RS-05-103, License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50 .60, Acceptance Criteria for Fracture Prevention Measures For..
ML052780469 | |
Person / Time | |
---|---|
Site: | Byron, Braidwood |
Issue date: | 10/03/2005 |
From: | Jury K Exelon Generation Co, Exelon Nuclear |
To: | Document Control Desk, Office of Nuclear Reactor Regulation |
References | |
RS-05-103 WCAP-16143-Np | |
Download: ML052780469 (101) | |
Text
Exelon Generation vvww .exeloncorp .com e - - o WiT)field Road Ile, I L 60555 10 CFR 50 .12 10 CFR 50 .90 RS-05-103 October 3, 2005 U. S . Nuclear Regulatory Commission Attn: Document Control Desk Washington, DC 20555-0001 Braidwood Station, Units 1 and 2 Facility Operating License Nos. NPF-72 and NPF-77 NRC Docket Nos. STN 50-456 and STN 50-457 Byron Station, Units 1 and 2 Facility Operating License Nos. NPF-37 and NPF-66 NRC Docket Nos. STN 50-454 and STN 50-455 Reactor
Subject:
License Amendment Request Regarding Coolant System Pressure and Report Request for Exemption from 10 CFR 50 .60, Temperature Limits and "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation"
References:
(1) Letter from M . Chawla (USNRC) to 0. D. Kingsley (Exelon Generation Company, LLC), "Issuance of Exemption from the Requirements of 10 CFR 50 Part 60 and Appendix G for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2," dated August 8, 2001 (2) Letter from L. B . Marsh (USNRC) to K. W. Singer (Tennessee Valley Authority), "Sequoyah Nuclear Plant, Units 1 and 2, Exemption from the Requirements of 10 CFR Part 50, Appendix G," dated July 7, 2004 Letter from C. Gratton (USNRC) to D. E. Grissette (Southern Nuclear Operating Company, Inc.), "Vogtle Electric Generating Plant, Units 1 and 2
- Issuance of Exemption and Amendments RE : Request to Revise Technical Specifications and Pressure Temperature Limits Report and Relocate the Cold Overpressure Protection System (COPS) Arming Temperature," dated March 28, 2005 (4) Technical Specification Task Force (TSTF) change traveler TSTF419, "Revise PTLR Definition and References in ISTS 5 .6 .6, RCS PTLR,"
Revision 0 In accordance with 10 CFR 50 .90, "Application for amendment of license or construction permit," Exelon Generation Company, LLC (EGC) is requesting an amendment to Appendix A, Technical Specifications (TS), of Facility Operating License Nos. NPF-72, NPF-77, NPF-37, and NPF-66 for Braidwood Station, Units 1 and 2, and Byron Station, Units 1 and 2, respectively .
The proposed amendment would (1) revise the TS 1 .1, "Definitions," description of the Pressure
U . S . Nuclear Regulatory Commission October 5, 2005 Page 2 and Temperature Limits Report (PTLR) by deleting reference to specifications containing limits in the PTLR ; (2) revise the administrative controls TS 5 .6.6, "Reactor Coolant System (RCS)
Pressure and Temperature Limits Report (PTLR)," by requiring the NRC approval documents to be identified by date and Topical Reports to be identified by number and title in accordance with Reference 4; and (3) add Westinghouse Electric Company, LLC, report WCAP-1 6143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," to the list of analytical methods provided in TS 5.6.6.
In support of the proposed amendment, and in accordance with 10 CFR 50 .12, "Specific exemptions," EGC is also requesting an exemption from 10 CFR 50 .60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation."
Specifically, the requested exemption will allow the use of WCAP-1 6143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2,"
dated November 2003 in calculating the reactor pressure vessel (RPV) pressure-temperature (P-T) limits for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, in lieu of 10 CFR 50, Appendix G, "Fracture Toughness Requirements," paragraph IV .A.2.c as required by 10 CFR 50 .60(a) .
