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License Amendment Request to Revise Operability Requirements and Actions for RCS Leakage Instrumentation
	ML110970066
Person / Time
Site:	Limerick
Issue date:	04/06/2011
From:	David Helker; Exelon Generation Co, Exelon Nuclear
To:	; Document Control Desk, Office of Nuclear Reactor Regulation
References
	Download: ML110970066 (28)
	v • d • e

{{#Wiki_filter:Exeen 10 CFR 50.90 April 6, 2011 U.S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, DC 20555-0001 Limerick Generating Station, Units 1 and 2 Facility Operating License Nos. NPF-39 and NPF-85 USNRC Docket Nos. 50-352 and 50-353

Subject:

License Amendment Request to Revise Operability Requirements and Actions for RCS Leakage Instrumentation

References:

1. TSTF-514-A, Revision 3, Revised BWR Operability Requirements and Actions tor RCS Leakage Instrumentation, dated November 24, 2010. 2. Notice of Availability of the Models for Plant-Specific Adoption of Technical Specifications Task Force Traveler TSTF514, Revision 3, Revise BWR Operability Requirements and Actions for RCS Leakage Instrumentation, dated December 17, 2010. In accordance with 10 CFR 50.90, Application for amendment of license, construction permit, or early site permit, Exelon Generation Company, LLC (EGC) requests an amendment to the Technical Specifications (TS) for Limerick Generating Station (LGS), Units 1 and 2. The proposed amendment modifies the Actions to be taken when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems. The modified Actions require additional, more frequent monitoring of other indications of Reactor Coolant System (RCS) leakage and provide appropriate time to restore another monitoring system to Operable status. This change is consistent with the U.S. Nuclear Regulatory Commission (USNRC) approved Safety Evaluation on Technical Specification Task Force (TSTF) Traveler, TSTF-514-A, Revision 3, Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation dated November 24, 2010 (Reference 1), as made available in the Federal Register on December 17, 2010 (Reference 2). of this submittal provides a description of the proposed changes, the requested confirmation of applicability, plant specific verifications, and variations in the proposed LGS TS changes from the approved TSTF-514-A (Reference 1). Affachment 2 provides the existing TS page markups showing the proposed changes. Attachment 3 provides the associated TS Bases markups for information only. The proposed changes have been reviewed by the LGS Plant Operations Review Committee and approved by the Nuclear Safety Review Board in accordance with the requirements of the EGC Quality Assurance Program. 10 CFR 50.90 April 6, 2011 U.S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, DC 20555-0001 Limerick Generating Station, Units 1 and 2 Facility Operating License Nos. NPF-39 and NPF-85 USNRC Docket Nos. 50-352 and 50-353

Subject:

License Amendment Request to Revise Operability Requirements and Actions for RCS Leakage Instrumentation

References:

1. TSTF-514-A, Revision 3, "Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation", dated November 24,2010. 2. Notice of Availability of the Models for Plant-Specific Adoption of Technical Specifications Task Force Traveler TSTF-514, Revision 3, "Revise BWR Operability Requirements and Actions for RCS Leakage Instrumentation," dated December 17, 2010. In accordance with 10 CFR 50.90, "Application for amendment of license, construction permit, or early site permit," Exelon Generation Company, LLC (EGC) requests an amendment to the Technical Specifications (TS) for Limerick Generating Station (LGS), Units 1 and 2. The proposed amendment modifies the Actions to be taken when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems. The modified Actions require additional, more frequent monitoring of other indications of Reactor Coolant System (RCS) leakage and provide appropriate time to restore another monitoring system to Operable status. This change is consistent with the U.S. Nuclear Regulatory Commission (USNRC) approved Safety Evaluation on Technical Specification Task Force (TSTF) Traveler, TSTF-514-A, Revision 3, "Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation" dated November 24, 2010 (Reference 1), as made available in the Federal Register on December 17, 2010 (Reference 2). of this submittal provides a description of the proposed changes, the requested confirmation of applicability, plant specific verifications, and variations in the proposed LGS TS changes from the approved TSTF-514-A (Reference 1). Attachment 2 provides the existing TS page markups showing the proposed changes. Attachment 3 provides the associated TS Bases markups for information only. The proposed changes have been reviewed by the LGS Plant Operations Review Committee and approved by the Nuclear Safety Review Board in accordance with the requirements of the EGC Quality Assurance Program.

U.S. Nuclear Regulatory Commission April 6, 201 1 Page 2 EGC requests approval of the proposed amendment by April 6, 2012. Once approved, the amendment shall be implemented within 60 days. There are no regulatory commitments contained in this letter. In accordance with 10 CFR 50.91, Notice for public comment; State consultation, paragraph (b), EGC is notifying the Commonwealth of Pennsylvania of this application for license amendment by transmitting a copy of this letter and its attachments to the designated State Official. Should you have any questions concerning this letter, please contact Ms. Wendy E. Croft at (610) 765-5726. I declare under penalty of perjury that the foregoing is true and correct. Executed on the 6th day of April 2011. Respectfully, 97 W. David P. Helker Manager, Licensing and Regulatory Affairs Exelon Generation Company, LLC Attachments: 1. Evaluation of Proposed Changes 2. Markup of Technical Specifications Pages 3. Markup of Technical Specifications Bases Pages (For Information Only) cc: USNRC Region I, Regional Administrator USNRC Senior Resident Inspector, LGS USNRC Project Manager, LGS R. A. Janati, Bureau of Radiation Protection U.S. Nuclear Regulatory Commission April 6, 2011 Page 2 EGC requests approval of the proposed amendment by April 6, 2012. Once approved, the amendment shall be.implemented within 60 days. There are no regulatory commitments contained in this letter. In accordance with 10 CFR 50.91, "Notice for public comment; State consultation," paragraph (b), EGC is notifying the Commonwealth of Pennsylvania of this application for license amendment by transmitting a copy of this letter and its attachments to the designated State Official. Should you have any questions concerning this letter, please contact Ms. Wendy E. Croft at (610) 765-5726. I declare under penalty of perjury that the foregoing is true and correct. Executed on the 6th day of April 2011. Respectfully, David P. Helker Manager, Licensing and Regulatory Affairs Exelon Generation Company, LLC Attachments: 1. 2. 3. Evaluation of Proposed Changes Markup of Technical Specifications Pages Markup of Technical Specifications Bases Pages (For Information Only) cc: USNRC Region I, Regional Administrator USNRC Senior Resident Inspector, LGS USNRC Project Manager, LGS R. R. Janati, Bureau of Radiation Protection

ATTACHMENT I Evaluation of Proposed Changes Limerick Generating Station, Units I and 2 Facility Operating License Nos. NPF-39 and NPF-85 ATTACHMENT 1 Evaluation of Proposed Changes Limerick Generating Station, Units 1 and 2 Facility Operating License Nos. NPF-39 and NPF-85

Subject:

Revise Operability Requirements and Actions for RCS Leakage Instrumentation 1.0

SUMMARY

DESCRIPTION 2,0 DETAILED DESCRIPTION

3.0 TECHNICAL EVALUATION

4.0 REGULATORY EVALUATION

4.1 Applicable Regulatory Requirements/Criteria 4.2 Precedent 4.3 No Significant Hazards Consideration 4.4 Conclusions

5.0 ENVIRONMENTAL CONSIDERATION

6.0 REFERENCES

Subject:

Revise Operability Requirements and Actions for RCS Leakage Instrumentation 1.0

SUMMARY

DESCRIPTION 2.0 DETAILED DESCRIPTION

3.0 TECHNICAL EVALUATION

4.0 REGULATORY EVALUATION

4.1 Applicable Regulatory Requirements/Criteria 4.2 Precedent 4.3 No Significant Hazards Consideration 4.4 Conclusions

5.0 ENVIRONMENTAL CONSIDERATION

6.0 REFERENCES

Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 1 of 5 1.0

SUMMARY

DESCRIPTION This evaluation supports a request to amend Operating Licenses NPF-39 and NPF-85 for Limerick Generating Station (LGS) Units 1 and 2, respectively. The proposed changes would revise the Operating Licenses to modify the Actions to be taken when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems. The modified Actions require additional, more frequent monitoring of other Reactor Coolant System (RCS) leakage indications and provide appropriate time to restore another monitoring system to Operable status. This change is consistent with the U.S. Nuclear Regulatory Commission (USNRC) approved Safety Evaluation on Technical Specification Task Force (TSTF) Traveler, TSTF-514-A, Revision 3, Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation dated November 24, 2010 (Reference 6.1), as referenced in the Federal Register Notice of Availability on December 17, 2010 (Reference 6.2). Variations from the USNRC-approved TSTF-514-A, Revision 3 are detailed in Section 3.0 of this submiffal. 2.0 DETAILED DESCRIPTION The background for this application is stated in the referenced model safety evaluation in the USNRCs Federal Register Notice of Availability published on December 17, 2010 and TSTF 514-A, Revision 3, Consistent with NRC-approved TSTF-5 14-A, Revision 3 the proposed changes are as follows: Technical Specification (TS) Limiting Condition for Operability (LCO) 3.4.3.1, Leakage Detection Systems is revised to add a new Action. The new Action, TS 3.4.3.1 Action F, is applicable when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems (i.e., all other monitoring systems are inoperable). The new Action requires analyzing grab samples of the primary containment atmosphere and monitoring RCS leakage using administrative means every 12 hours in addition to restoring another monitoring system to Operable status within 7 days. The TS Bases are revised to clearly define the RCS leakage detection instrumentation Operability requirements in the LCO Bases and to eliminate discussion from the TS Bases that could be erroneously construed as Operability requirements. The TS Bases are also revised to reflect the changes to the Technical Specifications and to more accurately reflect the existing TS. NOTE: Proposed revisions to the TS Bases are also included in this application for information only. The changes to the affected TS Bases pages will be incorporated in accordance with the TS Bases Control Program. Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 1 of 5 1.0

SUMMARY

DESCRIPTION This evaluation supports a to amend Operating Licenses NPF-39 and NPF-85 for Limerick Generating Station (LGS) Units 1 and 2, respectively. The proposed changes would the Operating Licenses to modify the Actions to be taken when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems. The modified Actions require additional, more frequent monitoring of other Reactor Coolant System (RCS) leakage indications and provide appropriate time to restore another monitoring system to Operable status. This change is consistent with the U.S. Nuclear Regulatory Commission (USNRC) approved Safety Evaluation on Technical Specification Task Force (TSTF) Traveler, TSTF-514-A, Revision 3, "Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation" dated November 24, 2010 (Reference 6.1), as referenced in the Federal Register Notice of Availability on December 17, 2010 (Reference 6.2). Variations from the USNRC-approved TSTF-514-A, Revision 3 are detailed in Section 3.0 of this submittal. 2.0 DETAILED DESCRIPTION The background for this application is stated in the referenced model safety evaluation in the USNRC's Federal Register Notice of Availability published on December 17, 2010 and TSTF-514-A, Revision 3. Consistent with NRC-approved TSTF-514-A, Revision 3 the proposed changes are as follows: Technical Specification (TS) Limiting Condition for Operability (LCO) 3.4.3.1, "Leakage Detection Systems" is revised to add a new Action. The new Action, TS 3.4.3.1 Action F, is applicable when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems (Le., all other monitoring systems are inoperable). The new Action requires analyzing grab samples of the primary containment atmosphere and monitoring RCS leakage using administrative means every 12 hours in addition to restoring another monitoring system to Operable status within 7 days. The TS Bases are revised to clearly define the RCS leakage detection instrumentation Operability requirements in the LCO Bases and to eliminate discussion from the TS Bases that could be erroneously construed as Operability requirements. The TS Bases are also revised to reflect the changes to the Technical Specifications and to more accurately reflect the existing TS. NOTE: Proposed revisions to the TS Bases are also included in this application for information only. The changes to the affected TS Bases pages will be incorporated in accordance with the TS Bases Control Program.

Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 2 of 5

3.0 TECHNICAL EVALUATION

Exelon Generation Company, LLC, (EGC) has reviewed the Federal Register Notice of Availability dated December 17, 2010. This review also included the referenced information provided in TSTF5 14-A, Revision 3. EGC has concluded that the justifications presented in the TSTF proposal and the Federal Register Notice of Availability prepared by the USNRC staff are applicable to LGS, Units 1 and 2 with the variations noted below, and justify this amendment for the incorporation of the changes to the corresponding TS. Additional reviews have determined that the proposed changes do not require any exemption or relief from regulatory requirements other than the TS, and do not affect conformance to any General Design Criteria differently than described in the Updated Final Safety Analysis Report (UFSAR). LGS Units 1 and 2 are Standard TS plants and differ from the BWR/4 Improved Standard Technical Specifications (ISTS) used as the TS reference/markup in TSTF-514-A, Revision 3. A list is provided below of the variations in the proposed LGS TS changes from the approved TSTF-514-A, Revision 3: Based on the addition of the proposed LGS TS 3.4.3.1 Action F the currentTS 3.4.3.1 Action F has been renumbered to TS 3.4.3.1 Action G. The change is consistent with the approved TSTF-5 14-A, Revision 3 intent and aligns with the current LGS TS. a In order to remain consistent with the current LGS TS 3.4.3.1 Action E, the proposed LGS TS 3.4.3.1 Action F was modified for LGS to require two operable TS LCO monitoring systems (the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system), as opposed to the single operable TS LCO monitoring system proposed by TSTF-5 14-A, Revision 3 Condition [D]. This change is more conservative than the TSTF-5 14-A, Revision 3 proposal and aligns with the current LGS TS. The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) requires HOT SHUTDOWN within 12 hours if two or more leakage detection instruments are inoperable with the exception of TS 3.4.3.1 Action E. TS 3.4.3.1 Action E allows two inoperable monitoring systems (the primary containment atmosphere gaseous radioactivity monitoring system and the drywell unit coolers condensate flow rate monitoring system) for 30 days with 12 hour compensatory grab samples. The proposed LGS TS 3.4.3.1 Action F allows two inoperable monitoring systems (the drywell floor drain sump flow monitoring system and the drywell unit coolers condensate flow rate monitoring system) for 7 days with 12 hour compensatory grab samples of the primary containment atmosphere and 12 hour administrative monitoring of RCS leakage. A review of past operating experience from 1/1/2006 to 2/9/20 1 1 at LGS Units 1 and 2 identified that the proposed Action F would have been entered three times for a total of 6 hours and 34 minutes. Although the proposed change to the LGS TS is an increase in the amount of time the plant is allowed to operate with the drywell floor drain sump flow monitoring system and the drywell unit coolers condensate flow rate monitoring system inoperable, the proposed Action F is more conservative than TS 3.4.3.1 Action E, is consistent with the approved TSTF-5 14-A, Revision 3 intent, and has operating experience to suggest it will be an infrequently entered Action statement. Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 2 of 5

3.0 TECHNICAL EVALUATION

Exelon Generation Company, LLC, (EGC) has reviewed the Federal Register Notice of Availability dated December 17, 2010. This review also included the referenced information provided in TSTF-514-A, Revision 3. EGC has concluded that the justifications presented in the TSTF proposal and the Federal Register Notice of Availability prepared by the USNRC staff are applicable to LGS, Units 1 and 2 with the variations noted below, and justify this amendment for the incorporation of the changes to the corresponding TS. Additional reviews have determined that the proposed changes do not require any exemption or relief from regulatory requirements other than the TS, and do not affect conformance to any General Design Criteria differently than described in the Updated Final Safety Analysis Report (UFSAR). LGS Units 1 and 2 are Standard TS plants and differ from the BWR/4 Improved Standard Technical Specifications (ISTS) used as the TS reference/markup in TSTF-514-A, Revision 3. A list is provided below of the variations in the proposed LGS TS changes from the approved TSTF-514-A, Revision 3: Based on the addition of the proposed LGS TS 3.4.3.1 Action F the current TS 3.4.3.1 Action F has been renumbered to TS 3.4.3.1 Action G. The change is consistent with the approved TSTF-514-A, Revision 3 intent and aligns with the current LGS TS. In order to remain consistent with the current LGS TS 3.4.3.1 Action the proposed LGS TS 3.4.3.1 Action F was modified for LGS to require two operable TS LCO monitoring systems (the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system), as opposed to the single operable TS LCO monitoring system proposed by TSTF-514-A, Revision 3 Condition [0]. This change is more conservative than the TSTF-514-A, Revision 3 proposal and aligns with the current LGS TS. The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) requires HOT SHUTDOWN within 12 hours if two or more leakage detection instruments are inoperable with the exception of TS 3.4.3.1 Action E. TS 3.4.3.1 Action E allows two inoperable monitoring systems (the primary containment atmosphere gaseous radioactivity monitoring system and the drywell unit coolers condensate flow rate monitoring system) for 30 days with 12 hour compensatory grab samples. The proposed LGS TS 3.4.3.1 Action F allows two inoperable monitoring systems (the drywell floor drain sump flow monitoring system and the drywell unit coolers condensate flow rate monitoring system) for 7 days with 12 hour compensatory grab samples of the primary containment atmosphere and 12 hour administrative monitoring of RCS leakage. A review of past operating experience from 1/1/2006 to 2/9/2011 at LGS Units 1 and 2 identified that the proposed Action F would have been entered three times for a total of 6 hours and 34 minutes. Although the proposed change to the LGS TS is an increase in the amount of time the plant is allowed to operate with the drywell floor drain sump flow monitoring system and the drywell unit coolers condensate flow rate monitoring system inoperable, the proposed Action F is more conservative than TS 3.4.3.1 Action E, is consistent with the approved TSTF-514-A, Revision 3 intent, and has operating experience to suggest it will be an infrequently entered Action statement.

Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page3of5 The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) requires HOT SHUTDOWN within 12 hours if two or more leakage detection instruments are inoperable with the exception of TS 3.4.3.1 Action E. The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) is being modified to include the exception of the proposed LGS TS 3.4.3.1 Action F. The change is consistent with the approved TSTF-5 14-A, Revision 3 intent and aligns with the current LGS TS. The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) requires HOT SHUTDOWN within 12 hours if the associated Completion Time of Actions A, B, C, D or E are not met. The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) is being modified to include proposed LGS TS 3.4.3.1 Action F. The change is consistent with the approved TSTF-5 14-A, Revision 3 intent and aligns with the current LGS TS. The proposed LGS TS Bases have been edited from the TSTF-514-A, Revision 3 Bases changes to reflect the specific LGS configuration and any variations from TSTF-5 14-A, Revision 3 described above and to correct previously existing typographical errors. These changes to the TSTF-5 14-A, Revision 3 for the LGS submittal have been evaluated in the LGS-specific No Significant Hazards Consideration Determination in Section 4.3. The only variations or deviations in EGCs proposal have been delineated above. The remainder of the EGC proposed changes are consistent with the TS changes described in the Federal Register Notice of Availability dated December 17, 2010 or the referenced information provided in TSTF514-A, Revision 3.

4.0 REGULATORY EVALUATION

4.1 Aplicable Regulatory Requirements / Criteria A description of the proposed changes and their relationship to applicable regulatory requirements and guidance was provided in the December 17, 2010, Federal Register Notice of Availability referenced information in TSTF514-A, Revision 3. 4.2 Precedent This change is consistent with the U.S. Nuclear Regulatory Commission (USNRC) approved Safety Evaluation on Technical Specification Task Force (TSTF) Traveler, TSTF-514-A, Revision 3, Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation dated November 24, 2010 , as referenced in the Federal Register Notice of Availability on December 17, 2010. 4.3 No Significant Hazards Consideration Determination In accordance with 10 CFR 50.90, Application for amendment of license, construction permit, or early site permit, Exelon Generation Company, LLC (EGC) requests an amendment to the Technical Specifications (TS) for Limerick Generating Station, Units 1 and 2. The proposed amendment modifies the Actions to be taken when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems. The modified Actions require additional, more frequent monitoring of other Reactor Coolant Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 3 of 5 The current LGS TS 3.4.3.1 Action F (proposed 3.4.3.1 Action G) requires HOT SHUTDOWN within 12 hours if two or more leakage detection instruments are inoperable with the exception of TS 3.4.3.1 Action current 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) is being modified to include the exception of the proposed LGS TS 3.4.3.1 Action F. The change is consistent with the approved TSTF-514-A, Revision 3 intent and aligns with the current The current LGS TS 3.4.3.1 Action F (proposed 3.4.3.1 Action G) requires HOT SHUTDOWN within 12 hours if the associated Completion Time of Actions A, B, C, D or E are not met. The current LGS TS 3.4.3.1 Action F (proposed TS 3.4.3.1 Action G) is being modified to include proposed LGS TS 3.4.3.1 Action F. The change is consistent with the approved TSTF-514-A, Revision 3 intent and aligns with the current LGS TS. The proposed LGS TS Bases have been edited from the TSTF-514-A, Revision 3 Bases changes to reflect the specific LGS configuration and any variations from TSTF-514-A, Revision 3 described above and to correct previously existing typographical errors. These changes to the TSTF-514-A, Revision 3 for the LGS submittal have been evaluated in the LGS-specific No Significant Hazards Consideration Determination in Section 4.3. The only variations or deviations in EGC's proposal have been delineated above. The remainder of the EGC proposed changes are consistent with the TS changes described in the Federal Register Notice of Availability dated December 17, 2010 or the referenced information provided in TSTF-514-A, Revision 3.

