult to perform such an analysis in a generic fashion. Rather, plant risk during this 24 hour allowance is managed using the contemporaneous risk assessment and management required by 10 CFR 50.65(a)(4) and recognizes the unquantified advantage to plant safety of avoiding a plant shutdown with the associated

transition risk.  

A risk impact of the 30 day allowance for barriers was performed. All Sequoyah initiating events are located on the table depicted in TSTF-427 OR Sequoyah has evaluated the use of LCO 3.0.9 for a barrier protecting against an initiating event not on the table located in TSTF-427 and calculated the frequency ranges within the ranges in the table so the above analysis is applicable for those initiators. Therefore, LCO 3.0.9 can be utilized when inoperable barriers affect Systems, Structures, or Components (SSCs).  

L02 CTS 4.0.2 states, "Each Surveillance Requirement shall be performed within the specified surveillance interval with a maximum allowable extension not to exceed 25 percent of the specified surveillance interval."  ITS SR 3.0.2 states, " The specified Frequency for each SR is met if the Surveillance is performed within 1.25 times the interval specified in the Frequency, as measured from the

provided to perform some periodic Required Actions.

Insert 1 SQN is adopting TSTF

-427, Revision 2, as incorporated in NUREG

-1431, Revision 4, with no deviations from Specification LCO 3.0.9. TVA has reviewed the TSTF

-427 documentation and the technical justifications presented in the model application safety evaluation prepared by the NRC staff and find that the technical justifications presented are applicable to SQN Units 1 and 2. In addition, TVA will be adopting the LCO 3.0.9 Bases, as indicated in the ITS conversion submittal. The only deviations to the LCO 3.0.9 Bases have been made for clarity and are justified in the Bases Justification for Deviations.

p h p?re q uestT yp e=areaItemPrint&itemId=31 Licensee Response/NRC Response/NRC Question Closure Id 30 NRC Question Number CSS-003Select Application Licensee ResponseAttachment 1 Attachment 2 Response Statement The new paragraphs (Insert 3 in the ITS submittal) added to the Bases Background Section of ITS 2.1.1, Reac tor Core SLs, re flect the SQN CTS Bases revised as part of SQN's license amendment to allow the use of Areva Advanced W17 High Thermal Performance Fuel.The NRC issued Amendments 331 (Unit 1) and 324 (Unit 2) (ML12249A394) on September 26, 2012, in response to SQN's appl ication dated June 17, 2011 (ML11172A071), as supplemented by letters dated July 27, 2011 (ML11210B531), November 14, 2011 (ML11320A003), March 23 (ML12088A170), April 26 (ML12118A165), May 15 (ML12137A297), May 24 (ML12153A377), and June 26, 2012 (ML121850009).

p h p?re q uestT yp e=areaItemPrint&itemId=30 Licensee Response/NRC Response/NRC Question Closure Id329NRC Question Number CSS-003Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 9/10/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 9/10/2014 1:29 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 9/17/201 4htt p s://members.excelservices.com/rai/index.

JFD3 stated the change is made for clarity. Th e TVA proposed changes are not in accordance with the approved ITS.

Please adopt the ITS, and clarify the sentence to read: 

"A maximum time is placed on each use of this allowance to ensure that required barrie rs are restored."Page 1of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Attach File 1 Attach File 2 Issue Date 5/8/2014 Added By Carl SchultenDate Modified Modified By Date Added 5/8/2014 2:35 PMNotification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleCarl SchultenRoger ScottPage 2of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id 31NRC Question Number CSS-004 Select Application Licensee ResponseAttachment 1 Attachment 1 draft revised Bases pages for RAI CSS-004.pdf (25KB)Attachment 2 Response Statement In response to CSS-004, the proposed change to the ITS Bases for LCO 3.0.9 will be made.Specifically, the ISTS sentence, "A maximum time is placed on each use of this allowance to ensure that as required barriers are found or are otherw ise made unavailable, they are restored,"will be revised in ITS to state, "A maximum time is placed on each use of this allowance to ensure that required barriers are restored."

See Attachment 1 for the draft revised Bases pages.Response Date/Time 5/16/2014 6:00 PMClosure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleCarl Schulten Added By Scott BowmanDate Added 5/16/2014 12:57 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=31 LCO  Applicability B 3.0    Westinghouse STS B 3.0-13 Rev. 4.0  1Revision XXX Sequoyah Unit 1 BASES

Adoption of LCO

-01, Revision 3, Section 11, which provides guidance and details on the assessment and management of risk during maintenance.

If the allowed time expires and the barriers are unable to perform their related support function(s), the supported system's LCO(s) must be declared not met and the Conditions and Required Actions entered in accordance with LCO 3.0.2.  

This provision does not apply to barriers which support ventilation systems or to fire barriers. The Technical Specifications for ventilation systems provide specific Conditions for inoperable barriers. Fire barriers are addressed by other regulatory requirements and associated plant programs. This provision does not apply to barriers which are not required to support system OPERABILITY (see NRC Regulatory Issue Summary 2001-09, "Control of Hazard Barriers," dated April 2, 2001).

6discovered 3 3 3because that LCO  Applicability B 3.0    Westinghouse STS B 3.0-13 Rev. 4.0  1Revision XXX Sequoyah Unit 2 BASES

Adoption of LCO

: 1.  [LICENSEE] commits to the guidance of NUMARC 93

-01, Revision 3, Section 11, which provides guidance and details on the assessment and management of risk during maintenance.

: 2. [LICENSEE] commits to the guidance of NEI 04-08, "Allowance for Non Technical Specification Barrier Degradation on Supported System OPERABILITY (TSTF

-427) Industry Implementation Guidance," March 2006.

Barriers are doors, walls, floor plugs, curbs, hatches, installed structures or components, or other devices, not explicitly described in Technical Specifications, that support the performance of the safety function of systems described in the Technical Specifications. This LCO states that the supported system is not considered to be inoperable solely due to required barriers not capable of performing their related support function(s) under the described conditions. LCO 3.0.9 allows 30 days before declaring the supported system(s) inoperable and the LCO(s) associated with the supported system(s) not met. A maximum time is placed on each use of this allowance to ensure that as required barriers are found or are otherwise made unavailable, they are restored. However, the allowable duration may be less than the specified maximum time based on the risk assessment.  

If the allowed time expires and the barriers are unable to perform their related support function(s), the supported system's LCO(s) must be declared not met and the Conditions and Required Actions entered in accordance with LCO 3.0.2.  

6discovered 3 3 3because that Licensee Response/NRC Response/NRC Question Closure Id223NRC Question Number CSS-004Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/4/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottCaroline TiltonAdded By Caroline Tilton Date Added 8/4/2014 4:07 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

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e., ((2500 psia x 110%) -15 psi)) =

2735 psig. The Background sec tion markup change JFD1 (shown below) converted the design pr essure 2500 psia to psig. However, 110% of the design pressure in psig would calculate a Pressure Safety Limit of 2733.5 psig (110% of 2485 psig is 2733.5 psig). Please r evise the Bases to retain 2500 psia as the design pressure of the RCS.

BACKGROUND The design pressure of the RCS is 2485psig. During normal operation and AOOs, RCS pressure is limited from exceeding the design pressure by more than 10%, in accordance with Sect ion III of the ASME Code (Ref. 2). To ensure system integrity, all RCS components are hydrostatically tested at 125% of design pressure, accordi ng to the ASME C ode requirements prior to initial operation when ther e is no fuel in the core. Following inception of unit operation, RCS compone nts shall be pressure tested, in accordance with the requirements of ASME Code, Sect ion XI (Ref. 3).

SAFETY LIMIT The maximum transient pressure allowed in the RCS pressure vessel under the ASME Code, Section III, is 110% of design pressure. The maximum transient pressure allowed in the RCS piping, val ves, and fittings under [USAS, Section B31.1 (Ref. 6)] is 120% of design pres sure.              Page 1of 2 Sequoyah ITS Conversion Databas e 8/27/201 4htt p s://members.excelservices.com/rai/index.

The most limiting of these two allowances is the 110% of design pressure; therefore, the SL on maximum allowable RCS pressure is 2735psig.Attach File 1 Attach File 2 Issue Date 5/8/2014Added By Carl SchultenDate Modified 5/8/2014 3:14 PMModified By Ray Schiele Date Added 5/8/2014 2:31 PMNotification Scott BowmanMichelle Conner Khadijah HemphillAndrew Hon Lynn MynattRay Schiele Carl SchultenRoger ScottPage 2of 2 Sequoyah ITS Conversion Databas e 8/27/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id 34NRC Question Number CSS-005Select Application Licensee Response  Attachment 1 ITS 2.1.2 Bases markup.pdf (33KB)Attachment 2 Response Statement In response to CSS-005, the proposed change to the Background Section of the Reactor Coolant System Pressure SL Bases will be made.