EGC has received approval to use the American Society of Mechanical Engineers (ASME),
Boiler and Pressure Vessel (B&PV) Code Case N-640, "Alternative Reference Fracture Toughness for Development of P-T Limit Curves," which provides higher allowable pressure limits through the entire range of operating temperatures (i.e ., Reference 1). The metal temperature requirement of the RPV closure head flange specified in 10 CFR 50, Appendix G ;
however, restricts the allowable pressure at temperatures below the reference nil-ductility transition temperature (RTNDT)+1200 F. The continued operation with these P-T limits, without the relief provided by WCAP-1 6143, would unnecessarily restrict the P-T operating window for Byron Station Units, 1 and 2, and Braidwood Station, Units 1 and 2. The methodology in WCAP-1 6143 eliminates the minimum temperature requirement for the highly stressed region of the closure flange for normal operation when the pressure exceeds 20 percent of the pre-service hydrostatic pressure . EGC has determined that the use of WCAP-16143 will require NRC approval of an exemption to 10 CFR 50 .60(a) .
Similar exemption requests were previously granted for Sequoyah Nuclear Plant, Units 1 and 2 Electric (i .e., Reference 2), and Vogtle Generating Plant, Units 1 and 2 (i .e ., Reference 3).
The attached amendment request and exemption request are subdivided as shown below.
Attachment 1 provides an evaluation of the proposed changes.
Attachments 2-A and 2-B include the marked-up TS pages with the proposed changes indicated for Braidwood Station and Byron Station, respectively .
Attachments 3-A and 3-B include the associated revised TS pages with the proposed changes incorporated for Braidwood Station and Byron Station, respectively .
Attachment 4 provides the justification for the exemption request . As described in Attachment 1, EGC has concluded that for the reasons specified in the attachment, special circumstances, as defined in 10 CFR 50 .12 exist; that the granting of the requested exemption will not present an undue risk to the health and safety of the public ; and that the
U . S. Nuclear Regulatory Commission October 5, 2005 Page 3 granting of the requested exemption is consistent with the common defense and security.
An environmental assessment of the requested exemption is provided in Attachment 4.
Attachment 5 provides a supporting affidavit signed by Westinghouse Electric Company LLC, the owner of proprietary information provided in Attachment 7. The affidavit sets forth the basis on "which the information may be withheld from public disclosure by the NRC and addresses with specificity the considerations listed in paragraph (b)(4) of 10 CFR 2 .390, "Public inspections, exemptions, requests for withholding ." Accordingly, it is respectfully requested that the information which is proprietary to Westinghouse be withheld from public disclosure in accordance with 10 CFR 2.390 . Also enclosed are a Westinghouse authorization letter, CAW-05-2033, Proprietary Information Notice and Copyright Notice .
Attachment 6 provides a non-proprietary version of WCAP-1 6143 . Attachment 7 provides the proprietary version of WCAP-16143 .
The current P-T curves are valid until 17 .6 effective full power years (EFPY) and 17.5 EFPY for Byron Station, Units 1 and 2, respectively, and until 16 EFPY for Braidwood Station, Units 1 and 2. Current estimates indicate that Byron Station, Unit 1, will reach 17.6 EFPY early in November 2006 . The license amendment and exemption are desired prior to expiration of these curves to allow implementation of the new P-T curves . Therefore, EGC requests that approval of this license amendment and exemption request be granted prior to October 1, 2006, to allow sufficient time to develop and implement new P-T curves . Following NRC approval, the amendment will be implemented within 30 days. After license amendment implementation, the Braidwood Station and Byron Station PTLRs will be revised in a timeframe to assure issuance prior to exceeding each unit's current EFPY limit . The revised PTLRs will be submitted to the NRC in accordance with the requirements of TS 5.6 .6.c.
The proposed amendment has been reviewed by the Braidwood Station and the Byron Station Plant Operations Review Committees and approved by their respective Nuclear Safety Review Boards in accordance with the requirements of the EGC Quality Assurance Program .
EGC is notifying the State of Illinois of this application for a change to the TS by sending a copy of this letter and its attachments to the designated State Official .
Should you have any questions about this letter, please contact J . A. Bauer at (630) 657-2801 .
I declare under penalty of perjury that the foregoing is true and correct. Executed on the 3' day of October 2005.