4.0 REGULATORY EVALUATION

4.1 Applicable Regulatory Requirements / Criteria A description of the proposed changes and their relationship to applicable regulatory requirements and guidance was provided in the December 17, 2010, Federal Register Notice of Availability referenced information in TSTF-514-A, Revision 3. 4.2 Precedent This change is consistent with the U.S. Nuclear Regulatory Commission (USNRC) approved Safety Evaluation on Technical Specification Task Force (TSTF) Traveler, TSTF-514-A, Revision 3, "Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation" dated November 24, 2010, as referenced in the Federal Register Notice of Availability on December 17, 2010. 4.3 No Significant Hazards Consideration Determination In accordance with 10 CFR 50.90, "Application for amendment of license, construction permit, or early site permit," Exelon Generation Company, LLC (EGC) requests an amendment to the Technical Specifications (TS) for Limerick Generating Station, Units 1 and 2. The proposed amendment modifies the Actions to be taken when the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system are the only operable reactor coolant leakage detection monitoring systems. The modified Actions require additional, more frequent monitoring of other Reactor Coolant

Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page4of5 System (ROS) leakage indications and provide appropriate time to restore another monitoring system to Operable status. EGO has evaluated whether or not a significant hazards consideration is involved with the proposed amendment by focusing on the three standards set forth in 10 CFR 50.92, Issuance of amendment, as discussed below: 1. Does the proposed amendment involve a significant increase in the probability or consequences of an accident previously evaluated? Response: No. The proposed changes clarify the Operability requirements for the RCS leakage detection instrumentation and modify the time allowed for the plant to operate when the only operable RCS leakage detection instrumentation monitors are the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system. The monitoring of ROS leakage is not a precursor to any accident previously evaluated. The monitoring of RCS leakage is not a direct method used to mitigate the consequences of any accident previously evaluated. Therefore, the proposed amendment does not involve a significant increase in the probability or consequences of an accident previously evaluated. The proposed changes also renumber the current TS Actions to accommodate the new TS Action. This change is administrative in nature and does not involve a significant increase in the probability or consequences of an accident previously evaluated. 2. Does the proposed amendment create the possibility of a new or different kind of accident from any accident previously evaluated? Response: No. The proposed changes clarify the Operability requirements for the RCS leakage detection instrumentation and modify the time allowed for the plant to operate when the only operable RCS leakage detection instrumentation monitor monitors are the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system. The proposed changes do not involve a physical alteration of the plant (no new or different type of equipment will be installed) or a change in the methods governing normal plant operation. Therefore, the proposed amendment does not create the possibility of a new or different kind of accident from any accident previously evaluated. The proposed changes also renumber the current TS Actions to accommodate the new TS Action. This change is administrative in nature and does not create the possibility of a new or different kind of accident from any accident previously evaluated. 3. Does the proposed amendment involve a significant reduction in a margin of safety? Response: No. The proposed changes clarify the Operability requirements for the RCS leakage detection instrumentation and increase the time allowed for the drywell floor drain sump Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 4 of 5 System (RCS) leakage indications and provide appropriate time to restore another monitoring system to Operable status. evaluated whether or not a significant hazards consideration is involved with the proposed amendment by focusing on the three standards set forth in 10 CFR 50.92, "Issuance of amendment," as discussed below: 1. the proposed amendment involve a significant increase in the probability or consequences of an accident previously evaluated? Response: No. The proposed changes clarify the Operability requirements for the RCS leakage detection instrumentation and modify the time allowed for the plant to operate when the only operable RCS leakage detection instrumentation monitors are the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system. The monitoring of RCS leakage is not a precursor to any accident previously evaluated. The monitoring of RCS leakage is not a direct method used to mitigate the consequences of any accident previously evaluated. Therefore, the proposed amendment does not involve a significant increase in the probability or consequences of an accident previously evaluated. The proposed changes also renumber the current TS Actions to accommodate the new TS Action. This change is administrative in nature and does not involve a significant increase in the probability or consequences of an accident previously evaluated. 2. Does the proposed amendment create the possibility of a new or different kind of accident from any accident previously evaluated? Response: No. The proposed changes clarify the Operability requirements for the RCS leakage detection instrumentation and modify the time allowed for the plant to operate when the only operable RCS leakage detection instrumentation monitor monitors are the containment atmosphere gaseous radioactivity monitoring system and the primary containment pressure and temperature monitoring system. The proposed changes do not involve a physical alteration of the plant (no new or different type of equipment will be installed) or a change in the methods governing normal plant operation. Therefore, the proposed amendment does not create the possibility of a new or different kind of accident from any accident previously evaluated. The proposed changes also renumber the current TS Actions to accommodate the new TS Action. This change is administrative in nature and does not create the possibility of a new or different kind of accident from any accident previously evaluated. 3. Does the proposed amendment involve a significant reduction in a margin of safety? Response: No. The proposed changes clarify the Operability requirements for the RCS leakage detection instrumentation and increase the time allowed for the drywell floor drain sump

Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 5of5 flow monitoring system and the drywell unit coolers condensate flow rate monitoring system to be inoperable concurrently from 12 hours to 7 days. Increasing the amount of time the plant is allowed to operate with these two leakage detection monitors inoperable does not significantly decrease the margin of safety due to the addition of compensatory actions to analyze grab samples of the primary containment atmosphere once per 12 hours and monitor RCS leakage by administrative means once per 12 hours. The overall likelihood that an increase in RCS leakage will be detected before it potentially results in gross failure is maintained with the addition of the actions. Therefore, the proposed amendment does not involve a significant reduction in a margin of safety. The proposed changes also renumber the current TS Actions to accommodate the new TS Action. This change is administrative in nature and does not involve a significant reduction in a margin of safety. Based on the above, EGC concludes that the proposed amendment does not involve a significant hazards consideration under the standards set forth in 10 CFR 50.92(c), and accordingly, a finding of no significant hazards consideration is justified. 4.4 Conclusions In conclusion, based on the considerations discussed above, (1) there is reasonable assurance that the health and safety of the public will not be endangered by operation in the proposed manner, (2) such activities will be conducted in compliance with the Commissions regulations, and (3) the issuance of the amendment will not be inimical to the common defense and security or to the health and safety of the public.

5.0 ENVIRONMENTAL CONSIDERATION

EGC has reviewed the environmental evaluation included in the model safety evaluation provided in the December 17, 2010 Federal Register Notice of Availability referenced information in TSTF-5 14-A, Revision 3. ECG has concluded that the staffs findings presented in that evaluation are applicable to LGS, Units 1 and 2, and the evaluation is hereby incorporated by reference for this application.

6.0 REFERENCES

6.1 TSTF-514-A, Revision 3, Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation dated November 24, 2010. 6.2 Notice of Availability of the Models for Plant-Specific Adoption of Technical Specifications Task Force Traveler TSTF514, Revision 3, Revise BWR Operability Requirements and Actions for RCS Leakage Instrumentation, dated December 17, 2010. Revise Operability Requirements and Actions for RCS Leakage Instrumentation : Evaluation of Proposed Changes Page 5 of 5 flow monitoring system and the drywell unit coolers condensate flow rate monitoring system to be inoperable concurrently from 12 hours to 7 days. Increasing the amount of time the plant is allowed to operate with these two leakage detection monitors inoperable does not significantly the margin of safety due to the addition of compensatory actions to analyze grab samples of the primary containment atmosphere once per 12 hours and monitor RCS leakage by administrative means once per 12 hours. The overall likelihood that an increase in RCS leakage will be detected before it potentially results in gross failure is maintained with the addition of the actions. Therefore, the proposed amendment does not involve a significant reduction in a margin of safety. The proposed changes also renumber the current TS Actions to accommodate the new TS Action. This change is administrative in nature and does not involve a significant reduction in a margin of safety. Based on the above, EGC concludes that the proposed amendment does not involve a significant hazards consideration under the standards set forth in 10 CFR 50.92(c), and accordingly, a finding of no significant hazards consideration is justified. 4.4 Conclusions In conclusion, based on the considerations discussed above, (1) there is reasonable assurance that the health and safety of the public will not be endangered by operation in the proposed manner, (2) such activities will be conducted in compliance with the Commission's regulations, and (3) the issuance of the amendment will not be inimical to the common defense and security or to the health and safety of the public.

5.0 ENVIRONMENTAL CONSIDERATION

EGC has reviewed the environmental evaluation included in the model safety evaluation provided in the December 17, 2010 Federal Register Notice of Availability referenced information in TSTF-514-A, Revision 3. ECG has concluded that the staffs findings presented in that evaluation are applicable to LGS, Units 1 and 2, and the evaluation is hereby incorporated by reference for this application.

6.0 REFERENCES

6.1 TSTF-514-A, Revision 3, "Revised BWR Operability Requirements and Actions for RCS Leakage Instrumentation" dated November 24, 2010. 6.2 Notice of Availability of the Models for Plant-Specific Adoption of Technical Specifications Task Force Traveler TSTF-514, Revision 3, "Revise BWR Operability Requirements and Actions for RCS Leakage Instrumentation," dated December 17, 2010.

ATTACHMENT 2 Markup of Technical Specifications Pages Limerick Generating Station, Units I and 2 Facility Operating License Nos. NPF-39 and NPF-85 REVISED TECHNICAL SPECIFICATIONS PAGES 3/4 4-8 3/4 4-8a ATTACHMENT 2 Markup of Technical Specifications Pages Limerick Generating Station, Units 1 and 2 Facility Operating License Nos. NPF-39 and NPF-85 REVISED TECHNICAL SPECIFICATIONS PAGES 3/4 4-8 3/44-8a

Ri AC OR COOLAN 31% LM r:.j.4.3 P140 FOR 001 AN lY FM IIAKA(E C:DLTLl L1MLllt1OG JON jjJPLifAjjiL LI.1.1 ml wino reactor uo ant loakioe detection ystLms ilhl 1 F t PP RAP L F: a. I nr mary un to omen P a tmosphrre qius rod i 00(21 I vi ty non tori ng

yscem, b.

Iho Irywell I loor drain sump flow monitoring system, The Irywel 1 unit coolers condensate Plow rate monitoring system, and 1. he primary conLiinment pressure and temperature rnoni toring system. APPLICABILI [1: OPERAtIONAL CONDI LIONS 1, 2, aid 3. )i ((flit y out imnmm nt ji our id oactivi ty mmii br not ir (1111 i( d to b( operable intl I Operational Condi tion 2. AC F IONS: A. With the pr i ma ry contai nment a tmosphere gaseous radi oacti vi ty monitoring system inoperable, analyze grab samples of primary containment atmosphere at least once nor 12 hours AND restore primary containment atmosphere gaseous radioactivity non i tori ng ystem to OPERABLE status wi thi ii 30 days. B, With the dryweli floor drain sump flow monitoring system inoperable, restore the drywel I floor drain surnp flow monitoring system to OPERABLE status within 30 (lays AND increase monitoring Frequency of drywel I unit cooler condensate flow rate (SR 4.4.3.2. i.c) to once every 8 hours, C. With the drywol 1 unit cool ers condensate 110w rate mnoni tori rig system inoperable, AND the primary containment atmosphere gaseous radioactivity monitoring system OPERABLE, perform a channel check of the primary containment atmosphere gaseous radioactivity monitoring system (SR 4.4.3.1.a) once per 8 hours. IL With the primary containment pressure and temperature monitoring system inoperable, restore the primary containment pressure and temperature monitoring system to OPERABLE status within 30 days. NOTE: All other tech Spec Limiting Conch tioris For 0eration and Surveillance Roqui rements associ ated with the primary containment oressure/temperature monitoring system still anply. Affected Loch Spec Sections include: 3/4.3.7.5, 4.4.3.2.1, 3/4.6.1.6. and 3/4.6.1.7. E. With the primary containment atmosphere gaseous radioactivity monitoring system inoperable AND the drywell unit coolers condensate flow rate monitoring system inoperable, restore the primary containment atmosphere gaseous radioactivity monitoring system to OPERABLE status within 3D days OR restore the dryweil unit coolers condensate flow rate monitoring system to OPERABLE status within 30 days. With the primary containment atmosphere gaseous radioactivity monitoring system inoperable, analyze grab samples of primary containment atmosphere at least once per 12 hours. LIMERICK liMIT 1 3/4 4-8 Amendment,,, 110wi tor lant I ion 11 ri rna ry tainrnent tmos raeji oa i vi rnoni ri n r drain ump low monitoring

tern, cJryvvell unit I r coneien f1 ow ra monitoring nd d.