Specifically, the Bases will be revised to state, "The design pressure of the RCS is 2500 psia."Additionally, the JFD indicator in the right hand margin will be removed.See Attachment 1 for the draft ITS 2.1.2 Bases markup.Response Date/Time 5/23/2014 9:30 AM Closure Statement Question Closure Date Notification Scott BowmanMichelle Conner Khadijah HemphillAndrew Hon Lynn MynattRay Schiele Carl SchultenAdded By Scott Bowman Date Added 5/23/2014 8:27 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/27/201 4htt p s://members.excelservices.com/rai/index.

B 2.1.2 Reactor Coolant System (RCS) Pressure SL 

APPLICABLE The RCS pressurizer safety valves, the main steam safety valves SAFETY  (MSSVs), and the reactor high pressure trip have settings established ANALYSES  to ensure that the RCS pressure SL will not be exceeded.

The RCS pressurizer safety valves are sized to prevent system pressure from exceeding the design pressure by more than 10%, as specified in Section III of the ASME Code for Nuclear Power Plant Components (Ref. 2). The transient that establishes the required relief capacity, and hence valve size requirements and lift settings, is a complete loss of  coolant2485 psig 3 1 RCS Pressure SL B 2.1.2    Westinghouse STS B 2.1.2-1 Rev. 4.0  1SEQUOYAH UNIT 2 Revision XXX B 2.0  SAFETY LIMITS (SLs)

B 2.1.2  Reactor Coolant System (RCS) Pressure SL 

BASES BACKGROUND The SL on RCS pressure protects the integrity of the RCS against overpressurization. In the event of fuel cladding failure, fission products are released into the reactor coolant. The RCS then serves as the primary barrier in preventing the release of fission products into the atmosphere. By establishing an upper limit on RCS pressure, the continued integrity of the RCS is ensured. According to 10 CFR 50, Appendix A, GDC 14, "Reactor Coolant Pressure Boundary," and GDC 15, "Reactor Coolant System Design" (Ref. 1), the reactor pressure coolant boundary (RCPB) design conditions are not to be exceeded during normal operation and anticipated operational occurrences (AOOs). Also, in accordance with GDC 28, "Reac tivity Limits" (Ref. 1), reactivity accidents, including rod ejection, do not result in damage to the RCPB

The design pressure of the RCS is 2500 psia. During normal operation and AOOs, RCS pressure is limited from exceeding the design pressure by more than 10%, in accordance with Section III of the ASME Code (Ref. 2). To ensure system integrity, all RCS components are hydrostatically tested at 125% of design pressure, according to the ASME Code requirements prior to initial operation when there is no fuel in the core. Following inception of unit operation, RCS components shall be pressure tested, in accordance with the requirements of ASME Code, Section XI (Ref. 3).

p h p?re q uestT yp e=areaItemPrint&itemId=300 ITS NRC Questions Id 73NRC Question Number CSS-006 Category TechnicalITS Section 3.2 ITS Number 3.2.3DOC Number A-4JFD Number JFD Bases Number Page Number(s) 181NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add Name Conf Call Requested NNRC Question ITS 3.2.3 Axial Flux Difference1.Page 181, DOC A0 4 states, in part:

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Licensee Response/NRC Response/NRC Question Closure Id 69NRC Question Number CSS-006Select Application Licensee ResponseAttachment 1 Attachment 1 revised 3.2.3 DOC A04.pdf (24KB)Attachment 2 Response Statement In response to CSS-006, discussion of change (DOC) A04, on page 181 of Enclosure 2, Volume 7, will be revised.Specifically, the sentence, "CTS 3.0.4 and ITS 3.0.4 prohibit entering the MODE of Applicability of a Technical Specification unless the requirements of the LCO are met."will be revised to, "CTS 3.0.

4 and ITS 3.0.4 specify c onditions for entering the MODE of Applicabil ity of a Technical Specification when the LCO is not met."See Attachment 1 for th e draft revised DOC A04.Response Date/Time 5/29/2014 4:00 PMClosure Statement Question Closure Date Notification Scott BowmanKristy BucholtzMichelle ConnerKhadijah HemphillAndrew Hon Ray SchieleCarl SchultenAdded By Scott Bowman Date Added 5/29/2014 2:55 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

DISCUSSION OF CHANGES ITS 3.2.3, AXIAL FLUX DIFFERENCE (AFD)

Sequoyah Unit 1 and Unit 2 Page 1 of 4 ADMINISTRATIVE CHANGES A01 In the conversion of the Sequoyah Nuclear Plant (SQN) Current Technical Specifications (CTS) to the plant specific Improved Technical Specifications (ITS), certain changes (wording preferences, editorial changes, reformatting, revised numbering, etc.) are made to obtain consistency with NUREG - 1431, Rev. 4.0, "Standard Technical Specifications - Westinghouse Plants" (ISTS) and additional Technical Specification Task Force (TSTF) travelers included in this

submittal.  

These changes are designated as administrative changes and are acceptable because they do not result in technical changes to the CTS.  

A02 CTS 3.2.1 states "The indicated AXIAL FLUX DIFFERENCE (AFD) shall be maintained within the limits specified in the COLR." CTS 3.2.1 ACTION a provides ACTIONs to take when the indicated AFD is outside the limits. CTS 4.2.1.1 requires a determination that the indicated AFD is within limits. CTS 4.2.1.2 states that the indicated AFD shall be considered outside the limits when at least 2 OPERABLE excore channels are indicating the AFD to be outside the limits. ITS LCO 3.2.3 states "The AFD in % flux difference units shall be maintained within the limits specified in the COLR." ITS LCO 3.2.3 is modified by a Note specifying when AFD is considered to be outside the limits. ITS SR 3.2.3.1 requires verification that AFD is within limits. This changes the CTS by deleting "indicated and adding "% flux difference units" to the LCO statement.  

This change is acceptable because the requirements have not changed. CTS 3.0.4 and ITS 3.0.4 prohibit entering the MODE of Applicability of a Technical Specification unless the requirements of the LCO are met. CTS 3.2.1 and ITS 3.2.3 are applicable in MODE 1 with THERMAL POWER > 50% RTP (CTS) and  50 RTP (ITS). Therefore, both the CTS and ITS prohibit exceeding Licensee Response/NRC Response/NRC Question Closure Id260NRC Question Number CSS-006Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/12/2014Notification Scott Bowman Michelle ConnerLynn MynattRay SchieleRoger ScottPete SnyderAdded By Khadijah Hemphill Date Added 8/12/2014 7:12 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

ThemostimportantCondition2ev eareuncont rolledbank w ithdrawalandboration ordilution ac cidents.usedtoconfirmtheadequacyoftheOverpowerTandOvertemperature Ttripsetpoints.Attach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Modified By Date Added 5/19/2014 9:42 AMNotification Michelle ConnerKhadijah Hemphill Andrew Hon Lynn Mynatt Lisa RegnerRay SchieleCarl Schulten Roger ScottPage 1of 1 Sequoyah ITS Conversion Databas e 8/26/201 4htt p s://members.excelservices.com/rai/index.

Bases Section, on pages 191 and 197 of Enclosure 2, Volume 7, will be revised.Specifically, the deleted text in the ISTS Bases fourth paragraph will be revised to read , "A Condition 4 ev ent significantly affected by the initial axial power distribution, as in dicated by AFD, is the LOCA.A Condition 3 event sign ificantly affected by AFD is the Complete Loss of RCS Flow event. A Condition 2 event significantly affected by AFD is the Uncontrolled RCCA Bank Withdrawal at Power event."See Attachment 1 for a draft revised ASA Bases for ITS 3.2.3 AFD.Response Date/Time 6/12/2014 4:45 AM Closure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew Hon Ray SchieleCarl SchultenAdded By Scott Bowman Date Added 6/12/2014 3:46 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

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APPLICABLE The AFD is a measure of the axial power distribution skewing to either the SAFETY  top or bottom half of the core. The AFD is sensitive to many core related ANALYSES parameters such as control bank positions, core power level, axial burnup, axial xenon distribution, and, to a lesser extent, reactor coolant temperature and boron concentration.  

The allowed range of the AFD is used in the nuclear design process to confirm that operation within these limits produces core peaking factors and axial power distributions that meet safety analysis requirements.  

The RAOC methodology (Ref.

: 2) establishes a xenon distribution library with tentatively wide AFD limits. One dimensional axial power distribution calculations are then performed to demonstrate that normal operation power shapes are acceptable for the LOCA and loss of flow accident, and for initial conditions of anticipated transients. The tentative limits are adjusted as necessary to meet the safety analysis requi rements.

The limits on the AFD ensure that the Heat Flux Hot Channel Factor (F Q(Z)) is not exceeded during either normal operation or in the event of xenon redistribution following power changes. The limits on the AFD also restrict the range of power distributions that are used as initial conditions in the analyses of Condition 2, 3, or 4 events. This ensures that the fuel cladding integrity is maintained for these postulated accidents.

Condition 2 accidents simulated to begin from within the AFD limits are used to confirm the adequacy of the Overpower T and Overtemperature T trip setpoints.

The limits on the AFD satisfy Criterion 2 of 10 CFR 50.36(c)(2)(ii).