Keith R. Jury Director, Licensing and Regulatory Affairs
U . S. Nuclear Regulatory Commission October 5, 2005 Page 4 : Evaluation of Proposed Changes -A: Markup of Proposed Technical Specifications Page Changes for Braidwood Station -B : Markup of Proposed Technical Specifications Page Changes for Byron Station -A: Revised Technical Specification Pages for Braidwood Station -B: Revised Technical Specification Pages for Byron Station : Justification for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" : Application for Withholding and Affidavit : Non-proprietary Version of WCAP-16143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2" : Proprietary Version of WCAP-1 6143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2"
ATTACHMENT 1 Evaluation of Proposed Changes INDEX 1 .0 DESCRIPTION
2.0 PROPOSED CHANGE
3.0 BACKGROUND
4.0 TECHNICAL ANALYSIS
5.0 REGULATORY ANALYSIS
5.1 No Significant Hazards Consideration 5 .2 Applicable Regulatory Requirements/Criteria 6 .0 ENVIRONMENTAL CONSIDERATION 7 .0 REFERENCES
ATTACHMENT 1 Evaluation of Proposed Changes 1 .0 DESCRIPTION Exelon Generation Company, LLC (EGC) is requesting an amendment to Appendix A, Technical Specifications (TS), of Facility Operating License Nos . NPF-72, NPF-77, NPF-37, and NPF-66 for Braidwood Station, Units 1 and 2, and Byron Station, Units 1 and 2, respectively . The proposed amendment would (1) revise the TS Section 1 .1, "Definitions,"
description of the Pressure and Temperature Limits Report (PTLR) by deleting reference to specifications containing limits in the PTLFV (2) revise the administrative controls TS 5 .6.6, "Reactor Coolant System (RCS) Pressure and Temperature Limits Report (PTLR)," by requiring the NRC approval documents to be identified by date and Topical Reports to be identified by number and title in accordance with Industry/Technical Specification Task Force (TSTF) Standard Technical Specification Change Traveler, TSTF-419 ; "Revise PTLR Definition and References in ISTS 5.6 .6, RCS PTLR," and (3) add Westinghouse Electric Company, LLC, WCAF416143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," to the list of analytical methods provided in TS 5.6.6.
2.0 PROPOSED CHANGE
TS Section 1 .1 TS Section 1 .1 currently defines the PTLR as the unit specific document that provides the reactor vessel pressure and temperature limits including heatup and cooldown rates, and current reactor the pressurizer Power Operated Relief Valve (PORV) lift settings for the vessel fluence period . These pressure and temperature limits shall be determined for each fluence period in accordance with Specification 5 .6 .6 . Unit operation within these limits is addressed in LCO 3.4.3, "RCS Pressure and Temperature (P/T) Limits," and LCO 3 .4 .12, "Low Temperature Overpressure Protection (LTOP) System ."
The proposed change deletes the reference to specifications containing limits in the PTLR.
The TS Section 1 .1 definition of PTLR has been revised to state:
"The PTLR is the unit specific document that provides the reactor vessel pressure and temperature limits including heatup and cooldown rates, and the pressurizer Power Operated Relief Valve (PORV) lift settings for the current reactor vessel fluence period .
These pressure and temperature limits shall be determined for each fluence period in accordance with Specification 5 .6.6."
TS 5.6.6 TS 5.6 .6.b requires that the analytical methods used to determine the RCS pressure and temperature limits shall be those previously reviewed and approved by the NRC, specifically those described in NRC letters dated January 21, 1998, "Byron Station Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for Referencing of Pressure Temperature Limits Report," and August 8, 2001, "Issuance of Exemption from the requirements of for 10 CFR 50 Part 60 and Appendix G Byron Station, Units 1 and 2 and Braidwood Station, Units 1 and 2."
The proposed change reformats TS 5.6 .6.b and adds WCAP-16143 as an analytical method approved by the NRC as follows :
Page 2 of 9
ATTACHMENT 1 Evaluation of Proposed Changes "The analytical methods used to determine the RCS pressure and temperature limits shall be those previously reviewed and approved by the NRC, specifically those described in the following documents:
1 NRC letter dated January 21, 1998, "Byron Station Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for Referencing of Pressure Temperature Limits Report,"
- 2. NRC letter dated August 8, 2001, Issuance of Exemption from the requirements of 10 CFR 50 Part 60 and Appendix G, for Byron Station, Units 1 and 2 and Braidwood Station, Units 1 and 2,"
- 3. Westinghouse WCAP-1 6143, "Reactor Vessel Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," and
- 4. The PTLR will contain the complete identification for each of the TS referenced Topical Reports used to prepare the PTLR (i .e., report number, title, revision, date, and any supplements) ; and ."