primary containmen pres ure and ture monitoring sy tern. OPERATIONAL CONDITIONS 1, nd mary containment ga radioactivi until tional Condition 2. monitor not required to be A. With the primary containment gaseous radioactivity monitoring system 1, analyze grab primary containment a at least once r 12 hours AND restore primary containment a gaseous radioactivi monitoring tem to OPERABLE tus within 30 B. With the 1 floor drain ump flow monitoring system inoperable, restore the 11 r drain sump low monitoring stem to OPERABLE tatus within 30 s AND inc monitor ng of I unit cooler conden flow rate (SR 4.4... 1. ) to once every 8 Y1OUrs. With the drywell unit cool condensate flow rate monitoring inoperable, AND the mary containment atmosphere gaseous radioactivity monitoring system a channel check of the mary containment a re gaseous monitoring (SR 4.4.. 1.a) once per 8 hours. D. With the mary containment pressure and rature monitoring system inoperable, restore the primary containment pressure and ture monitoring to OPERABLE status within 30 days. With the primary containment atmosphere gaseous radioactivity monitoring system inoperabl AND the 11 unit coolers condensate flow rate monitoring i rabIe, restore the primary containment a gaseous radioactivity taring to OPERABLE status within 30 days OR restore the drywell unit coolers condensate flow rate monitoring to OPERABLE status within 30 days. With the primary containment atmosphere gaseous radioactivi monitoring system inoperable, analyze grab samples of primary containment atmosphere at least once per 12 hours. LIMERICK - UNIT 1 3/4 4 8 Amendment +-l-, -+/-4Q., -l&9-, ~

RJiillLQAtL+/-iLU4 1/4.1 .1 liLAC ICR COOLANI )Y)l EM LEALAC I iALJLLLLJJLLiLLMS lil1LI_LNQ J(JNL)1iiON. ILl. I no t/l lowin recctr noul mt loikajo tote tion ysrms hi I 001 RABIE 1. hi p iTiiiiry

eritai rnnont it.mnphero jreous r id iomct i vi ty motH tori nj nystim, 0.

I hi rvwi t leer Orci ii ump tlnw miii toiri mmmi cyc tern, lh irywe I I unit coolers cur lermtite How rate unnm turing system, mud 1. the primary containment pressure md temperature muni tnrmnq system. APPI I CAll LIlY: OPERA ii ONAL CONDI I IONS 2, and I. the primary ontai nment gaseous roiL omctiv ty moni tor is not required to be operable mint II (Jperationa I Condition 2. 4CTiN A. WI th the mr i mary contai nment atmosphere gaseous radi oacti vi ty mon i tori rig system i noperab le, ceo 1 yze grab samples (31 pr i mary containment atmosphere at least once per 12 hours AND restore primary containment atmosphere gaseous radioactivity moni tori ng system to OPERABLE status within 30 Uays. B. With the drywell floor drain sump flow monitoring system inoperable, restore the drywe II El oor dra in sump flow moni tori ng sys tern to OPERABLE status within 30 days ANt) increase monitoring frequency of drywe 11 unit cool or condensate flow rate (SR 4.4.3.2.i.c) to once every 8 hours. C. With the drywel 1 unit coolers condensate flow rate monitoring system inoperable, AND the primary containment atmosphere gaseous radioactivity monitoring system OPERABLE, perform a channel check of the pri nary containment a tmosphere gaseous radioactivity monitoring system (SR 4.4.3.1.a) once per 8 hours. 0. With the pr i nary contai nment pressure and temperature moni tori rig system inoperable, restore the primary containment pressure arid temperature monitoring system to OPERABLE status within 30 days. Note: All other loch Spec Limiting Lend i ti ens or Operati on and Survei lance Regui rements associ ated with the primary containment Eressure/telflperatLlre 110111 tori no system sti 11 apply. Affected tech

pec Sections md ude:

3/4.3. /.5. 4.4.3.2.1. 3/4.6.1.6, and 3/4.6.1.7. E. With the primary containment atmosphere gaseous radioactivity moni tori rig system inoperable AND the drywel 1 nmn it coolers condensa to flow rate mon i tori rig system I noperab I c, restore the primary conta i nment atmosphere gaseous radi cacti vi ty mcmii tori rmg system to OPERABLE status within 30 days OR restore the drywel 1 unit coolers condensate flow rate monitoring system to OPERABLE status within 30 days. With the primary containment atmosphere gaseous radioactivity monitoring system inoperable, analyze grab samples of primary containment atmosphere at least once per 12 hours. LIMERICK UNiT 2 3/4 4-8 Amendment No. 03, 4-03, 4-33, f3-- r I n 11 pr i rna ry trno i vi mon i ri nq

tern, l).

drywe I I loor cl in sump low moni II d. Iht? pr mdry inment ratu moni rinq sy tern. OPERArrONAL ainment rational Condition monitor not ired to be 1\\. With primary containment atmos inoperabr , analyze rab sampl 0 per 12 hou AND restore primary monitoring to OPERABLE monitoring re at least once radioactivi B. \\~ith trle drywell loor low moni rinq drywell floor clra in ump fl ow mon tori nq tern f\\ND inc moni tori nq drywe 11 uni 4.4.3.. 1. ) to once tern inoperabl , restore the OPERABLE tatus within 30 cool r concJc2nsd fl ow ra te (SR drywe 11 un! t I rs concJen a flow mon i tori ng sy tem ii, rimary containment gaseous radioactivity monitoring system rform a channel chec of the primary containment a re qaseous monitoring stern (SR 4.4.. l.a) once per 8 hour. radioactiv Wi th J\\ND the C. D. With the primary containment pres u and rature monitoring system inoperabl, tore the primary containment pressure and ture monitoring system to OPERABLE status within 30 With the primary containment re qaseous radioactivi monitoring system inoperable AND the d 1 uni cool rs condensate flow rate monitoring system inoperabl , restore the primary containment gaseous radioactivity monitoring system to OPERABLE status within 30 OR restore the drywell unit coolers condensate flow rate monitoring to OPERABLE status within 30 With the primary containment re gaseous radioactivity monitoring system inoperable, analyze grab samples of primary containment atmosphere at least once per 12 hours. ~ LIMERICK - UNIT 2 3/4 4-8 Amendment No..;4, -l-GJ, *, ~

Insert I F. With the drywell floor drain sump monitoring system inoperable the drywell unit coolers condensate flow rate monitoring system inoperable analyze grab samples of the primary containment atmosphere once per 12 hours, AND monitor Reactor Coolant System leakage by administrative means once per 12 hours restore either the drywell floor drain sump monitoring system to OPERABLE status within 7 days OR restore the drywell unit coolers condensate flow rate monitoring system to OPERABLE status within 7 days. Insert 1 With the drywell floor drain sump monitoring system inoperable AND the drywell unit 1"'1"\\'.... IO'1"C' 1"""'t'\\rlot'\\C'-:::.1'o flow rate monitoring system inoperable analyze grab samples of the primary containment atmosphere once per 12 hours, AND monitor Reactor Coolant System leaKaCle by administrative means once per 12 hours AND restore either the drywell floor drain sump monitoring system to OPERABLE status within 7 days OR restore the drywell unit condensate flow rate monitoring system to OPERABLE status within 7 days.

REAC FOR COOLANT SYSTEM AC [IONS (Continued) tWitl1 any other two or more leak detection systems inoperable other than ACl1O ACflOr4S F above OR with required Actions and associated Completion Time of AC lIONS A, B, and F (;, I) . riot met, be in 1101 SHIJIDOWN within 12 hours AND in COLD SHUIDOWN within hours. 4.4.3.1 lhe reactor coolant system leakage detection systems shall be demonstrated opmable by: a. Perform a CHANNEL CHECK of the primary containment atmosphere gaseous radioactivity monitoring system in accordance with the Surveillance lrequency Control Program. b. Perform a CHANNEL FUNCTIONAL lEST at required leakage detection instrumentation in accordance with the Surveillance Frequency Control Program. [his does not apply to containment pressure and temperature monitoring system. c:. Perform a CHANNEL CALIBRATION of required leakage detection instrumentation in accordance with the Surveillance Frequency Control Program. rhis does not apply to containment pressure and temperature monitoring system. d. Monitor primary containment pressures AND primary containment temperature in accordance with the Surveillance Irequency Control Program. LIMERICK - UNIT 1 3/4 4-8a Amendment No. 444, 1 k Action ncl in fl0T SHUTDO~~N r trla n ONS COLD SHUTDOltJN Vi .4.. 1 rh(~ rabl ka on 11 demon tra conta nment n rda with b. Perform a CHANNEL FUNCTIONAL rumentation in accordance with not apply to containment p detect on requency Control Program. ratu monitoring sy tem. form a CHANNEL CALIBRATION of required lea detection instrumentation in rdance with the Surveillance Control Program. fhi does not pply to containment pressure and ture monitoring d. Monitor primary containment pressu s primary containment ccordance with the Surveillance Frequency Control ture in LIMERICK - UNIT 1 3/4 4-8a Amendment No. +4G, ~

IL/\\((Uli i:optrii (1[l1 ACIiUitiJent i;ii,sj) WIth my st her to mure leak lotect uii system; oupermbl e other than mhove (JR with requ I red Actions and issoci ated Lompletion I lee ot AC ((iNC A, B, p be In HUE COO DOWN within L hours AND in COLD SHU I DOWN within U1VLiLLANCL PL1JUIRLMLTIL L:LI. I the nostor cool ant ystun 1akage detection systems chat I he I [liOns tratcdt uperah e by: a. Prturm a CHANNEL CHECK ot the primary containment atmosphere gaseous m11actlVl Li ;norii torroj ystem in accordance wi to the Sjrvei lance rJemiry (nt ro I P roqrarn. b. Pertorm a CHANNEL FUNCTIONAL VEST oF requi red eakaqe detecti on instrumentation in accordance with the Survei Ii once Frequency Control Program. this does not apply to containment pressure and temperature non i tori ng system. c. Pertorm a CHANNEL CALIBRAT [ON of requi red leaKage detecti on instrumentation in accordance w th toe survei II once Frequency Control Program. his does iot apply to containment pressure and temperature moni tori ng sys tern. 1. Monitor urimary containment pressure AND primary containment temperature in accordance with the Curve i ((once Frequency Control Program. LIMERICK UNIt 2 3/4 4-Ba Amendment No. D3, 44A, 4-53 ra n prj in ion inment vii th LJ. of required I with t Surveillance to containment p sure detection Control ture I;v i th the containment detection in rumentation Control ram. rhi does ture monitoring system. tvJonitor primary wi h primary containment Control Progr'am. rature in LIMERICK - UNIT 2 3/4 4-8a Amendment No. -+/--W, +4+, ~

ATTACHMENT 3 Markup of Technical Specifications Bases Pages (For Information Only) Limerick Generating Station. Units I and 2 Facility Operating License Nos. NPF-39 and NPF-85 REVISED TECHNICAL SPECIFICATIONS BASES PAGES B 3/4 4-3 B 3/4 4-3a B 3/4 4-3c B 3/4 4-3d ATTACHMENT 3 Markup of Technical Specifications Bases Pages (For Information Only) Limerick Generating Station, Units 1 and 2 Facility Operating License Nos. NPF-39 and NPF-85 REVISED TECHNICAL SPECIFICATIONS BASES PAGES B 3/4 4-3 B 3/44-3a B 3/4 4-3c B 3/4 4-3d

Li

1. Li.

I LHARACL ULILCI ION OYiEM lA[ KI lLI NI) IN AR Catety Nesi go i3asi s (Ret. I), roqur res means for detect inn and, to the extont ci deriti tying the location it the sourco ot Reactor Cool ant System (RES) PRFSSIJRF IIULJNI)ARY ILAKAUL. Rogirl a tory Guide I.45 (Ref. N) der hes acceptab e methods to eleLt1nj eakage (Ietectiin

/St005.