LCO The shape of the power profile in the axial (i.e., the vertical) direction is largely under the control of the operator through the manual operation of the control banks or automatic motion of control banks. The automatic motion of the control banks is in response to temperature deviations resulting from manual operation of the Chemical and Volume Control System to change boron concentration or from power level changes.  

3). Separate signals are taken from the top and bottom detectors. The AFD is defined as the difference in normalized flux signals between the top and bottom excore detectors in each detector well. For convenience, this flux difference is

converted to provide flux difference units expressed as a percentage and labeled as % flux or %I. 1 and 2 1 2X, Y, 2 2 s 6 , 6 AFD (RAOC Methodology)

B 3.2.3 B    Westinghouse STS B 3.2.3 B-2 Rev. 4.0 2 1 1SEQUOYAH UNIT 2 Revision XXX BASES

: 2) establishes a xenon distribution library with tentatively wide AFD limits. One dimensional axial power distribution calculations are then performed to demonstrate that normal operation power shapes are acceptable for the LOCA and loss of flow accident, and for initial conditions of anticipated transients. The tentative limits are adjusted as necessary to meet the safety analysis requi rements.

The limits on the AFD ensure that the Heat Flux Hot Channel Factor (F Q(Z)) is not exceeded during either normal operation or in the event of xenon redistribution following power changes. The limits on the AFD also restrict the range of power distributions that are used as initial conditions in the analyses of Condition 2, 3, or 4 events. This ensures that the fuel cladding integrity is maintained for these postulated accidents.

Condition 2 accidents simulated to begin from within the AFD limits are used to confirm the adequacy of the Overpower T and Overtemperature T trip setpoints.  

The limits on the AFD satisfy Criterion 2 of 10 CFR 50.36(c)(2)(ii).

LCO The shape of the power profile in the axial (i.e., the vertical) direction is largely under the control of the operator through the manual operation of the control banks or automatic motion of control banks. The automatic motion of the control banks is in response to temperature deviations resulting from manual operation of the Chemical and Volume Control System to change boron concentration or from power level changes.  

Signals are available to the operator from the Nuclear Instrumentation System (NIS) excore neutron detectors (Ref.

3). Separate signals are taken from the top and bottom detectors. The AFD is defined as the difference in normalized flux signals between the top and bottom excore detectors in each detector well. For convenience, this flux difference is

p h p?re q uestT yp e=areaItemPrint&itemId=261 ITS NRC Questions Id 75 NRC Question Number CSS-008 Category TechnicalITS Section 3.2ITS Number 3.2.4DOC Number JFD Number JFD Bases Number 3Page Number(s) 235 NRC Reviewer Supervisor SelectTechnical Branch POC Add NameConf Call Requested N NRC Question ITS 3.2.4 Quadrant Power Tilt Ratio1.ACTIONS, A.3 Bases Page 235, JFD3, discussion (shown below) on SRs required to be performe d by Required Action A.3 incorrectly modifies the bases.Ifthesepeakingfactorsare notwithintheirlimits,theRequiredActions of the applicable LCOs t h eseSurveillances provide anappropriateresponsefortheabnormalcondition.Please revise the ITS Bases to addr ess the ISTS basis fact that Required Action A.3 states:"Perfo rm SR 3.2.1.1, SR 3.2.1.2, SR 3.2.1.3, SR 3.2.2.1 and SR 3.2.2.2.An example revision is provided below.If these peaking factors are not within their limits, the Required Actions of the applicable LCOs of these Surveillances provide an appropriate response for the abnormal condition.Attach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Modified By Page 1of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

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Licensee Response/NRC Response/NRC Question Closure Id 93 NRC Question Number CSS-008Select Application Licensee ResponseAttachment 1 Attachment 1 revised ITS 3.2.4 Bases A.3.pdf (62KB)Attachment 2 Response Statement In response to CSS-008, the ITS Bases for Required Action A.3, on pages 235 and 242 of Enclosure 2, Volume 7, will be revised.Specifically, the sentence, "If these peaking factors are not within th eir limits, the Required Actions of the applicable LCOs provide an appropriate response for the abnormal condition."will be revised to, "If these peaking factors are not within their limits, the Required Acti ons of the applicable LCOs of these Surveillances provide an appropriate response for the abnormal condition."See Attachment 1 for the draft revised ITS Bases for Required Action A.3.Response Date/Time 6/4/2014 10:45 AM Closure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonRay SchieleCarl SchultenAdded By Scott Bowman Date Added 6/4/2014 9:42 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

A.2 After completion of Required Action A.1, the QPTR alarm may still be in its alarmed state. As such, any additional changes in the QPTR are detected by requiring a check of the QPTR once per 12 hours thereafter.

A 12 hour Completion Time is sufficient because any additional change in QPTR would be relatively slow.

A.3 The peaking factors F Q(Z), as approximated by )Z(F C Q and )Z(F W Q , and H N F are of primary importance in ensuring that the power distribution remains consistent with the initial conditions used in the safety analyses. Performing SRs on H N F and F Q(Z) within the Completion Time of 24 hours after achieving equilibrium conditions from a Thermal Power reduction per Required Action A.1 ensures that these primary indicators of power distribution are within their respective limits. Equilibrium conditions are achieved when the core is sufficiently stable at intended operating conditions to support flux mapping. A Completion Time of 24 hours after achieving equilibrium conditions from Thermal Power reduction per Required Action A.1 takes into consideration the rate at which peaking factors are likely to change, and the time required to stabilize the plant and perform a flux map. If these peaking factors are not within their limits, the Required Actions of these Surveillances provide an appropriate response for the abnormal condition. If the QPTR remains above its specified limit, the peaking factor surveillances are required each 7 days thereafter to evaluate H N F and F Q (Z) with changes in power distribution. Relatively small changes are expected due to either burnup and xenon redistribution or correction of the cause for exceeding the

A.4 Although H N F and F Q(Z) are of primary importance as initial conditions in the safety analyses, other changes in the power distribution may occur as the QPTR limit is exceeded and may have an impact on the validity of the safety analysis. A change in the power distribution can affect such reactor parameters as bank worths and peaking factors for rod  X, Y, FH(X, Y) X, Y, FH(X, Y) X, Y, FH(X, Y) X, Y, FH(X, Y) 1 1 1 1 the applicable LCOs 3 QPTR B 3.2.4 Westinghouse STS B 3.2.4-3 Rev. 4.0  2Revision XXX SEQUOYAH UNIT 2 BASES ACTIONS  (continued)

A.2 After completion of Required Action A.1, the QPTR alarm may still be in its alarmed state. As such, any additional changes in the QPTR are detected by requiring a check of the QPTR once per 12 hours thereafter.

A.3 The peaking factors F Q(Z), as approximated by )Z(F C Q and )Z(F W Q , and H N F are of primary importance in ensuring that the power distribution remains consistent with the initial conditions used in the safety analyses. Performing SRs on H N F and F Q(Z) within the Completion Time of 24 hours after achieving equilibrium conditions from a Thermal Power reduction per Required Action A.1 ensures that these primary indicators of power distribution are within their respective limits. Equilibrium conditions are achieved when the core is sufficiently stable at intended operating conditions to support flux mapping. A Completion Time of 24 hours after achieving equilibrium conditions from Thermal Power reduction per Required Action A.1 takes into consideration the rate at which peaking factors are likely to change, and the time required to stabilize the plant and perform a flux map. If these peaking factors are not within their limits, the Required Actions of these Surveillances provide an appropriate response for the abnormal condition. If the QPTR remains above its specified limit, the peaking factor surveillances are required each 7 days thereafter to evaluate H N F and F Q (Z) with changes in power distribution. Relatively small changes are expected due to either burnup and xenon redistribution or correction of the cause for exceeding the

A.4 Although H N F and F Q(Z) are of primary importance as initial conditions in the safety analyses, other changes in the power distribution may occur as the QPTR limit is exceeded and may have an impact on the validity of the safety analysis. A change in the power distribution can affect such reactor parameters as bank worths and peaking factors for rod  X, Y, FH(X, Y) X, Y, FH(X, Y) X, Y, FH(X, Y) X, Y, FH(X, Y) 1 1 1 1 the applicable LCOs 3 Licensee Response/NRC Response/NRC Question Closure Id262NRC Question Number CSS-008Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/12/2014Notification Scott Bowman Michelle ConnerLynn MynattRay SchieleRoger ScottPete SnyderAdded By Khadijah Hemphill Date Added 8/12/2014 7:14 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

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ITS NRC Questions Id 76NRC Question Number CSS-009Category TechnicalITS Section 3.6ITS Number 3.6.1DOC Number A-4JFD Number JFD Bases Number Page Number(s) 18NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add NameConf Call Requested NNRC Question ITS 3.6.1 Containment1.Page 18, DOC A04 states, in part: In addition, deletion of the current Actions of CTS 3.6.1.6 is acceptable, because CTS 4.0.4 (ITS SR 3.0.4) already precludes entering the MODE of Applicability when the LCO is not met.Please revise this DOC statement to correctly reflect the requirements of CTS 4.0.4.An example revision is provided below. In addition, deletion of the current Actions of CTS 3.6.1.6 is acceptable, because CTS 4.0.4 (ITS SR 3.0.4) already precludes entering the MODE of Applicability when the LCO is not met in accordance with the requirements of LCO 3.0.4

Licensee Response/NRC Response/NRC Question Closure Id 71NRC Question Number CSS-009Select Application Licensee ResponseAttachment 1 Attachment 1 revised 3.6.1 DOC A04.pdf (17KB)Attachment 2 Response Statement In response to CSS-009, discussion of change (D OC) A04 on page 18 of Enclosure 2, Volume 11, will be revised.Specifically, the sentence, "In addition, deletion of the current Ac tions of CTS 3.6.