3.0 BACKGROUND
NRC Generic Letter 96-03, "Relocation of the Pressure and Temperature Limit Curves and Low Temperature Overpressure Protection System Limits," dated January 31, 1996, allowed licensees to relocate the pressure temperature (P-T) limit curves and the Low Temperature Overpressure Protection (LTOP) System limits from the TS to a PTLR . The methodology used to determine the P-T limit curves and the LTOP System limit parameters is required to comply with the specific requirements of Appendices G, "Fracture Toughness Requirements," and H, "Reactor Vessel Material Surveillance Program Requirements," to 10 CFR 50, "Domestic Licensing of Production and Utilization Facilities," be documented in an NRC approved topical report or an NRC approved plant-specific submittal, and be incorporated by reference into the TS . Subsequent changes in the methodology must be approved by a license amendment. The NRC approved the relocation of the Byron and Braidwood pressure and temperature limit curves and LTOP system limits in Reference 2.
TSTF419 was submitted by the industry to remove duplication in the requirements of TS 5.6.6 and the definition of the PTLR, and to allow licensees to identify topical reports referenced in TS 5.6.6 by number and title only. A requirement was added in a reviewer's note to require that the complete citation in the PTLR for each topical report include the report number, title, revision, date, and any supplements. TSTF419 received NRC approval on March 21, 2002 .
EGC is also requesting an exemption from 10 CFR 50 .60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation ."
Specifically, the requested exemption will allow the use of WCAP-16143 in calculating the reactor pressure vessel (RPV) P-T limits for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, in lieu of 10 CFR 50, Appendix G, "Fracture Toughness Requirements," paragraph IV .A.2.c as required by 10 CFR 50.60(a) . The change in methodology must be approved by the NRC in a license amendment. This amendment
ATTACHMENT 1 Evaluation of Proposed Changes request, therefore, proposes to incorporate WCAP-16143 in the approved methodologies listed in TS 5 .6 .6.b.
4.0 TECHNICAL ANALYSIS
The TS Section 1 .1 definition of PTLR identifies the specifications in which the pressure and temperature limits are addressed. TS 5 .6.6 .a requires that the individual specifications that address RCS pressure and temperature limits be referenced . The proposed changes to the definition eliminate duplication between the TS Section 1 .1 definition of PTLR and TS 5.6.6.
This change is consistent with TSTF-419 .
The revision to ITS 5 .6.6.b to allow the Topical Reports to be identified by number and title would allow EGC to use current Topical Reports to support limits in the PTLR without having to submit an amendment to the facility operating license each time the Topical Report is revised provided there is no change to the approved methodology. The PTLR would provide specific information identifying the particular Topical Reports used to determine the P-T limits or the LTOP System limits . TS 5.6.6.b provides the assurance that only the approved methodologies contained in the referenced Topical Reports will be used for the determination of the P-T limits or LTOP System limits . This proposed change is consistent with TSTF419 .
10 CFR 50, Appendix G, contains requirements for the metal temperature of the closure head flange and vessel flange regions . This rule states that the metal temperature of the closure flange regions must exceed the material unirradiated reference nil-ductility transition temperature (RTNDT) by at least 120OF for normal operation when the pressure exceeds 20 percent of the pre-service hydrostatic test pressure . The margin of 120'F and the pressure limitation of 20 percent of hydrotest pressure were developed using the Kia fracture toughness, in the mid 1970s, to ensure that appropriate margins would be maintained .
Since 1974, additional knowledge has been gained about RPV materials, which demonstrates the lower bound fracture toughness provided by the Kia curve is well beyond the margin of safety required to protect against potential RPV failure . Use of the methodology in WCAP-16143 eliminates the requirement that the minimum temperature of the highly stressed region of the closure flange exceed the unirradiated RTNDT by 120'F for normal operation when the pressure exceeds 20 percent of the pre-service hydrostatic pressure .