) 1111 ts n leakage trcrn the reactor coo Hit pressure boundary tRCPB) are rnqui red so that ippropriate acti on can be taken betore the integrity of the RCPI3 is impa rod (Ref. N). leakage detect) on systems to r tho RCS a cc prov i ded to a 1 ert the opera torn when I eakage rd tes above normal background levels are detected and a I so to supply quantitative measurement ot leakage rates. Systems for soparati ng the leakage of an I denti Lied source from an uni denti fled source are necessary to provide prompt and quantitative information to the operators to permit thorn to take mmcdi ate corrective action. Leakage from the RCPB iris) de the drywe I 1 is detected by at least one of four (4) independently mon i tored variables which i nd ode drywel I drain sump level changes over time yielding drain flow rates, arid drywel I gaseous radioactivity, drywel 1 unit cooler condensate flow rate and drywe I pressure/temperature levels, the primary means of quantifying leakage in the drywel I are the drywell floor drain sump flow monitoring system for UNIDENTIFIED LEAKAGE and the drywel 1 equipment drain tank flow monitoring system for IDENTIFIED LLAKAGE. IDENFIFEED leakage is not germane to this tech Spec arid the associated drywell equipment drain tank flow monitoring system is not included. (he dryweli floor drain sump flow monitoring system monitors UNIDENTIFIED LEAKAGE collected in the floor drain sump. UNIDENTIFIED LEAKAGE consists of leakage from RCPB components inside the drywell which are riot normally subject to leakage and otherwise routed to the drywel I equipment drain surnp. The primary containment floor drain sump has transmitters that supply level rid i cation to the mdi n control room via the plant monitoring system. The floor drain sump level transmitters are as soci ated with High/Low level switches that open/close the sump tank drain valves automatically. The level instrument processing unit calculates an average leak rate (gpm) for a given measurement pen ad which resets whenever the sump drain valve closes. The level processing unit provides an alarm to the main control room each time the average leak rate changes by a predetermined value since the last time the alarm was reset. For the drywell floor drain sump flow monitoring system, the setpoint basis is a 1 gpm change in lJN[l)l-NlIFIEI) LEAKAGE. In addition to the drywell floor drain sump flow monitoring system described above, the discharge of each sump is monitored by an independent flow element. The measured flow rate from the flow element is integrated and recorded. A main control room alarm is also provided to indicate an excessive sump discharge rate measured via the flow clement. ihis system, referred to as the drywell floor drain flow totalizer, is not credited for dryweil floor drain sump flow monitoring system operabi lity. LIMERICK UNIT 1 B 3/4 4-3 Amendment,, u re tr1e drywell ttie (jrywell equi IDENTIF ED 1 ka i equi drain tank identifi source from an unidentified source tative information to the operators from the RCPB in ide the tly monitored vari bl which include yi lding drain flow , and drywell 1 unit cooler conden te flow rate drywell fhe primary mean of i ing lea in the drywell drain ump low monitoring for UNIDENTI lED LEAKAGE and drain tank flow monitoring for IDENTIFIED LEAKAGE. not germane to this Tech and the associated drywell flow monitoring system is not included. drywell floor drain ump flow monitoring sy tem monitors UNIDENTIFIED LEAKAGE colI in the loor drain ump. UNIDENTIFIED LEAKAGE con i ts of leakage from RCPB componen in ide the drywell which are not normally ect to lea and otherwise routed to the drywel I equi drain sump. Ihe mary containment floor drain sump ha transmitters that upply level indication to main control room via the plant monitoring system. rhe floor drain ump level transmitters re a sociated with Hi Low 1 I switches that open/close the sump tank drain valves automatically. fhe level instrument processing unit calculates an average leak rate (gpm) for a given measurement ad which resets whenever the sump drain valve loses. The level processing unit provides n alarm to the main control room each time the average leak rate changes a ned value ince the last time the alarm was reset. For the 11 loor dra n sump flow monitoring system, the int basis is a 1 gpm change in UNIDENTIFIED LEAKAGE. In addition to the drywell floor drain sump flow monitoring described above, the discharge of each sump is monitored by an independent flow element. The measured flow rate from the flow lement is i and recorded. A main control room alarm is also provided to indicate an excessive sump discharge rate measured via the flow e-Iement. fhis system, referred to as the "drywell floor drain flow totalizer", is not credited for d 1 floor drain sump flow monitoring system operabil ity. LIMERICK - UNIT 1 B 3/4 4-3 Amendment 4G, ~, ~

KAL i/l,L i. [ IFAKAGE DELECIlUN YGFIMS KACE(R OHND II CAR Citety Us rn has I Ret. () requl res mean; for detecting and, to the extent prict ci ilenti ty rig the Iooiti err ot the

ource of Rea: tor coolant System I. itS) lIjRE BOUNDARY lEAKAGE.

Regul it ory (in do .lh (Ref. B) dccc ibes acceptable methods or solting leakage detection

ystlns.

>evtsor > line ts cri leakage trem the roictor eel ant pressure boundary (RCPB) are regui red so thi t ippropr (ito ic t on carl be ti ken be fore the integrity ot the RCPI3 i s spa red (Ref. B). leakage dot ectiori systems tor the hitS are provided to alert the operators when leakage rates above normal background levels ire detected and also to supply lunti titi ye measurement of leakage rites.Ryl

ytems tor eparati ng the leakage ut an ident i fled source from an unidentified source are necessary to provide prompt and quantitative information to the operators to permit them to take immediate corrective action.

Leakage from the RCPB inside the drywel 1 is detected by at least one of four (4) independently monitored variables which include drywel 1 drain somp level changes over time yielding drain flow rates, and drywel I gaseous radioactivity, drywell unit cooler condensate flow rate and drywell pre:ur c/temperature levels. the pr i mary means of guanti fyi ng leakage in the drywel 1 are the drywel I floor drain sump flow monitoring system for UNIDENTIFIED LEAKAGE and the dryweil equipment drain tank flow monitoring system for IDENTIFIED LEAKAGE. IDENF[FIED leakage is not germane to this Tech Spec and the associated drywell equipment drain tank flow monitoring system is not included. (he drywel 1 floor drain sump flow mon toring system monitors UNIDENTIFIED LEAKAGE collected in the floor drain sump. IJNIDENTIFIED LEAKAGE consists of leakage from RCPB components inside the drywell which (ire riot normally subject to leakage arid otherwise routed to the drywel 1 equipment drain sumnp. The primary containment floor drain sump has transmitters that supply level indication to the main control room via the plant moni tori rig system. The floor dra in sump level transmi tters are associ ated with High/Low level switches that open/close the sump tank drain valves automatically. The level instrument processing unit calculates an average leak rate (gpm) for a given measurement period which resets whenever the sump drain valve closes. the level processing unit provides an alarm to the main control room each time the average leak rate changes by a predetermined value since the last time the alarm was reset. For the rywell floor drain sump flow monitoring system, the setpoint basis is a 1 gpm change in UNIDENTIFIED LEAKAGE. In addition to the dryweli floor drain sump flow monitoring system described above, the discharge oF each sump is monitored by an independent flow element. Tire measured flow rate from the flow element is integrated arid recorded. A main control room alarm is also provided to indicate an excessive sump discharge rate measured via the flow clement. This system, referred to as the drywell floor drain flow totalizer, is not credited for drywehi floor drain surnp flow monitoring system operability. liMERICK ((NIL 2 B 3/4 4-3 Amendment 4, 1D3 boundary (RCPS) required a the in ri of the RCPS i impaired (Ref. re provided to alert the operators when and also to supply source from an unidentified source information to the operators to permit from the RCPS inside the drywell is Iy monitored variables which include yi lding drain flow rates, and drywell 11 unit cool conden ate flow rate and drywell fhe imary means of quanti ing leakage in the drywell in ump low monitoring sy em for UNIDENTIFIED LEAKAGE and drain tank flow monitoring system for IDENTIFIED LEAKAGE. not germane to thi fech and the associ ted drywell low monitoring sy tern i not included. fhe drywell I r d in ump low monitoring monitors UNIDENTIFIED LEAKAGE coil ted in Ule floor drain ump. UNIDENTIFIED LEAKAGE consi ts of leakage from RCPS n the drywel I which not normally ect to lea nd otherwise routed to the drywell equi drain sump. The primary containment floor drain sump ha ransmit tha upp y level indication to the main control room via the plant monitoring fhe floor drain sump level transmitters are associated with Hi /Low 1 that lose the sump tank drain valves automatically. The level in rument proces 1ng un t calculates an average leak rate (gpm) for a given measurement period which resets whenever the sump drain valve closes. fhe level processing unit provides an alarm to the main control room each time the average leak rate by rmined value ince the last time the alarm was reset. For the drywell floor drain flow monitoring system, the jnt basis is a 1 gpm change in UNlDENTI lED In addi ion to the drywell floor drain sump flow monitoring system described above, the discharge of ch sump is monitored by an i t flow element. The measured flow rate from the flow element is j rated and recorded. A main control room alarm is also provided to indicate an excessive sump discharge rate measured via the flow lement. This , referred to as the "drywell floor drain flow totalizer", is not credited for drywell floor drain sump flow monitoring system operabil ity. LIMERICK - UNIf 2 S 3/4 4-3 Amendment ~, ~

Insert 2 In addition to meeting the OPERABILITY requirements, the monitors are typically set to provide the most sensitive response without causing an excessive number of spurious alarms. Insert 2 In addition to meeting the OPERABILITY requirements, the monitors are typically set to provide the most sensitive response without causing an excessive number of spurious alarms.