1.6 is acceptable, because CTS 4.0.4 (ITS SR 3.0.4) already precludes entering the MODE of Applicability when the LCO is not met."w ill be revised to read, "In addition, deletion of the current Actions of CTS 3.6.1.6 is acceptable, because CTS 4.0.4 (ITS SR 3.0.4) already precludes entering the MODE of Applicability when the LCO is not met in accordance with the requi rements of LCO 3.0.4."See Attachment 1 for th e draft revised DOC A04.Response Date/Time 5/29/2014 4:05 PMClosure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew Hon Ray SchieleCarl SchultenAdded By Scott BowmanDate Added 5/29/2014 3:02 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/26/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=71 DISCUSSION OF CHANGES ITS 3.6.1, CONTAINMENT Sequoyah Unit 1 and Unit 2 Page 2 of 4 A03 CTS 4.6.1.1.c requires performance of visual examinations and leakage rate testing in accordance with the Containment Leakage Rate Testing Program. ITS SR 3.6.1.1 requires this same test, but adds an exception for containment air lock testing. This changes the CTS by excluding the containment air lock testing in the required CTS surveillance.

This change is acceptable because ITS SR 3.6.2.1 requires performance of air lock leakage rate testing. Furthermore, ITS SR 3.6.2.1 is required to be evaluated against the acceptance criteria that are applicable to SR 3.6.1.1. This will ensure the airlock barrel leakage is accounted for in determining the combined Type B and C containment leakage rate. This change is designated as administrative because it does not result in technical changes to the CTS.

A04 CTS 3.6.1.6, ACTION, states, "With the structural integrity of the containment vessel not conforming to the above requirements, restore the structural integrity to within the limits prior to increasing the Reactor Coolant System temperature above 200°F."  CTS 3.6.1.6 ACTION does not state what action to take if the structural integrity limits are not met while in MODE 1, 2, 3, or 4. Thus, entry into CTS 3.0.3 is required if CTS 3.6.1.6 is not met while in MODE 1, 2, 3, or 4.

CTS 3.0.3 allows 1 hour to prepare for a shutdown and requires the unit to be in HOT STANDBY (ITS MODE 3) within the next 6 hours, HOT SHUTDOWN (ITS MODE 4) within the following 6 hours, and Cold Shutdown (similar to ITS MODE

: 5) within the subsequent 24 hours (37 hours total). ITS 3.6.1 ACTION A requires that if the containment is inoperable, it must be restored to OPERABLE status within 1 hour. ITS 3.6.1 ACTION B requires that if the Required Action and associated Completion Time are not met (i.e., the containment is not restored to OPERABLE status in 1 hour), the unit must be in MODE 3 within 6 hours and MODE 5 within 36 hours (37 hours total). This changes CTS by stating the ACTIONS rather than deferring to CTS 3.0.3. In addition, it deletes the CTS Actions to restore the limits prior to increasing the Reactor Coolant System temperature above 200

°F. The purpose of CTS 3.0.3 is to place the unit outside the MODE of Applicability within a reasonable amount of time in a controlled manner. CTS 3.6.1.6 is silent on these actions, deferring to CTS 3.0.3 for the actions to accomplish this. This change is acceptable because the ACTIONS specified in ITS 3.6.1 adopt ISTS structure for placing the unit outside the MODE of Applicability while changing the time specified to enter MODE 3 and MODE 5 but still within the plants ability to safely shutdown. In addition, deletion of the current Actions of CTS 3.6.1.6 is acceptable, because CTS 4.0.4 (ITS SR 3.0.4) already precludes entering the MODE of Applicability when the LCO is not met. Therefore, it is not necessary to include these requirements as specific actions in ITS 3.6.1. This change is designated as administrative because it does not result in technical changes to

the CTS.

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Licensee Response/NRC Response/NRC Question Closure Id 73 NRC Question Number CSS-010Select Application Licensee Response Attachment 1 Attachment 1 revised 3.6.1 Bases JFD 5.pdf (901KB)Attachment 2 Response Statement In response to CSS-010, just ification for deviation (JFD) 5, on page 38 of Enclosure 2, Volume 11, will be revised.Specifically, JFD 5 will be revised to, "The ISTS bracketed requirement regarding Containment Tendon Surveillance Program is deleted because it is not applicable to SQN Unit 1 and Unit 2. Reference 4, ASME Code, Section XI, S ubsection IWL, is associated with the Containment Tendon Surveillance Program.Therefore, it is not applicable to SQN, and the reference is deleted.The SQN containments do not util ize containment tendons."

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Licensee Response/NRC Response/NRC Question Closure Id226NRC Question Number CSS-010Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/4/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/4/2014 5:01 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

ITS NRC Questions Id 78NRC Question Number CSS-011Category TechnicalITS Section 3.6ITS Number 3.6.2DOC Number JFD Number JFD Bases Number Page Number(s) n/aNRC Reviewer Supervisor SelectTechnical Branch POC Add NameConf Call Requested NNRC Question No RAIsAttach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Modified By Date Added 5/19/2014 9:51 AMNotification Scott BowmanMichelle ConnerKhadijah HemphillAndrew Hon Lynn MynattLisa RegnerRay Schiele Carl SchultenRoger ScottPage 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=78 Licensee Response/NRC Response/NRC Question Closure Id224NRC Question Number CSS-011Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/4/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/4/2014 4:14 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Perform SR 3.6.3.5 for the resilient seal purge valves closed to comply with Required Action G.1. [Emphasis added]Please provide a discussion of change for the language added to CTS ACTION e in ITS Re quired Action G.3.

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Licensee Response/NRC Response/NRC Question Closure Id100 NRC Question Number CSS-012 Select Application Licensee Response Attachment 1 Attachment 1 3.6.3 resilient revision.pdf (37KB)Attachment 2 Response Statement CTS 4.6.3.6 requires the performance of leakage rate testing of each containment purge supply and exhaust isolation valve.The equivalent test in ITS is SR 3.6.3.5.ITS SR 3.6.3.5 only applies to containment purge valves with resilient seals.This change, as discussed in discussion of change (DOC) A07, is appropriate as each of the purge supply and exhaust isolation valves at SQN has a resilient seal.Because CTS 3.6.3 Action e requires the performance of CTS 4.6.3.6, the same change applies to ITS 3.6.3 Required Action G.3 with regard to the performance of SR 3.6.3.5.Therefore, ITS 3.6.3 DOC A07 will be revised to include a discussion of the change to CTS 3.6.3 Action e, as it applies to the performance of SR 3.6.3.5 for the resilient purge valves closed to comply with Required Action G.1.See Attachment 1 for the changes to the CTS 3.6.3 markup (pages 85 and 93 of Enclosure 2, Volume 11) and ITS 3.6.3 DOC A07 (page 102).Response Date/Time 6/5/2014 5:00 PMClosure Statement Question Closure Date Notification Scott BowmanMichelle Conner Khadijah HemphillAndrew HonRay SchieleCarl Schulten Added By Scott Bowman Date Added 6/5/2014 3:55 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=100 A01ITS ITS 3.6.3 CONTAINMENT SYSTEMS ACTIONS (continued)

April 13, 2009 SEQUOYAH - UNIT 1    3/4 6-18    Amendment No. 12, 81, 101, 120, 197, 203, 217, 254, 271, 301, 323 Page 2 of 16 ACTION B  ACTION D ACTION F ACTION E Condition B Note SR 3.6.3.1 In accordance with the Surveillance Frequency Control Program LA01SR 3.6.3.2, SR 3.6.3.3 shield building A05 ACTION H ACTION A ACTION C ACTION B, ACTION D ACTION A A04 ACTION G shield building A05 L02 A08 L03check valve, L04 M01Add proposed Categories and Completion Times A01ITS ITS 3.6.3 CONTAINMENT SYSTEMS ACTIONS (continued)

: b. With more than one pair of containment purge lines open or    with one or more penetration flow paths with two containment isolation valves inoperable for reasons other than:  1. leakage rate limits of containment purge isolation valve(s), 2. leakage rate limit of BYPASS LEAKAGE PATHS TO THE AUXILIARY BUILDING , or  3. inoperable containment vacuum relief isolation valve(s),

isolate the affected penetration within 1 hour by use of at least one closed and deactivated automatic valve, closed manual valve, or blind flange and verify# the affected penetration flow path is isolated once per 31 days.