The proposed methodology for the Byron Station and Braidwood Station P-T limits relies, in part, on American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel (B&PV) Code Case N-640, "Alternative Reference Fracture Toughness for Development of P-T Limit Curves,Section XI, Division 1," which allows the use of Kjc fracture toughness curve rather than the K,,, curve. EGC received approval to use Code Case N-640 in Reference 3 and Reference 4 . P-T limits developed using the Kic fracture toughness curve permit a much higher allowable pressure through the entire range of temperatures . The benefit is negated; however, at temperatures below RTNDT +120°F because of the additional flange requirement of 10 CFR 50, Appendix G . 10 CFR 50, Appendix G, restricts the ability to raise the pressurizer power operated relief valve (PORV) setpoint as temperature rises by restricting the setpoint to the flange temperature limit rather than the ASME Code Case N-640 P-T limit.
ATTACHMENT I Evaluation of Proposed Changes Using the KI, fracture toughness, WCAP-1 6143 presents analyses that show that there is significant margin between the applied stress intensity factor at boltup and the material fracture toughness at cracks postulated to exist in the highest stress region of the closure head/flange region . The analyses also showed the boltup temperature requirement for Braidwood, Units 1 and 2, and Byron, Units 1 and 2, could be performed at 60'F or higher, easily justifying bolt up at ambient temperature. The results presented in WCAP-1 6143 demonstrate that the 10 CFR 50, Appendix G RPV closure head flange requirement can be eliminated and appropriate fracture margins are still maintained .
Applying WCAP-16143 methodology to the P-T curves will enhance overall plant safety by expanding the P-T operating window, especially in the region of low temperature operations .
The two primary safety benefits that would be realized are a reduction in the potential challenges to the LTOP system and a reduction in the risk of damaging the reactor coolant pump seals. This will produce a significant improvement in plant safety by reducing the probability of an inadvertent reduction in reactor coolant inventory, and in easing the burden on the operators.
5.0 REGULATORY ANALYSIS
5.1 NO SIGNIFICANT HAZARDS CONSIDERATION According to 10 CFR 50.92, "Issuance of amendment," paragraph (c), a proposed amendment to an operating license involves no significant hazards consideration if operation of the facility in accordance with the proposed amendment would not:
Involve a significant increase in the probability or consequences of an accident previously evaluated ; or (2) Create the possibility of a new or different kind of accident from any accident previously evaluated ; or Involve a significant reduction in a margin of safety .
In support of this determination, an evaluation of each of the three criteria set forth in 10 CFR 50.92 is provided below regarding the proposed license amendment.
Overview In accordance with 10 CFR 50 .90, "Application for amendment of license or construction permit," Exelon Generation Company, LLC (EGC) is requesting an amendment to Appendix A, Technical Specifications (TS), of Facility Operating License Nos. NPF-72, NPF-77, NPF-37, and NPF-66 for Braidwood Station, Units 1 and 2, and Byron Station, Units 1 and 2, respectively .
The proposed amendment would (1) revise the TS 1 .1, "Definitions," description of the Pressure and Temperature Limits Report (PTLR) by deleting reference to specifications containing limits in the PTLR ; (2) revise the administrative controls TS 5.6.6, "Reactor Coolant System (RCS) Pressure and Temperature Limits Report (PTLR)," by requiring the NRC approval documents to be identified by date and Topical Reports to be identified by number and title in accordance with TSTF-419 ; and (3) add Westinghouse Electric Page 5 of 9
ATTACHMENT 1 Evaluation of Proposed Changes Company, LLC, WCAP-16143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," to the list of analytical methods provided in TS 5 .6.6.
EGC has evaluated whether or not a significant hazards consideration is involved with the proposed TS changes by focusing on the three criteria set forth in 10 CFR 50 .92 as discussed below:
Criteria 1 . Does the proposed change involve a significant increase in the probability or consequences of an accident previously evaluated?
Response: No.
The proposed change to the definition of PTLR is considered to be an editorial change because the requirements of TES 5.6 .6 continue to specify the Limiting Conditions for Operation that address operation within the P-T limits .