AC C R f[lAN ICYS EM lie pr mary conta neent a tmospheri C (Jaseous adi oacti vi ty mon i tori op system cunti nuousl v moni tors toe primary containment atmosphere Par qaseous radioacti v ty Civil A ,ui(t(n lncrr isa ot ridioict.i Vi ty, in ih iiiiy Do i5tribited to RCPB stoam or rictor water I rakago, I

onnunc ited hír toe ina ri control room.

i-he primary COfltiflmO trphi 10 ifeui-rtd-a-tivity-monitor +/-nig yi+-mi t -ri-rJp,l,-} t-point ryrr i ciLwi , -but I ntiv Ietet Fncra-s-ecl I ratje a-too of I ithn I wir. irgnr rhuruje; in heakajo -at-c; uu-Itctod n proportionally ohoFtw ir; (het Ccrdensate from the eight drywe II air coolers is routed to the drywei 1 P oor (Ira in sump mi is mom tored by a series at tow transmi tters that crovide indication and alarms in the ma in coritro I room. [lie outputs trom the Plow transmi tters are added together by summing mi to to provide a total continuous condensate drain flow rate. he high flow a I arm setpoi nt is based on condensate drain Plow rate in excess of I ppm over the current 1 y i denti tied preset leak rate. [he drywe ii a i r coo I er condensate flow rate moni turing syst.rn serves as an added indicator, hut not quanti Pier, of RCS UNIDENI IFIED LLAKAhE (Ret. [he drywell temperature and pressure monitoring system provide an indirect method for detecti op PCPB I eakge. A temperature and/or pressure rise in the drywel 1 above normal levels may be indicative of a reactor coolant or steam leakage (Ref.. APP LI CEEfJYANALYSE A threat of 5 l (ml fi cant compromi si to the RCPB cxi sts if the harrier contains a crack that i s large enough to propagate rapidly. Leakage rate limits are set low enough to detect the leakage cmi tted Prom a single crack in the RCPB (Refs, Jand Eh-ef th Ecakaqe detection systems inside the drywel 1-i-s designed with the ca-pabi i ty dturtinp Iakag lacc than the uctahlished leakage ratc limits aid provdin mjrpri te al arms of excess Icakage i-n t-h-e ontroI ro-&- 7 A control room alarm allows the operators to evaluate the significance of the indicated leakage and, if necessary, shut down the reactor for further investigation and corrective action. The allowed leakage rates are well below the rates predicted for critical crack sizes (Ref. Therefore, these actions provide adequate responses before a significant break in the RCPB can occur. RCS leakage detection ii rumentation satisfies (Criterion 1 of the NRC Pal icy Ctatement. [MIT INC CONDITION FOR OPERAIjlL,OQj re drywcl 1 floor drain oump Plow monitoring system is rcqui red so quantify t-- UD[NfII[D LEAKAGE from the PEE. The other monitoring sytemc provide early aIarms the oprakor so closer eimination of other detection ystem will be rmine the extent of any corrective action that my he required. [11th any Iek-a-P lstccti on system i nonerable, omerti tori ng for I eakaoe in the REED is degrde& LIMERICK UNI[ 1 B 3/ 4 4-3a Amendment in sump rms in by flow to provi i r not 11 i r low n t from the flow continuous conden drain fl ow ra 11 tor, but pre sure monitoring sy tem provide an indirect method for re and/or pressure ri in the drywell above normal a reactor coo1ant or team 1f~akage (Ref. ~. fies (Criterion 1 of the NRC Policy A control room I and, if rrective action. fhe all riti 1 cra k izes (Ref. ( before a ignificant break ln RCS lea detection If Sta temen t. to evaluate the significance down the ctor for further investi I rates are well below the rates Therefore, these actions de the RCPB occur. of the indicated on and icted for responses rhe jr)'ldcll floor drain SUFflP flo'ii Fflonitoring S)'stCFfl is rcquired:o quaAtif)' tt~@" UNIOErnIFIED LEAI<AGE flom the ReS. fMC otAcr Awnitoring systems pro',idc early alarmsf7 to thQ of]Qr61tor gO (loser exam; nat; on of other detect; on S) stCfflS wi 11 be lilade L~ R d!tellfli nc the cxh:nt of any correct; 'rfe acti Of! that Ffly be requi red. II'; th M1) I eEikEigeP' j2::~eable, IftDniteeing fee leakage in tl.e REPS i2 degloded.*' LIMERICK UNIT 1 B 3/ 4 4-3a Amendment ~I

E[AiH)R UPIANI t75lfM he primary conta I rment atmospheric gaseous radiouctivi ty monitoring system continuously moni tors the primary containment atmosphere for gaseous radioectity evel s, A sudden increase ot radioactivity, which nay be attributed to RCPB steam or reactor water lakaqe, is annunciated in the main control room. fe primary continm etniusphori r

i115 radfoact. iv ty inoni torin yskem is not u:apob In af rtantif skg #tS hot t i v noogh 0) inrrasd rat ot I

ni i n I heo-t. larger hoatetto n inakap rates or detected 10 prenortiona I ly short 5-4 mu s I Pet-i--+ indonsato rum the erght drywel I air coolers is routed to the irywel 1 floor drain suinp jilil i

wont tored by a series ot flow transmitters that provide indication and alarms in the main control room.

I he outputs from the flow transmi tters are added together by sumini rig uni ts to provide a total coriti nuous condensate drain flOW rate, the high hi ow alarm setpoint is based on condensate drain flow rate in excess of 1 ppm over the currently identit red preset leak rate, The drywell air cooler condensate flow rate morn tori ng system serves as an added indicator, but riot guanti Tier, of RCS l.JNIDENTIFIED LEAKAGE (Ref. [he Irywe I I tempera ture and pressure moni tori rig systems provide an i ndi rect method for detecting RCPB leakage. A temperature and/or pressure rise in the drywell above normal levels may he indicative of a reactor coolant or steam leakage (Ref. M. APPL [CABLE S Al El ( ANALYSES A threat of si gui hi cant compromise to the RCPB cxi sts if the barrier contains a crack that is large enough to propagate rapidly. Leakage rate limits are set low enough to detect the leakage emitted from a single crack in the RCPB (Refs. and. f ikg dtction inside the 4ryw-il is designed with the aped ty e-ctincj leakage less than the established leakage rate limits or provdin tpropr ate I aries of mxces s I eakage in the control rooi A control room alarm allow the operators to evaluate the significance of the indicated leakage and, if necessary, shut down the reactor for further investigation and corrective action. Ihe allowed leakage rates are well below the rates predicted for critical crack sizes (Ref. 2i, Therefore, these actions provide adequate response before a significant break n the RCPB can occur. RCS leakage detection inst umentation satisfies Criterion 1 of the NRC Policy Statement. LIMITING CONDITION FOR OPERA1ION (LCO) I-h drysel I floor drain surnp flow monitoring systcm is rcqui red to guanti fy tI 4iDEN[iF1ED LEAKAGE from the I1CS. The other monitoring systems provide early alat-m to the cperators so closor examination of other detection systcrns will be made termi ne the extent of any correcti ye acti on thpt may be requi red, With any 1 eaka detection system inoperable monitoring for leakage in the RCPD is degrad LIMERICK iJNJT 2 B 3/4 4-3a Amendment rywell floor (jrain sump i ndi ion nd 1arms n are added her by low ra fhe high flow of 1 gpm over the cool r condensate flow rate quantifi r, of RCS UNIDENTIFIED rout(~d to the ttld t prov i rom the flow transmitter total continuous con den ate drain conden a dra n low ra in I k ra The drywell ai r an added indicator, but not nd pres ure monitoring systems provide an indirect method for A rature nd/or pres ure ri in the drywell above normal of ctor coo I ant or team lea kage (Ref. f.@ to the RCPS exists if the barrier contains a crack that i I to propaga rapidly. Lea rate 1imits are set low enough to (jeteet the 1eakage emitted fromas i n91 e era ckin the RCPS (Ref s. jl and ~. foe Ii ~ F t IH:Jl ~; :! T : r.; Ht ';1. ; i -; '::;1; ~fP ~::m~:::~:::~:~ ~:i:;~::::~~::;:g:<~~~E ~~;~:H ;~L!;::t===:~=: rs to evaluate the significance of the indicated 1 and, i ry, hut down the reactor for further investigation and corrective ction. fhe al lowed lea rates are well below the rates predicted for ritical crack i (Ref.~. Therefore, these actions provide adequate response before a igo if i nt brea~ the RePB can occur. RCS lea detection ins~entation sati fies Criterion 1 of the NRC Policy Statement. rho drY1dclj floor dra i n,::uffip f13\\tf [flOAi tori ng 5ysteffl is required to quaflti f, tid: JZ ~~jID~NTr~I~D L~AKAGE froffi the ReS. The other ffionitoring systeffis provide early a1arffisL to the operators 50 C1oscr p)(Jffli flati Ofl of other detecti Ofl SystCfflS ~9'i 11 be A'lade te.Q.. Jf!!ltH'ftlinQ thQ ext8nt of dny corrective action that ffiay be required. IJith an) lcal<a~4 .j~tt~Ltiofl '5dt~m illepel obl~, mtM1toi 111t:'1 fel l~okElg~ 11i tli~ RePB 13 d~gl ~d~d~ ~ LIMERICK - UNIT 2 B 3/4 4-3a Amendment ~

Insert 3 This LCO requires instruments of diverse monitoring principles to be OPERABLE to provide confidence that small amounts of UNIDENTIFIED LEAKAGE are detected in time to allow actions to place the plant in a safe condition, when RCS leakage indicates possible RCPB degradation. The LCO requires four instruments to be OPERABLE. The drywell floor drain sump monitoring system is required to quantify the UNIDENTIFIED LEAKAGE rate from the RCS. The identification of an increase in UNIDENTIFIED LEAKAGE will be delayed by the time required for the UNIDENTIFIED LEAKAGE to travel to the drywell floor drain sump and it may take longer than one hour to detect a 1 gpm increase in UNIDENTIFIED LEAKAGE, depending on the origin and magnitude of the leakage. This sensitivity is acceptable for containment sump monitor OPERABILITY. The reactor coolant contains radioactivity that, when released to the primary containment, can be detected by the gaseous primary containment atmospheric radioactivity monitor. A radioactivity detection system is included for monitoring gaseous activities because of its sensitivity and rapid response to RCS leakage, but it has recognized limitations. Reactor coolant radioactivity levels will be low during initial reactor startup and for a few weeks thereafter, until activated corrosion products have been formed and fission products appear from fuel element cladding contamination or cladding defects. If there are few fuel element cladding defects and low levels of activation products, it may not be possible for the gaseous primary containment atmospheric radioactivity monitor to detect a 1 gpm increase within 1 hour during normal operation. However, the gaseous primary containment atmospheric radioactivity monitor is OPERABLE when it is capable of detecting a 1 gpm increase in UNIDENTIFIED LEAKAGE within 1 hour given an RCS activity equivalent to that assumed in the design calculations for the monitors (Reference 9). The LCO is satisfied when monitors of diverse measurement means are available. Thus, the drywell floor drain sump monitoring system in combination with a gaseous primary containment atmospheric radioactivity monitor, a primary containment air cooler condensate flow rate monitoring system, and a primary containment pressure and temperature monitoring system provides an acceptable minimum. Insert 3 This LCO requires instruments of diverse monitoring principles to be OPERABLE to provide confidence that small amounts of UNIDENTIFIED LEAKAGE are detected in time to allow actions to place the plant in a safe condition, when RCS leakage indicates possible RCPB degradation. The LCO requires four instruments to be OPERABLE. The drywell floor drain sump monitoring system is required to quantify the UNIDENTIFIED LEAKAGE rate from the RCS. The identification of an increase in UNIDENTIFIED LEAKAGE will be delayed by the time required for the UNIDENTIFIED LEAKAGE to travel to the drywell floor drain sump and it may take longer than one hour to detect a 1 gpm increase in UNIDENTIFIED LEAKAGE, depending on the origin and magnitude of the leakage. This sensitivity is acceptable for containment sump monitor OPERABILITY. The reactor coolant contains radioactivity that, when released to the primary containment, can be detected by the gaseous primary containment atmospheric radioactivity monitor. A radioactivity detection system is included for monitoring gaseous activities because of its sensitivity and rapid response to RCS leakage, but it has recognized limitations. Reactor coolant radioactivity levels will be low during initial reactor startup and for a few weeks thereafter, until activated corrosion products have been formed and fission products appear from fuel element cladding contamination or cladding defects. If there are few fuel element cladding defects and low levels of activation prOducts, it may not be possible for the gaseous primary containment atmospheric radioactivity monitor to detect a 1 gpm increase within 1 hour during normal operation. However, the gaseous primary containment atmospheric radioactivity monitor is OPERABLE when it is capable of detecting a 1 gpm increase in UNIDENTIFIED LEAKAGE within 1 hour given an RCS activity equivalent to that assumed in the design calculations for the monitors (Reference 9). The LCO is satisfied when monitors of diverse measurement means are available. Thus, the drywell floor drain sump monitoring system in combination with a gaseous primary containment atmospheric radioactivity monitor, a primary containment air cooler condensate flow rate monitoring system, and a primary containment pressure and temperature monitoring system provides an acceptable minimum.