: c. With one or more containment vacuum relief isolation valve(s) inoperable, the valve(s) must be returned to OPERABLE status within 72 hours.  

: d. With one or more BYPASS LEAKAGE PATHS TO THE AUXILIARY BUILDING not within limit, restore within limit within 4 hours.  

: e. With one or more penetration flow paths with one or more containment purge supply and/or exhaust isolation valves not within leakage limits, isolate the affected penetration flow path by use of at least one closed and de-activated automatic valve, closed manual valve, or blind flange within 24 hours. Verify# the affected penetration flow path is isolated once per 31 days for isolation devices outside containment and prior to entering MODE 4 from MODE 5 if not performed within the previous 92 days for isolation devices inside containment. Perform SR 4.6.3.6 once per 92 days for the valve used to isolate the affected penetration flow path.  

: f. With one or more penetration flow paths of a closed system design with one containment isolation valve inoperable, isolate the affected penetration flow path within 72 hours by use of at least one closed and de-activated automatic valve, closed manual valve, or blind flange, and verify# the affected penetration is isolated once per 31 days.  

: g. With any of the above ACTIONS not met, be in at least HOT STANDBY within the next 6 hours  and in COLD SHUTDOWN within the following 30 hours.

* Valves and blind flanges in high radiation areas may be verified by use of administrative  means. ------------------------------------------------------------------------------------------------------------------------------

4.6.3.1 Verify each purge supply and/or exhaust isolation valve is closed, except when containment purge valves (only one set of supply valves and one set of exhaust valves) are open for pressure control, ALARA or air quality considerations for personnel entry, or for Surveillances that require the valves to be open, at least once per 31 days. April 13, 2009 SEQUOYAH - UNIT 2 3/4 6-18    Amendment No. 72, 90, 104, 109,  193, 207, 245, 260, 290, 315 Page 10 of 16 ACTION B  ACTION D ACTION F ACTION G ACTION E Condition B Note SR 3.6.3.1 In accordance with the Surveillance Frequency Control Program LA01SR 3.6.3.2, SR 3.6.3.3 shield building A05 ACTION H ACTION A ACTION C ACTION B, ACTION D ACTION A A04shield building A05 L02 A08 L03check valve, L04 M01Add proposed Categories and Completion Times DISCUSSION OF CHANGES ITS 3.6.3, CONTAINMENT ISOLATION VALVES Sequoyah Unit 1 and Unit 2 Page 3 of 12 This change is designated as administrative since it does not result in a technical change to the CTS.  

A06 CTS 4.6.3.3 requires the isolation time of each power operated or automatic containment isolation valve to be determined to be within limits when tested pursuant to Specification 4.0.5. ITS SR 3.6.3.4 requires the isolation time of each automatic power operated containment isolation valve to be verified within limits with a Frequency of "In accordance with the Inservice Testing Program."

This changes the CTS by stating containment isolation valve testing is performed at a Frequency that is in accordance with the Inservice Testing Program.

A07 CTS 4.6.3.6 requires a performance of a leakage rate test for each containment purge supply and exhaust isolation valve at least once per 3 months. ITS SR 3.6.3.5 requires performance of a leakage rate test for containment purge valves with resilient seals at a Frequency of "In accordance with the Surveillance Frequency Control Program."  This changes the CTS by specifying that the leakage rate test is only required to be performed on isolation valves with resilient seals. Moving the specified Surveillance Frequency to the Surveillance Frequency Control Program is discussed in DOC LA01.

The purpose of CTS 4.6.3.6 is to verify the leakage rate of each containment purge supply and exhaust isolation valve is within limits. CTS 4.6.3.6 does not specify that the Surveillance Requirement only applies to containment purge supply and exhaust isolation valves with resilient seals, because each of the purge supply and exhaust isolation valves at SQN has a resilient seal. Specifying within ITS SR 3.6.3.5 that the SR only applies to containment purge valves with resilient seals, aligns the text with the ISTS, and is consistent with the Bases justifying the increased leakage test Frequency for purge valves with resilient seals. This change is designated as administrative, because it does not result in a technical change to the CTS.

A08 CTS 3.6.3 ACTION a, in part, provides a required action to isolate one inoperable containment isolation valve in one or more penetration flow paths with two containment isolation valves. CTS 3.6.3 ACTION f, in part, provides a required action to isolate one inoperable containment isolation valve in one or more penetration flow paths of a closed system design. ITS 3.6.3 ACTION A, in part, provides a required action to isolate one inoperable containment isolation valve in one or more penetration flow paths. This changes the CTS by combining the

required actions for one inoperable containment isolation valve in penetration flow paths with either one or two containment isolation valves.  

Licensee Response/NRC Response/NRC Question Closure Id245NRC Question Number CSS-012Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/7/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/7/2014 11:26 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

ITS NRC Questions Id 80 NRC Question Number CSS-013 Category TechnicalITS Section 3.6ITS Number 3.6.3DOC Number A-8JFD Number JFD Bases Number Page Number(s) 102 NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add NameConf Call Requested N NRC Question 1.Page 102, DOC A0 8 states, in part:

CTS 3.6.3 ACTION a, in part, prov ides a required ac tion to isolate one inoperable containment is olation valve in one or more penetration flow paths with tw o containment isolation valves.[Emphasis added]CTS 3.6.3 ACTION f, in part, provides a required action to isolate one inoperable c ontainment isolatio n valve in one or more penetration flow paths of a closed system design. DOC A08 applies only to CTS 3.6.3 ACTION f.Please revise DOC A08 to only reference the applicable CTS section.Page 120, Insert 2 (JFD 6) ITS Condition E, One or more containment vacuum relief isol ation vales inoperabl e is CTS ACTION c.Please explain why the vacuum relief containment isolation valves are not evaluated as a plant-specific application of TSTF-446 CIV Category 1 through 14 containment isolation valves of ITS Condition A.Attach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Page 1of 2 Sequoyah ITS Conversion Databas e 9/25/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=80 Modified By Date Added 5/19/2014 9:58 AMNotification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonLynn MynattLisa RegnerRay SchieleCarl SchultenRoger ScottPage 2of 2 Sequoyah ITS Conversion Databas e 9/25/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=80 Licensee Response/NRC Response/NRC Question Closure Id101 NRC Question Number CSS-013Select Application Licensee Response Attachment 1 Attachment 2 Response Statement In response to CSS-013, part 1, ITS 3.6.3 discussion of change (DOC) A08 discusses the formation of ITS 3.6.3 ACTION A from the combination of parts of CTS 3.6.3 Action a (as it applies to an inoperable containment isolation valve in one or more penetration flow paths with two containment isolation valves) and parts of CTS 3.6.3 Action f (as it applies to one or more penetration flow paths of a closed system with one containment isolation valve inoperable).The parts of CTS 3.6.3 Action a and CTS 3.6.3 Action f that are not combined to form ITS 3.6.3 ACTION A (two or more penetration flow paths with inoperable containment isolation valve), are combined to form ITS 3.6.3 ACTION C. Therefore, ITS 3.6.3 DOC A08 is correct as written.In response to CSS-013, part 2, CTS 3.6.3 Action c was approved April 28, 1995, by license amendments 197 and 188 for SQN Units 1 and 2, respectively. The change clarified the LCO requirements applicable to the dual function of the containment vacuum relief (VR) isolation lines by indicating the actions that would be required should one or more of the VR lines be incapable of performing its containment isolation function or incapable of performing its VR function. More specifically, the change revised CTS 3.6.3, "Containment Isolation Valves," and CTS 3.6.6, "Vacuum Relief Valves," action statements to separate the containment isolation requirements from the vacuum relief requirements.Prior to the license amendment, CTS 3.6.3 Action b would require that an inoperable vacuum relief lines be isolated within 4 hours. Isolation of the line would involve closing the isolation valve and removing electrical power in order to fulfill the isolation requirement. However, this conflicted with CTS 3.6.6, which requires the vacuum relief lines be open for operability of the vacuum relief system.The change to CTS 3.6.3 added an action (Action c) to allow one or more of the containment vacuum relief isolation valves to be inoperable for 72 hours prior to requiring a unit shut down.Therefore, because of the dual function of the containment vacuum relief isolation valves, the CTS 3.6.3 Action and associated completion time for one or more inoperable vacuum relief containment isolation valves has been retained in ITS 3.6.3 ACTION E.Response Date/Time 6/6/2014 6:35 AMClosure Statement Question Closure Date Page 1of 2 Sequoyah ITS Conversion Databas e 9/25/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=101 Licensee Response/NRC Response/NRC Question Closure Id345NRC Question Number CSS-013Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 9/22/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 9/22/2014 3:12 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 9/25/201 4htt p s://members.excelservices.com/rai/index.