The proposed changes to reference only the Topical Report number and title do not alter the use of the analytical methods used to determine the pressure temperature (P-T) limits or Low Temperature Overpressure Protection (LTOP) System setpoints that have been reviewed and approved by the NRC . This method of referencing Topical Reports would allow the use of current Topical Reports to support limits in the PTLR without having to submit an amendment to the operating license provided there is no change to the approved methodology. TS 5 .6.6.b requires that the analytical methods used to determine the P-T limits be those previously reviewed and approved by the NRC .
Implementation of revisions to Topical Reports would still be reviewed in accordance with 10 CFR 50.59, "Changes, tests and experiments," and where required receive NRC review and approval .
The use of WCAP-1 6143, following approval by the NRC, for generation of P-T limits will continue to ensure that reactor pressure vessel integrity is maintained under all conditions .
The proposed changes do not adversely affect accident initiators or precursors nor alter the design assumptions, conditions, or configuration of the facility or the manner in which the plant is operated and maintained . The proposed changes do not alter or prevent the ability of structures, systems, and components (SSCs) from performing their intended function to mitigate the consequences of an initiating event within the assumed acceptance limits . The proposed changes do not affect the source term, containment isolation, or radiological release assumptions used in evaluating the radiological consequences of an accident previously evaluated. The proposed changes do not increase the types or amounts of radioactive effluent that may be released offsite, nor significantly increase individual or cumulative occupational/public radiation exposures .
The proposed changes are consistent with safety analysis assumptions and resultant consequences .
Based on the above discussion, the proposed changes do not involve an ncrease he probability or consequences of an accident previously evaluated.
Page 6 of 9
ATTACHMENT 1 Evaluation of Proposed Changes
- 2. Does the proposed change create the possibility of a new or different kind of accident from any accident previously evaluated?
Response: No.
The proposed change to the definition of PTLR is considered to be an editorial change because the requirements of TS 5.6.6 continue to specify the Limiting Conditions for Operation that address operation within the P-T limits .
The proposed changes to reference only the Topical Report Number and title do not alter the use of the analytical methods used to determine the P-T limits or LTOP setpoints that have been reviewed and approved by the NRC. This method of referencing Topical Reports would allow the use of current Topical Reports to support limits in the PTLR without having to submit an amendment to the operating license provided there is no change to the approved methodology. TS 5 .6.6.b requires that the analytical methods used to determine the P-T limits be those previously reviewed and approved by the NRC. Implementation of revisions to Topical Reports would still be reviewed in accordance with 10 CFR 50.59 and where required receive NRC review and approval .
The use of WCAP-16143, following approval by the NRC, for generation of P-T limits will continue to ensure that reactor pressure vessel integrity is maintained under all conditions.
The proposed changes will allow the use of a new NRC-approved methodology for the calculation of P-T limits . However, the changes do not involve a physical alteration of the plant {i.e., no new or different type of equipment will be installed) and do not introduce a new mode of plant operation . Safety functions associated with P-T limits and LTOP setpoints will continue to function as previously assumed in accident analyses .
Based on this evaluation, the proposed change does not create the possibility of a new or different kind of accident from any accident previously evaluated .
- 3. Does the proposed change involve a significant reduction in a margin of safety?
Response : No .
The proposed change to the definition of PTLR is considered to be an editorial change because the requirements of TS 5.6.6 continue to specify the Limiting Conditions for Operation that address operation within the P-T limits .
The proposed the changes to reference only the Topical Report Number and title do not alter use of the analytical methods used to determine the P-T limits or LTOP setpoints that have been reviewed and approved by the NRC. This method of referencing Topical Reports would allow the use of current Topical Reports to support limits in the PTLR without having to submit an amendment to the operating license provided there is no change to the approved methodology. TS 5 .6.6.b requires that the analytical methods used to determine the P-T limits be those previously reviewed and Page 7 of 9
ATTACHMENT 1 Evaluation of Proposed Changes approved by the NRC . Implementation of revisions to Topical Reports would still be reviewed in accordance with 10 CFR 50.59 and where required receive NRC review and approval .