thAc I 011 hOOLAN ; I 1 N 40 iONS coot i nued) 0. WI th the requ I red pri Fury con ti i nrnent a I r coo or condensi to t ow rite mon i tori nq system inooerble, 31 1:1,3,1.1 must be performed every 0 hours to provide periodic F ntormnit on t ic t v Lv time urimarv eon mmert Ot 11010 trequerit ntervi I Loan the routi rio troquency ot every I

flour, ho 3 hour intervu 1

provides peri 0(1 (C irmtornmti on that is adequate to detect I eakiqe and rocnqrii /es that other turms ot loikige det*tmon ire aval lahie. 10 requr red ALE ION has been clan Lied to state that the addi tional survel I lance requi cement is not applicable if the requi red pr wary conti I nmnent atmosphere aseous radioactivity moni torinq system i salso inoperable. Lonsi stent with SR 4.0.3, surveillances are not requi red to he performed on inoperable equipment. In this case, ACtION Statement A. and H. requirements p ply. U. With the urinary conta i runent pres sure and tempera tore moni tori nq system inoperable, operation may continue Lor up to 10 lays q von the systems mdi rect capabi 1 i ty to detect RLS lea ka qe. I luweve r, of me r immore I mi t i rig tech Spec req iii rements as soc i a ted with the primary containment pressure/temperature monitoring system will sti 11 op p1 y. H. Wi th both the P11 mary contai nment atmosphere gaseous radioactivity moni tor arid the primary containment air cooler condensate flow rate monitor inoperable, the only nouns of detecting leakage is the drywel I tinur drain surnp rnonr tar and the drywel 1 pressure/tempera Lure i nstrumeri tat ion. ilil s condi ti on does riot provide the requi red diverse means of leakage detection. Ihe requi red ACtION is to restore either of the immoperabl e non I tors to OPERABLE status within 30 days to regain the intended leakage detection diversity. Ihe 30 day Completion Lime ensures that the plant will not be operited in i dcgraded cont gut ation for a lonqthy time period W ile the primary containment atrnos here radioactivity monitor is INOPERABLE, rimary containment atmospheric grab samples will he taken and analyzed every 12 hours since ACTION atemei A requirements also apply. iNS any requl red ACt ION of Conditions A, B, C, U annot be met within the associated Completion time, the plant must be brought to arm OPERAtIONAL CONDITION in which the LCO does not apply. lo achieve this status, the plant must be brought to at least 1101 SHUTOOWN within 12 hours and COLD SHUTDOWN within the next 24 hours. the allowed Completion Times are reasonable, based on operating experience, to pertorm the ACtIONS in an orderly manner and without challenging plant systems. SuRVEILLANCE REQUIREMENTS SR 4.4.3.1.a this SR is for the performance of a CHANNEL CHECK of the required primary containment atmospheric monitoring system. The check gives reasonable confidence that the channel is operating properly. LIMERICK - IJNIt B 3/4 4-3c Amendment,, rIONS rature monitoring inoperable, the tem' indirect ility to mit ng rech requirements a sociated rature monitoring system will ill r' mary con may cantin I primary con D. radi ctivity monitor nd the monitor inoperable, the only loor drain ump monitor and the drywell ACTION i to restore ither of the to regain the intended leakage ures that the plant will not be time period. Wile ~the primary i INOPERABLE, rimary containment every 12 hours since ACTION , f? tn" F' ACTION of Condition A, S, C, D .annot be met within the etion Time, the plant must be to an OPERATIONAL CONDITION in not apply. fo achieve this tatus, the plant must be brought to SHUTDOWN within 12 hours and COLD SHUTDOWN within the next 24 hours. letion limes are reasonable, based on operating experience, to in an orderly manner and without challenging plant systems. f for the performance of a CHANNEL CHECK of the required primary containment a ri monitoring rhe check gives reasonable confidence that the channel is operating p y. LH1ERICK - UNIT~ B 3/4 4-3c Amendment -+/-4G, ~, ~

II ACIIJC COIlLAfIF $?SILM W. ALjIi3iLiLorLLi C. With the rqui rod primary containment air cooler condensate H ow rote moni toring system noperahie, SR 4.4.3 l.a must be pertormed every 8 hours to provide periodic itirifla 1H1

r icr ivi ty fl the pr mary contal nment at a more trquent I ritervo I than toe rout 110 trr ouenrv it every 12 hours, lie 4 hour interval provides periodic ii to rina t i on the t i s adegua to to ietec t I ea kage and recogn i zes the t other to rrns of leakage detection are available, the required ACtION has been clan tied to state toot the add I H ona I survei ii once requi rement is not applicable if the requl red primary conita iniment. atmosphere qaseous radioactivity mon tori rnij system is at so inoperable.

Cunsi stout with SR 1.0.3, survei 11 ances are not requi red to be per tormed on inoperable equipment. In this case, ACTION Statement A, and E. requl rements I y. U. With the primary containment pressure and temperature monitoring system inoperable, operation may continue for up to 30 (lays gi veil the systems i rid i rect capab i Ii t,y to detect RCS leakage. However, other more limiting tech Spec regui rements associ a ted with tine primary contai nment pressure/temperature monitoring system will still app ly. C. With both the primary containment atmosphere gaseous radioactivity monitor and the primary conta inment. air cooler condensate How rate moni tor inoperable, the only means of detect i rig leakage is the drywel I flour drai n rump monitor and the drywel 1 pressure/ temperature ins trumentati on. lb I s condi ti on does not provide the requl red diverse, means of leakage detection. The requi red ACTION is to restore either of the inoperable mon i tons to OPERABLE status within 30 clays to regain the intended leakage detect ion diversity. [he 30 da,y Completion time ensures that the plant will not he operated in a degraded configurat ion tor a lengthy time period. Whi Ic the primer contai nment atmosphere gaseous radioactivity moni tor is INOPERABLE, rimary containment atmospheric grab samples will be taken and analyzed every 12 hours since A. requirements also apply. c I run red ACTION of Conditions A, B. C, Ocannot be met within the associated Completion

time, the plant must be brought to an OPERATIONAL CONDiTION in which the LCO does riot apply.

To achieve this status, the plant muSt be brought to at least HOt SHIJFDOWN within 12 hours arid COLD SHUTDOWN within the next 24 hours. Ide at owed Completion I lines are reasonable, based on operating experience, to perform the ACTIONS in an orderly manner and without challenging piant systems. ci n F II AM F [)[flH r flLA[EM rc )tJr\\VLILLI,II,,L RL,4UiRLlLiLL, SR 4.4.3.1.a [his SR is for the performance of a CHANNEL CHECK of the required primary containment atmospheric monitoring system. The check gives reasonable confidence that the channel is operating properly. LIMERICK UNIt 2 B 3/4 4-3c Amendment,, r'formed D. ItJi th vvi ttl Ule pply. inment pressure and

rabIe, inue for up to 30 given the sy tern' capabi i to However, other more limiting Tech rements ssociated containment pn:ssure/

rature monitoring system will ti 11 primary containment tmo gaseous radioactivity monitor nd the ir cool condensate low rate monitor inoperable, the only kage i the drywell loor drain ump monitor and the drywell in trumentation. fhi condition does not provide the required of I ion. file i ACTION i to restore ither of the monitors to OPERABLE status wi n 30 to regain the intended leakage diversity. fhe 30 day letion fime en ures that the plant wi 1I not be nconf i!] lH'ati 0 n r a 1 time ri 0d. ~Jhi lethe pri mar inment radioactivity monitor i rimary ......~~--"JI-,.- containment grab samples will be taken and anal every 12 hours Slnce AC' r ;lnt A. rements aIso apply. ~ lNSE'((.T ~ ~ ~ r I n lred ACTION of Conditions A, B, C, DA~cannot be met within the ~ ia letion fime, the plant must be brought to an OPERATIONAL CONDITION in which LCO not Iy. fo achieve this tus, the plant must be to t 1 t HOT SHUTDOWN wi in 12 hours and COLD SHUTDOWN within the next 24 hours. fhe I lowed letion rimes are reasonable, based on operating experience, to perform the IONS in an orderly manner and without challenging plant rformance of a CHANNEL CHECK of the required primary containment c monitor ng The check gives reasonable confidence that the channel operating properly. LIMERICK UNlf 2 B 3/4 4 3c Amendment +GJ, ~, ~