ITS NRC Questions Id 81NRC Question Number CSS-014Category Technical ITS Section 3.6 ITS Number 3.6.3DOC Number JFD Number JFD Bases Number 15Page Number(s) 168NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add Name Conf Call Requested NNRC Question 1.Page 168, Bases Insert 6, JFD15, Bases Table 3.6.3-1, Containment Isolation Valve Completion Times.

The Categories in the table under "Pressure Boundary Maintained"and "Pressure Boundary Compromised"are identified using a numerical value between 1 and 14.Please add a key to Table 3.6.3-1 which explains the meaning of each numerical category.Attach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Modified By Date Added 5/19/2014 10:01 AMNotification Scott BowmanKhadijah HemphillAndrew HonLynn MynattLisa RegnerRay Schiele Carl SchultenRoger ScottPage 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=81 Licensee Response/NRC Response/NRC Question Closure Id 192NRC Question Number CSS-014Select Application Licensee ResponseAttachment 1 Attachment 2 Response Statement In response to CSS-014, SQ N has reviewed ITS 3.6.3 Bases Table B 3.6.3-1 and determined that a "table key"to explain the meaning of each numerical category is not required. ITS Table B 3.6.3-1 indicates the relationship between a valve's unique identifier (UNI D) to the associated Penetration number and one of two potential Categories and Completion Times based on the status of the Pressure Boundary.Each containment penetration will have two different categories based on the penetration pressure boundary status. If the pressure boundary status is "maintained,"the numerical category would be 1-7 based on the associated completion times. If the pressure boundary status is "compromised,"then, the numerical category would be 8-14 based on the associated completion times.Therefore, based on the information already provided in ITS Table B 3.6.3-1, no change is required.Response Date/Time 7/17/2014 5:25 AM Closure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonRay SchieleCaroline TiltonAdded By Scott Bowman Date Added 7/17/2014 4:26 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id268NRC Question Number CSS-014Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/20/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/20/2014 9:15 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

p h p?re q uestT yp e=areaItemPrint&itemId=268 ITS NRC Questions Id 82NRC Question Number CSS-015Category TechnicalITS Section 3.6 ITS Number 3.6.4DOC Number A-2JFD Number JFD Bases Number Page Number(s) 235NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add Name Conf Call Requested NNRC Question ITS 3.6.4 Containment Pressure1.Page 235, DOC A02, states CTS 3.6.1.4 in part, states:"Primary containment internal pressure shall be maintained between -0.1 and 0.

3 psig-" ITS 3.6.4 states "Containment pressure shall be  -0.1 and  +0.3 psig." Addi tionally, the title for CTS 3.6.1.4 is "Internal Pressure." The title for ITS 3.6.4 is "Containment Pressure.This changes the CTS by changing the title and changing the LCO statement." 10 CFR 50.36(b), states, in part "The technical specifications shall be derived from the analyses and evaluation included in the safety analysis report, [-].

SQN document S3-01.doc describes in Section 3.1, Conformance with NRC General Design Criteria, Criterion 41 -Containment Atmosphere Cleanup on page 3.1-24 "The Shield Building, surrounding the primary containment , serves as a secondary containment."Table 1.3.1-1 Desi gn comparison with D.C. Cook and Trojan states Sequoyah uses a "freestanding steel primary containment vessel. [Emphasis added]The FSAR shows Sequoyah design includes a primary containment volume and a secondary containment volume.The ISTS contains design information and/or values that are generic to Westinghouse vintage plants.Page 1of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Please verify that the proposed Se quoyah TS are derived from the analyses and evaluation as required under 10 CFR 50.36(b) and that the language used in ITS is consistent with the language in the analysis from whic h the TS is derived. Attach File 1 Attach File 2 Issue Date 5/19/2014 Added By Carl SchultenDate Modified Modified By Date Added 5/19/2014 10:04 AMNotification Scott BowmanMichelle ConnerKhadijah HemphillAndrew Hon Lynn MynattLisa RegnerRay Schiele Carl SchultenRoger ScottPage 2of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id 125NRC Question Number CSS-015 Select Application Licensee ResponseAttachment 1 Attachment 2 Response Statement In response to CSS-015, the following information is provided to describe the Sequoyah Nuclear Plant (SQN) containment design and confirm that the information provided in ITS LCO 3.6.4, Containment Pressure, reflects the design basis of the plant and is consistent with the analyses and language in the updated final safety analysis report (UFSAR) as required by 10 CFR 50.36(b).As described in UFSAR Section 6.2.1, the containment consists of a containment vessel and a separate shield building enclosing the containment vessel and annulus. The containment vessel is a freestanding, welded steel structure that provides primary containment. The shield building is a reinforced concrete structure similar in shape to the containment vessel that protects the containment vessel from external events. The inner steel containment and its penetrations establish the leakage limiting boundary of the containment. Maintaining the containment OPERABLE limits the leakage of fission product radioactivity from the containment to the environment. During a loss of coolant accident, the shield building acts as a secondary

containment enclosure by providing a barrier to airborne, primary containment leakage from air-filled automatic isolating penetrations. The Emergency Gas Treatment System (EGTS) maintains the secondary containment at a negative pressure during the post-accident period. The EGTS also collects and processes the secondary containment atmosphere prior to release to the environment. The EGTS and shield building function to keep out-leakage minimal, but are not factors in determining the design leak rate.Therefore, the proposed ITS containment Specifications accurately describe the SQN containment design, reflect the design basis of the plant, and are consistent with the analyses and language in the updated final safety analysis report (UFSAR) as required by 10 CFR 50.36(b).Response Date/Time 6/17/2014 1:25 PM Closure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonPage 1of 2 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id269NRC Question Number CSS-015Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/20/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/20/2014 9:16 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

ITS NRC Questions Id 83NRC Question Number CSS-016Category Technical ITS Section 3.6 ITS Number 3.6.4 DOC Number LA-1JFD Number JFD Bases Number Page Number(s) 235NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add Name Conf Call Requested NNRC Question 1.Page 235, DOC LA01 in part states:CTS 3.6.1.4 states that the Pr imary containment internal pressure shall be maintained between -0.1 and 0.3 psig relative to the annulus pressure. [Emphasis added]ITS LCO 3.6.4 includes a similar requirement, but does not specify that it is relative to the annulus pressure. [-]this type of information is not necessary to be included in the Technical Specifications to provide adequa te protection of public health and safety.ITS LCO 3.6.4 still provides a requirement to maintain containment pressure within limits.

The Emergency Gas Treat ment System and th e Auxiliary Building Gas Treatment System establish and maintain the air pressure below atmospheric in the Shie ld Building annulus and the Auxiliary Building S econdary Containment Enclosure (ABSCE), respectively to ensure compliance with GDC-41, Containment Atmosphere Cleanup . These systems reduce the concentration of radioactive nuclides in the air released from the annulus and the ABSCE. Please provide discuss ion to show that having TS primary containment internal pressure not referenced to annulus pressure does not result in a change to the SQN licensing basis for meeting GDC-41.The discussion should describe the location of the Page 1of 2 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

pressure sensors used to detect differences between the primary containment gage pressure and annulus gage pressure.Attach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Modified By Date Added 5/19/2014 10:07 AMNotification Scott BowmanKhadijah HemphillAndrew HonLynn MynattLisa RegnerRay SchieleCarl SchultenRoger ScottPage 2of 2 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id 144NRC Question Number CSS-016 Select Application Licensee ResponseAttachment 1 Attachment 1 3.6.4 LCO.pdf (2MB)Attachment 2 Response Statement In response to CSS-016, ITS LCO 3.6.4, on pages 238 and 239 of Enclosure 2, Volume 11, will be revised to reflect that the containment pressure limit values are relative to the annulus pressure.Revisions to ITS 3.6.4 include changes to the CTS 3.6.1.4 markups (pages 233 and 234) to reflect the retention of "relative to the annulus pressure,"deletion of discussion of change (DOC) LA01 (page 235), and addition of "relative to the annulus pressure"to the ISTS 3.6.4 LCO statement. See Attachment 1 for the draft ITS 3.6.4 changes discussed above. Response Date/Time 6/23/2014 1:25 PM Closure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonRay Schiele Carl SchultenAdded By Scott Bowman Date Added 6/23/2014 12:22 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

CONTAINMENT SYSTEMS INTERNAL PRESSURE  LIMITING CONDITION FOR OPERATION 3.6.1.4  Primary containment internal pressure shall be maintained between -0.1 and 0.3 psig relative to the annulus pressure.

:  MODES 1, 2, 3 and 4. 

SEQUOYAH - UNIT 1    3/4 6-9 A01ITS LCO 3.6.4 A pplicability A CTION A A CTION B SR 3.6.4.1 ITS 3.6.4 Page 1 of 2 LA02In accordance with the Surveillance Frequency Control Program LA01 A02CONTAINMENT A02 CONTAINMENT SYSTEMS INTERNAL PRESSURE  LIMITING CONDITION FOR OPERATION 3.6.1.4  Primary containment internal pressure shall be maintained between -0.1 and 0.3 psig relative to the annulus pressure.