The P-T limits provide assurance that the reactor pressure vessel is maintained . The use of WCAP-1 6143, following approval by the NRC, for generation of P-T limits will continue to ensure that reactor pressure vessel integrity is maintained under all conditions .
The proposed changes do not alter the manner in which safety limits, limiting safety system settings or limiting conditions for operation are determined . Changes to setpoints at which protective actions are initiated that are allowed by the use of WCAP-1 6143 are evaluated in accordance with 10 CFR 50.59 and where required receive NRC review and approval. Sufficient equipment remains available to actuate upon demand for the purpose of mitigating an analyzed event .
Based on this evaluation, the proposed change does not involve a significant reduction in a margin of safety .
Therefore, the proposed changes do not involve a significant hazards consideration under the criteria set forth in 10 CFR 50.92(c) .
5.2 APPLICABLE REGULATORY REQUIREMENTS/CRITERIA 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation," part (a) requires that the fracture toughness and material surveillance program for the reactor coolant system pressure boundary must meet the requirements of 10 CFR 50, Appendix G, "Fracture Toughness Requirements ."
10 CFR 50.60(b) allows alternatives to the requirements as specified in 10 CFR 50.12, "Specific exemptions." EGC has determined that an exemption is required to allow the use of WCAP-1 6143 in lieu of 10 CFR 50, Appendix G, paragraph IV.A.2 .c as required by 10 CFR 50.60(a) . The bats and justification for the exemption is provided as Attachment 4 to this submittal. Inclusion of WCAP-16143 in the TS following NRC approval continues to meet the requirements of 10 CFR 50.60 and 10 CFR 50 .12 .
6.0 ENVIRONMENTAL CONSIDERATION
A review has determined that the proposed amendment would change a requirement with respect to installation or use of a facility component located within the restricted area, as defined in 10 CFR 20, "Standards for protection against radiation," or would change an inspection or surveillance requirement. However, the proposed amendment does not involve (i) a significant hazards consideration, (ii) a significant change in the types or significant increase in the amounts of any effluent that may be released offsite, or (iii) a significant increase in individual or cumulative occupational radiation exposure .
Accordingly, the proposed amendment meets the eligibility criterion for categorical exclusion set forth in paragraph (c)(9) of 10 CFR 51 .22, "Criterion for categorical exclusion ;
identification of licensing and regulatory actions eligible for categorical exclusion or otherwise not requiring environmental review ." Therefore, pursuant to 10 CFR 51 .22(b), no environmental impact statement or environmental assessment need be prepared in connection with the proposed amendment.
Page 3 of 9
ATTACHMENT 1 Evaluation of Proposed Changes
7.0 REFERENCES
1 . Letter from G . F . Dick (USNRC) to 0 . D . Kingsley (Commonwealth Edison Company),
"Issuance of Amendments," dated January 23, 1998 2 . Letter from R. A. Capra (USNRC) to 0. D. Kingsley (Commonwealth Edison Company),
"Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for Referencing of Pressure Temperature Limits Report," dated January 21, 1998 from . Chawla (USNRC) to 0. D. Kingsley (Exelon Generation Company, LLC),
- 3. Letter M "Issuance of Exemption from the Requirements of 10 CFR 50 Part 60 and Appendix G, for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2," dated August 8, 2001
"Issuance of Amendments ; Revised Pressure-Temperature Limits Methodology; Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2," dated October 4, 2004
- 5. Technical Specification Task Force (TSTF) change traveler TSTF-419, "Revise PTLR Definition and References in ISTS 5 .6.6, RCS PTLR," Revision 0
Attachment 2-A BRAIDWOOD STATION UNITS 1 AND 2 Docket Nos. 50-456 and 50-457 License Nos . NPF-72 and NPF-77 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Markup of Technical Specifications Pages 1 .1-6 5.6-5
Definitions 1 .1 1 .1 Definitions PRESSURE AND The PTLR is the unit specific document that TEMPERATURE LIMITS provides the reactor vessel pressure and REPORT (PTLR) temperature limits including heatup and cooldown rates, and the pressurizer Power Operated Relief Valve (PORV) lift settings for the current reactor vessel fluence period . These pressure and temperature limits shall be determined for each fluence period in accordance with j
Sciecification 5 .6 .6 . Unjj operate RCS within Press t ese limIts is add ssed in .33, 37,R i ~s re (P/T)Jits," a L CO 3 .4 . 2 LCO
"'ow Temper e Over suit 1- U=UU UH 4 stem ."