Insert 4 F. With the drywell floor drain sump monitoring system inoperable and the drywell unit coolers condensate flow rate monitoring system inoperable, one of the two remaining means of detecting leakage is the primary containment atmospheric gaseous radiation monitor. The primary containment atmospheric gaseous radiation monitor typically cannot detect a 1 gpm leak within one hour when RCS activity is low. Indirect methods of monitoring RCS leakage must be implemented. Grab samples of the primary containment atmosphere must be taken and analyzed and monitoring of RCS leakage by administrative means must be performed every 12 hours to provide alternate periodic information. Administrative means of monitoring RCS leakage include monitoring and trending parameters that may indicate an increase in RCS leakage. There are diverse alternative mechanisms from which appropriate indicators may be selected based on plant conditions. It is not necessary to utilize all of these methods, but a method or methods should be selected considering the current plant conditions and historical or expected sources of UNIDENTIFIED LEAKAGE. The administrative methods are the drywell cooling fan inlet/outlet temperatures, drywell equipment drain sump temperature indicator, drywell equipment drain tank hi temperature indicator, and drywell equipment drain tank flow indicator. These indications, coupled with the atmospheric grab samples, are sufficient to alert the operating staff to an unexpected increase in UNIDENTIFIED LEAKAGE. In addition to the primary containment atmospheric gaseous radiation monitor and indirect methods of monitoring RCS leakage, the primary containment pressure and temperature monitoring system is also available to alert the operating staff to an unexpected increase in UNIDENTIFIED LEAKAGE. The 12 hour interval is sufficient to detect increasing RCS leakage. The Required Action provides 7 days to restore another RCS leakage monitor to OPERABLE status to regain the intended leakage detection diversity. The 7-day Completion Time ensures that the plant will not be operated in a degraded configuration for a lengthy time period. Insert 4 F. With the drywell floor drain sump monitoring system inoperable and the drywell unit coolers condensate flow rate monitoring system inoperable, one of the two remaining means of detecting leakage is the primary containment atmospheric gaseous radiation monitor. The primary containment atmospheric gaseous radiation monitor typically cannot detect a 1 gpm leak within one hour when RCS activity is low. Indirect methods of monitoring RCS leakage must be implemented. Grab samples of the primary containment atmosphere must be taken and analyzed and monitoring of RCS leakage by administrative means must be performed every 12 hours to provide alternate periodic information. Administrative means of monitoring RCS leakage include monitoring and trending parameters that may indicate an increase in RCS leakage. There are diverse alternative mechanisms from which appropriate indicators may be selected based on plant conditions. It is not necessary to utilize all of these methods, but a method or methods should be selected considering the current plant conditions and historical or expected sources of UNIDENTIFIED LEAKAGE. The administrative methods are the drywell cooling fan inlet/outlet temperatures, drywell equipment drain sump temperature indicator, drywell equipment drain tank hi temperature indicator, and drywell equipment drain tank flow indicator. These indications, coupled with the atmospheric grab samples, are sufficient to alert the operating staff to an unexpected increase in UNIDENTIFIED LEAKAGE. In addition to the primary containment atmospheric gaseous radiation monitor and indirect methods of monitoring RCS leakage, the primary containment pressure and temperature monitoring system is also available to alert the operating staff to an unexpected increase in UNIDENTIFIED LEAKAGE. The 12 hour interval is sufficient to detect increasing RCS leakage. The Required Action provides 7 days to restore another RCS leakage monitor to OPERABLE status to regain the intended leakage detection diversity. The 7-day Completion Time ensures that the plant will not be operated in a degraded configuration for a lengthy time period.

It AL FOR 000LAN I SYS EM SR l.4.31.b hi; SR 1S tur the perormanc? of a CHANNEL CONE F IONAL fESI o the requ i red RCS eakage itect on nstrtuiientati on. oe test ensures that the moni tors can perform their function in the desi rod manner. ho test a so verities the alarm setpoint and relative iccuracy ot the instrument string. ho SR is for the performance of a CHANNEL CALIBRAF ION of requi red leakage detection 1 ostrumentati on channels. the ccl i brati on von Ci os the accuracy of the instrument

string, including the instruments located inside containment.

SR 4.4.3.1.d his SR provides a routine check of primary contai nment pressure and temperature for indirect ev i Hence of RCS leakage. RE F ER ENC ES LOS UFSAR, Section 5.2.5.1. Regulatory Guide 1.45, IN3ErY5 _L4 LOS UFSAR, Section 5.2.5.2.1.4. LOS UFSAR, Section 5.2.5.2.1.1(2). GEAP -5520, Apri I 1968 NUREG-75/067, October 1975. UFSA Section 5.2.5.6. 3/4.4.3,2 OPERAtIONAL LEAKAGE The allowable leakage rates from the reactor coolant system have been based on the predicted and experimentally observed behavior of cracks in pipes. The normally expected background leakage due to equipment design and the detection capability of the instrumentation for determining system leakage was also considered. The evidence obtained from experiments suggests that for leakage somewhat greater than that specified for IJNIDENT1I lEE) LEAKAGE the probability is small that the imperfection or crack associated with such leakage would grow rapidly.

However, in all cases, if the leakage rates exceed the values specified or the leakage is located and known to be PRESSURE BOUNDARY

LEAKAGE, the reactor will be shutdown to allow further investigation and corrective action.

The limit of 2 gpm increase in UNIDENtIFIED LEAKAGE over a 24-hour period and the monitoring of drywell floor drain sump and dryweli equipment drain tank flow rate at least once every eight (8) hours conforms with NRC staff positions specified in NRC Generic Letter 88-01, NRC Position on IGSCC in BWR Austenitic Stainless Steel

Piping, as revised by NRC Safety Evaluation dated March 6, 1990.

The ACTION requirement for the 2 gpmn increase in UNIDENTIFIED LEAKAGE limit ensures that such leakage is identified or a plant shutdown is initiated to allow further investigation and corrective action. Once identified, reactor operation may continue dependent upon the impact on total leakage. LIMERICK UNIT 1 B 3/4 4-3d Amendment No., CHANNEL FUNCTIONAL of monitor can ri i the a1 rm j red RCS I ka rm their int and I ati ve a CHANN L CALIBRATION of required lea detection 1 bration the accuracy of the instrument ruments I ted in i inment. primary containment pres ure and temperature for fhe allowable lea rates from the reactor coolant system have been based on the nd experimentally observed behavior of cracks in pipes. fhe normally round leakage due to equipment design and the detection capability of the instrumentation for determining system lea was also considered. The evidence obtained from experiments s that for leakage somewhat greater than that specified for UNlDENTI lED LEAKAGE the probability is small that the imperfection or rack associated with such lea would grow rapidly. However, in all cases, if the leakage rates exceed the values specified or the leakage is located and known to be PRESSURE BOUNDARY LEAKAGE, the reactor will be shutdown to al low further investigation and corrective action. The limit of 2 gpm increase in UNIDENTIFIED LEAKAGE over a 24 hour riod and the monitoring of drywell floor drain sump and drywel1 equipment drain tank ow rate at least once every eight (8) hours conforms with NRC staff positions specified in NRC Generic Letter 88-01, "NRC Position on IGSCC in BWR Austenitic Stainless Steel Piping," as revised by NRC Sa Evaluation dated March 6, 1990. The ACTION requirement for the 2 gpm increase in UNIDENTIFIED LEAKAGE limit ensures that such leakage is identified or a plant shutdown is initiated to allow further investigation and corrective action. Once identified, reactor operation may continue dependent upon the impact on tota 1 lea ka ge. LIMERICK - UNIT 1 B 3/4 4-3d Amendment No. -+/-4-{},.~

REAC 10k [00 LAN I [YE I EM ll/V3LS Li[s3LtJ.LLoUCLLLCiJJL+/-J1iJL1L illtIL!!OIU ER 1.1 1.1 k ter the prteiinance of a CHANNEL IIJNC I I0NAL ELEE of the roqu rod REE I delert ion ristrmnrarion. Ihe test ensures that the non I tors can oerform their

nt len ii he fei red abner.

he test il so von t lea the a 1 arm setpoi nt and relative rccuri C y ot the instrument string. [hi a ER a for the performance it a CHANNEL CAL IBRAI ION ot requl red leakaqe detection natrumnenitatmun rhanriel a. he calibration yen ties the accuracy of the instrument

string, including the instruments located inside containment.

1.3. I his ER prey desa tout no check of primary cunita nment pressure and temperature for indirect evidence of RCS 1 eakage. REF ER E N C E S LOS U[SAR, Regu 1 a tory [CS

UFSAR, I (

UI SAR ten LOS UFSAR, Section 5.2.5.2.1.4 LOS UI aAR Sf rtion 5 / 5 2 1 1(2) GEAP562O, April 1968. NlJREGi5/O6/, October [975. 5.2.5.6. ,1T J 3/4 4 3 2 EWfWA1 IONAL LEAKACE [he allowable leakage rates from the reactor coolant system have been based on the predicted and experimentally observed behavior of cracks in pipes. The normally expected background leakage due to equi pment design and the detection capability of the ins trumenta [ion for determi ni rig system leakage was a iso considered. The evidence ubta I nod trout 1 xperi merits suggests that for leakage somewhat greater than that aped Lied for IJNIDENFIFIED LEAKAGE the probability is small that the imperfection or crack associated with such leakage would grow rapidly.

However, in all

cases, if the leakage rates exceed the values specified or the leakage is located and known to be PRESSURE BOIJNDARY

LEAKAGE, the reactor wi 11 he shutdown to allow further investigation and corrective action.

The 1 imi t of 2 gpm increase in UNIDENTIFIED LEAKAGE over a 24-hour period and the monitoring of drywell floor drain sump and drywell equipment drain tank flow rate at least once every eight (8) hours conforms with NRC staff positions specified in NRC Generic Letter 88-01, NRC Position on IGSCC in BWR Austenitic Stainless Steel

Piping, as revised by NRC Safety Evaluation dated March 6, 1990.

[he ACTION requirement for the 2 gpm increase in IJNIDENTIFIED LEAKAGE limit ensures that such leakage is identified or a plant shutdown is initiated to allow further investigation and corrective action. Once identified, reactor operation may continue dependent upon the impact on total leakage. 2. 4 i( t i;io Seition 5 2 5 2 1 3 L ) f) LIMERICK UNIE 2 B 3/4 4-3d Amendment 403, + 4 .R_ FUNCTIONAL I f trlat the moni tor j i t I ka t j r rforma of a CHANNEL CAL BRATION of required I libra ion v rifi Ule (curacy of the in trument loca in containment. mary containment pressure and ra tu for .. 5.1*~=5 Hay iCY.~~ LGS UFSAR, 5.2.5.2.1.4 LGS U ion ....1. 1( GE/\\P ,ri I 968. NUREG-75/067, October 1975. Lion .2..6. fhe Ilowabl from the reactor coolant have been based on the predicted and experimentally observed behavior of cracks in pes. The normally ba round I due to design and the ion capabili of the instrumentation for determining system ea was also considered. The evidence obtained from rimen that for lea somewhat greater than that ified for UNIDENTIFIED LEAKAGE the probability i small that the i ion or rack a sociated with uchlea would grow rapidly. However, in all cases, if the I rates exceed the values specified or the lea is located and known to be PRESSURE BOUNDARY LEAKAGE, the reactor will be shutdown to al low further investigation and corrective tion. The limit of 2 gpm increa in UNIDENTI lED LEAKAGE over a 24-hour period and the monitoring of drywell floor drain sump and drywell equi drain tank flow rate at least once every eight (8) hours conforms with NRC staff positions peci ied in NRC Generic Letter 88 01, "NRC Position on IGSCC in BWR Austenitic Stainl s I Piping," as revised by NRC Sa Evaluation dated March 6, 1990. The ACTION requirement for the 2 gpm increase in UNIDENTIFIED LEAKAGE limit ensures that such 1 kage is identified or a plant shutdown is initiated to allow further investigation and corrective action. Once identified, reactor operation may continue upon the impact on total leakage. LIMERICK UNIT 2 B 3/4 4-3d Amendment +GJ, ~

Insert 5 Revision 0, Reactor Coolant Pressure Boundary Leakage Detection Systems, May 1973. Insert 6 9. LGS UFSAR, Section 5,2,52.1,5 Insert 5 Revision 0, "Reactor Coolant Pressure Boundary Leakage Detection Systems," May 1973. Insert 6 9. LGS UFSAR, Section 5.2.5.2.1.5}}

v t e Letter Sequence Request
TAC:ME5993, Revise BWR Operability Requirements and Actions for RCS Leakage Instrumentation (Approved, Closed)
Initiation Request Acceptance Administration Questions Answers Results Approval Other:
MONTHYEAR2011-04-06 [Table View]

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