: MODES 1, 2. 3 and 4.  

ACTION: With the containment internal pressure outside of the above limits, restore the internal pressure to within the limits within 1 hour or be in at least HOT STANDBY within the next 6 hours and in COLD SHUTDOWN within the following 30 hours.  

SURVEILLANCE REQUIREMENTS 4.6.1.4  The primary containment internal pressure shall be determined to within the specified limits at least once per 12 hours. 

SEQUOYAH - UNIT 2    3/4 6-9 A01ITS LCO 3.6.4 A pplicability A CTION A A CTION B SR 3.6.4.1 ITS 3.6.4 Page 2 of 2 LA02In accordance with the Surveillance Frequency Control Program LA01 A02 A02CONTAINMENT DISCUSSION OF CHANGES ITS 3.6.4, CONTAINMENT PRESSURE Sequoyah Unit 1 and Unit 2 Page 1 of 2 ADMINISTRATIVE CHANGES A01 In the conversion of the Sequoyah Nuclear Plant (SQN) Current Technical Specifications (CTS) to the plant specific Improved Technical Specifications (ITS), certain changes (wording preferences, editorial changes, reformatting, revised numbering, etc.) are made to obtain consistency with NUREG-1431, Rev. 4.0, "Standard Technical Specifications- Westinghouse Plants" (ISTS) and additional Technical Specification Task Force (TSTF) travelers included in this

submittal.  

These changes are designated as administrative changes and are acceptable because they do not result in technical changes to the CTS.  

A02 CTS 3.6.1.4 states, in part, "Primary containment internal pressure shall be maintained between -0.1 and 0.3 psig-"  ITS 3.6.4 states "Containment pressure shall be  -0.1 and  +0.3 psig."  Additionally, the title for CTS 3.6.1.4 is "Internal Pressure."  The title for ITS 3.6.4 is "Containment Pressure."  This changes the CTS by changing the title and changing the LCO statement.

LA01 CTS 3.6.1.4 states that the Primary containment internal pressure shall be maintained between -0.1 and 0.3 psig relative to the annulus pressure.

ITS LCO 3.6.4 includes a similar requirement, but does not specify that it is relative to the annulus pressure. This changes the CTS by moving the detail that the containment pressure limits are relative to the annulus pressure to the Bases.  

The removal of this detail, which is related to system design, from the CTS is acceptable because this type of information is not necessary to be included in the Technical Specifications to provide adequate protection of public health and safety. ITS LCO 3.6.4 still provides a requirement to maintain containment pressure within limits. Also, this change is acceptable because these types of details will be adequately controlled in the ITS Bases. Changes to the Bases are controlled by the Technical Specification Bases Control Program in Chapter 5. This program provides for the evaluation of changes to ensure the Bases are DISCUSSION OF CHANGES ITS 3.6.4, CONTAINMENT PRESSURE Sequoyah Unit 1 and Unit 2 Page 2 of 2 properly controlled. This change is designated as a less restrictive removal of detail change because information relating to system design is being removed from the CTS.  

LA02 CTS 4.6.1.4 requires the primary containment internal pressure to be determined to be within limits at least once per 12 hours. ITS SR 3.6.4.1 requires a similar Surveillance, but specifies the periodic Frequency as "In accordance with the Surveillance Frequency Control Program."  This changes the CTS by moving the specified Frequencies for the SRs to the Surveillance Frequency Control Program.

The removal of these details related to Surveillance Requirement Frequencies from the Technical Specifications is acceptable, because this type of information is not necessary to be included in the Technical Specifications to provide adequate protection of public health and safety. The existing Surveillance Frequencies are removed from Technical Specifications and placed under licensee control pursuant to the methodology described in NEI 04-10. A new program (Surveillance Frequency Control Program) is being added to the Administrative Controls section of the Technical Specifications describing the control of Surveillance Frequencies. The surveillance test requirements remain in the Technical Specifications. The control of changes to the Surveillance Frequencies will be in accordance with the Surveillance Frequency Control Program. The Program shall ensure that Surveillance Requirements specified in the Technical Specifications are performed at intervals sufficient to assure the associated Limiting Conditions for Operation are met. This change is designated as a less restrictive removal of detail change, because the Surveillance Frequencies are being removed from the Technical Specifications.  

3.6.4 A Containment Pressure (Atmospheric, Dual, and Ice Condenser)

LCO  3.6.4 A  Containment pressure shall be  [-0.3] psig and  [+1.5] psig.  

A.1 Restore containment pressure to within limits.  

1 hour  B. Required Action and associated Completion Time not met.  

B.1 Be in MODE 3.  

AND B.2 Be in MODE 5.

6 hours

SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY SR 3.6.4 A.1 Verify containment pressure is within limits.  

[ 12 hours  OR In accordance  

with the Surveillance  

]    3.6.1.4 1 3 1 4 4 A pplicability A CTION A CTION 4.6.1.4 10.3 Containment Pressure (Atmospheric, Dual, and Ice Condenser) 3.6.4 A    Westinghouse STS 3.6.4 A-1 Rev. 4.0    CTS 1 2 1SEQUOYAH UNIT 2 Amendment XXX 3.6  CONTAINMENT SYSTEMS

LCO  3.6.4 A  Containment pressure shall be  [-0.3] psig and  [+1.5] psig.  

APPLICABILITY: MODES 1, 2, 3, and 4.  

ACTIONS  CONDITION REQUIRED ACTION COMPLETION TIME A. Containment pressure not within limits.  

A.1 Restore containment pressure to within limits.

1 hour  B. Required Action and associated Completion Time not met.  

B.1 Be in MODE 3.  

AND B.2 Be in MODE 5.  

SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY SR  3.6.4 A.1 Verify containment pressure is within limits.  

]    3.6.1.4 1 3 1 4 4 A pplicability A CTION A CTION 4.6.1.4 10.3 Licensee Response/NRC Response/NRC Question Closure Id276NRC Question Number CSS-016Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/21/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/21/2014 8:12 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

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ITS NRC Questions Id 84NRC Question Number CSS-017Category FYIITS Section 3.6ITS Number 3.6.5DOC Number JFD Number JFD Bases Number Page Number(s) NRC Reviewer Supervisor SelectTechnical Branch POC Add NameConf Call Requested NNRC Question No RAIsAttach File 1 Attach File 2 Issue Date 5/19/2014Added By Carl SchultenDate Modified Modified By Date Added 5/19/2014 10:08 AMNotification Scott BowmanKhadijah HemphillAndrew Hon Lynn MynattLisa RegnerRay Schiele Carl SchultenRoger ScottPage 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id225NRC Question Number CSS-017Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/4/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/4/2014 4:15 PMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/20/201 4htt p s://members.excelservices.com/rai/index.

thanthec o ntainmentdesi g n pressure.Themaximum peakcontainment ITS NRC Questions Id112 NRC Question Number CSS-018Category TechnicalITS Section 3.6ITS Number 3.6.6 DOC Number JFD Number JFD Bases Number 2Page Number(s) 306 NRC Reviewer Supervisor Rob ElliottTechnical Branch POC Add NameConf Call Requested N NRC Question 1.Page 306, JFD 2, 2 nd paragraph of Applicable Safety Analyses (ASA).This paragraph (as shown below) states the maximum containment atmosphere temperature results from the DBA SLB analysis.JFD 2 deletes ISTS ASA bases not in brackets (with the exception of the statement "[for a few seconds]") that discuss the basis of the containment design temperature. Please provide Sequoyah-specific ASA bases for the containment design temperature in an equivalent level of detail to the deleted ISTS Bases discussion.TheDBAanalysesshowthatthemaximumpeakcontainmentpressureof

[44.1]psigresultsfromtheLOCAanalysis,andiscalculatedtobele satmospheretemperatureof[385]°FresultsfromtheSLBanalysis a nwascalcula tedtoexceedthecontainmentdesigntemperature[forafewseconds]d uringtheDBASLB.Thebasisofthecontainmentdesigntemperature,however,istoensure theOPERABILITYofsa fetyrelatedequipmentinsidecont ainment(Ref.3).Thermalanalysess howedtha tthetimeintervalduringwhichthec ontainmentatmospheretemperatureexceedthecontainmentdesigntemperaturewasshorteno ughthat tequipmentsurfacetemperaturesr emainedbelowthedesi gntemperature.Therefore,itisconclud edthatthec alculatedtra nsientcont ai nm eatmospheretemperaturesareaccep tablefortheDBASL B.Attach File 1 Attach File 2 Issue Date 5/30/2014Added By Carl SchultenDate Modified Modified By Date Added 5/30/2014 2:32 PMNotification Khadijah HemphillAndrew Hon Lynn MynattLisa RegnerRay Schiele Carl Schulten Roger ScottPage 1of 1 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

Licensee Response/NRC Response/NRC Question Closure Id135 NRC Question Number CSS-018Select Application Licensee ResponseAttachment 1 Attachment 1 3.6.6 ASA revision.pdf (3MB)Attachment 2 Response Statement In response to CSS-018, ITS 3.6.6 Bases Applicable Safety Analysis (ASA) Section on pages 306 and 317 of Enclosure 2, Volume 11, will be revised to provide a Sequoyah-specific discussion that reflects the peak calculated containment temperature and its relationship to the design containment temperature.

Specifically, the second paragraph of the ASA Section will be revised to read, in part, "The basis of the containment design temperature (327°F) is to ensure the OPERABILITY of safety related equipment inside containment (Ref. 3).The maximum peak containment atmosphere temperature of 325.6°F results from the SLB analysis.Therefore, the calculated peak containment atmosphere temperature is acceptable for the DBA SLB."See Attachment 1 for the draft revised ITS 3.6.6 Bases change discussed above.Response Date/Time 6/20/2014 5:15 AM Closure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonRay SchieleCarl SchultenAdded By Scott Bowman Date Added 6/20/2014 4:16 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

B 3.6.6 C    Westinghouse STS B 3.6.6 C-3 Rev. 4.0  1 2Revision XXX SEQUOYAH UNIT 1 1BASES

The DBA analyses show that the maximum peak containment pressure of  

[44.1] psig results from the LOCA analysis, and is calculated to be less than the containment design pressure. The maximum peak containment atmosphere temperature of

[385]°F results from the SLB analysis and was calculated to exceed the containment design temperature [for a few seconds] during the DBA SLB. The basis of the containment design temperature, however, is to ensure the OPERABILITY of safety related equipment inside containment (Ref. 3). Thermal analyses showed that the time interval during which the containment atmosphere temperature exceed the containment design temperature was short enough that the equipment surface temperatures remained below the design temperature.

Therefore, it is concluded that the calculated transient containment atmosphere temperatures are acceptable for the DBA SLB

.

The modeled Containment Spray System actuation from the containment analysis is based on a response time associated with exceeding the containment High-3 pressure signal setpoint to achieving full flow through the containment spray nozzles. A delayed response time initiation 11.33 325.6 4 2High - High

===2.2 2trainstrain===

an ARS fan Containment Spray System (Ice Condenser)

B 3.6.6 C    Westinghouse STS B 3.6.6 C-3 Rev. 4.0  1 2Revision XXX SEQUOYAH UNIT 2 1BASES

The operation of the Containment Spray System, together with 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 serves 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.  

APPLICABLE The limiting DBAs considered relative to containment OPERABILITY are SAFETY  the loss of coolant accident (LOCA) and the steam line break (SLB). The ANALYSES 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  

The modeled Containment Spray System actuation from the containment analysis is based on a response time associated with exceeding the containment High-3 pressure signal setpoint to achieving full flow through the containment spray nozzles. A delayed response time initiation 11.33 325.6 4 2High - High

===2.2 2trainstrain===

an ARS fan Licensee Response/NRC Response/NRC Question Closure Id277NRC Question Number CSS-018Select Application NRC Question ClosureAttachment 1 Attachment 2 Response Statement Response Date/Time Closure Statement This question is closed and no further information is required at this time to draft the Safety Evaluation.Question Closure Date 8/21/2014Notification Scott Bowman Michelle ConnerKhadijah HemphillAndrew HonLynn MynattRay SchieleRoger ScottAdded By Caroline Tilton Date Added 8/21/2014 8:14 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/21/201 4htt p s://members.excelservices.com/rai/index.

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Licensee Response/NRC Response/NRC Question Closure Id217NRC Question Number CSS-019 Select Application Licensee Response Attachment 1 Attachment 1 3.6.7 DOC M01.pdf (25KB)Attachment 2 Response Statement In response to CSS-019, ITS 3.6.7 discussion of change (DOC) M01, on page 338 of Enclosure 2, Volume 8, will be revised to include the basis for the stated Frequencies for ITS SR 3.6.7.1 and ITS SR 3.6.7.2.Concerning SR 3.6.7.1, a sentence will be added to DOC M01 to state, "The 12 hour Frequency is based on industry operating experience related to shield building annulus pressure variations and pressure instrument drift during the applicable MODES."For SR 3.6.7.2, a sentence will be added to DOC M01 to state, "The 31 day Frequency is based on engineering judgment and is considered adequate in view of other indications of door status available to the operator."See Attachment 1 for the draft revised ITS 3.6.7 DOC M01.Response Date/Time 7/31/2014 12:10 PMClosure Statement Question Closure Date Notification Scott BowmanMichelle ConnerKhadijah HemphillAndrew HonRay SchieleCaroline Tilton Added By Scott BowmanDate Added 7/31/2014 11:06 AMDate Modified Modified By Page 1of 1 Sequoyah ITS Conversion Databas e 8/22/201 4htt p s://members.excelservices.com/rai/index.

submittal.  

These changes are designated as administrative changes and are acceptable because they do not result in technical changes to the CTS.  

A02 CTS 3.6.1.7 does not provide an ACTION to take if the shield building is inoperable while in MODE 1, 2, 3, or 4; it only includes a requirement that the shield building be restored to OPERABLE status prior to increasing Reactor Coolant System temperature above 200°F (i.e., MODE 4). Therefore, entry into CTS 3.0.3 is required if CTS 3.6.1.7 is not met while in MODE 1, 2, 3, or 4. CTS 3.0.3 requires action to be initiated within 1 hour to prepare for a shutdown and requires the unit to be in MODE 3 within 7 hours and MODE 5 within 37 hours. When the shield building is inoperable and not restored to an OPERABLE status within the specified Completion Time (see DOC L01), ITS 3.6.7 ACTION B requires the unit be in MODE 3 within 6 hours and MODE 5 within 36 hours. This changes the CTS by stating the ACTIONS within the Specification rather than deferring to CTS 3.0.3. In addition, it deletes the Action to restore the LCO prior to entering MODE 4.

The purpose of CTS 3.0.3 is to place the unit outside the MODE of Applicability within a reasonable amount of time in a controlled manner. CTS 3.6.1.7 is silent on these actions, deferring to CTS 3.0.3 for the actions. This change is acceptable because the ACTIONS specified in ITS 3.6.7 adopt ISTS structure for placing the unit outside the MODE of Applicability without changing the time specified to enter MODE 3 and MODE 5. In addition, deletion of the current Action of CTS 3.6.1.7 is acceptable because CTS 3.0.4 (ITS LCO 3.0.4) already precludes entering the MODE of Applicability when the LCO is not met.

Therefore, it is not necessary to include these requirements as specific actions in ITS 3.6.7. This change is designated as administrative, because it does not result in technical changes to the CTS.  

M01 ITS SR 3.6.7.1 requires verification that annulus negative pressure is greater than 5 inches water gauge every 12 hours. ITS SR 3.6.7.2 requires verification that the shield building access door in each access opening is closed every 31 days. CTS 3.6.1.7 does not contain these Surveillance Requirements. This changes the CTS by adding new Surveillance Requirements to verify annulus negative pressure is within limits and to verify the shield building access door in each access opening is closed.  (See DOC LA03 for moving the "12 hour" and "31 day" Frequencies for these Surveillance Requirements to the Surveillance Frequency Control Program.)

DISCUSSION OF CHANGES ITS 3.6.7, SHIELD BUILDING Sequoyah Unit 1 and Unit 2 Page 2 of 5 The shield building surrounds the containment vessel and forms an annulus between the containment vessel and the inner wall of the shield building. This annular space collects containment leakage that may occur following a loss of coolant accident. A negative pressure is maintained in the annulus between the shield building and the steel containment vessel by the Emergency Gas Treatment System (EGTS). The release of radioactive contaminants to the environment is controlled via filters in the EGTS trains. The purpose of CTS 3.6.1.7 is to ensure the shield building is OPERABLE in MODES 1, 2, 3, and 4 to ensure the release of radioactive material from the containment atmosphere is restricted to the leakage paths assumed in the accident analysis.

Since shield building access door position and annulus pressure are integral to shield building OPERABILITY, ITS 3.6.7 adds a specific Surveillance Requirement (ITS SR 3.6.7.1) to verify every 12 hours that annulus negative pressure is within the limit assumed in the containment analysis. Additionally, a specific Surveillance Requirement (ITS SR 3.6.7.2) is added to verify every 31 days that the door in each access opening is closed, so that the shield building boundary is not breached at any time when the shield building boundary is required. This change is designated as more restrictive because new Surveillance Requirements have been added to ensure the shield building OPERABILITY is maintained.  

REMOVED DETAIL CHANGES LA01 CTS 3.6.1.7 requires that the structural integrity of the shield building be maintained at a level consistent with the acceptance criteria in CTS 4.6.1.7. CTS 4.6.1.7 requires the structural integrity of the shield building to be determined by a visual inspection of the exposed shield building interior and exterior surfaces and verifying no apparent changes in concrete surface appearance or other abnormal degradation. ITS LCO 3.6.7 requires the shield building to be OPERABLE. This changes the CTS by moving the detail of what constitutes shield building OPERABILITY to the Bases.