QUADRANT POWER TILT QPTR shall be the ratio of the maximum upper RATIO (QPTR) excore detector calibrated output to the average of the upper excore detector calibrated outputs, or the ratio of the maximum lower excore detector calibrated output to the average of the lower excore detector calibrated outputs, whichever is greater .
RATED THERMAL POWER RTP shall be a total reactor core heat transfer (RTP) rate to the reactor coolant of 3586 .6 MWt .
REACTOR TRIP The RTS RESPONSE TIME shall be that time interval SYSTEM (RTS) RESPONSE from when the monitored parameter exceeds its RTS TIME trip setpoint at the channel sensor until loss of stationary gripper coil voltage . The response time may be measured by means of any series of sequential, overlapping, or total steps so that the entire response time is measured . In lieu of measurement, response time may be verified for selected components provided that the components and methodology for verification have been previously reviewed and approved by the NRC .
BRAIDWOOD - UNITS 1 & 2 1 .1 - 6 Amendment
Reporting Requirements 5 .6 5 .6 Reporting Requirements 5 .6 .6 Reactor Coolant System (RCS) PRESSURE AND TEMPERATURE LIMITS REPORT (PTLR)
- a. RCS pressure and temperature limits for heat up, cooldown, low temperature operation, criticality, and hydrostatic testing as well as heatup and cooldown rates, and Power Operated Relief Valve (PORV) lift settings shall be established and documented in the PTLR for the following :
the following LCO 3 .4 .3, "RCS Pressure and Temperature (PIT) Limits," and documents :
LCO 3 .4 .12, "Low Temperature Overpressure Protection (LTOP)
System" ;
The analytical methods used to determine the RCS pressure and temperature limits shall be those previously reviewed-and approved by the NRC, specifically those described in R`I C -
letterO dated January 21, 1998, "Byron Station Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for 2 . NRC letter Referencing of Pressure Temperature Limits Report,_ .
dated y August 8, 2001, "Issuance of Exemption from the requirements of 10 CFR 50 Part 60 and Appendix G for Byron Station, Units 1 and 1 2 and Braidwood Station, Units 1 and 2;,g
- c. The PTLR shall be provided to the NRC upon issuance for each reactor vessel fluence period and for any revision or supplement thereto .
5 .6 .7 Post Accident Monitoring Repor When a report is required by Condition C or H of LCO 3 .3 .3, "Post Accident Monitoring (PAM) Instrumentation," a report shall be submitted within the following 14 days . The report shall outline the preplanned alternate method of monitoring, the cause of the inoperability, and the plans and schedule for restoring the instrumentation channels of the Function to OPERABLE status .
1-1 3 . Westinghouse WCAP-16143, "Reactor Vessel Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," and The PTLR will contain the complete identification for each of the TS referenced Topical Reports used to prepare the PTLR (i .e ., report number, title, revision, date, and any supplements) ; and BRAIDWOOD - UNITS 1 & 2 5 .6 - 5 Amendment
Attachment 2-113 BYRON STATION UNITS 1 AND 2 Docket Nos. 50-454 and 50-455 License Nos . NPF-37 and NPF-66 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Markup of Technical Specifications Pages 1 .1-6 5 .6-5
Definitions 1 .1 1 .1 Definitions PRESSURE AND The PTLR is the unit specific document that TEMPERATURE LIMITS provides the reactor vessel pressure and REPORT (PTLR) temperature limits including heatup and cooldown rates, and the pressurizer Power Operated Relief Valve (PORV) lift settings for the current reactor vessel fluence period . These pressure and temperature limits shall be determined for each fluence period in accordance with Specification 5 .6 .6 .1 Unit opera ti within limits is allssed in. RCS PPresss won C re S r:
an empera (PIT) jits," a LCO 3 .4 ow Temper e Over sure P tection ( TOP) stem ."
QUADRANT POWER TILT QPTR shall be the ratio of the maximum upper RATIO (QPTR) excore detector calibrated output to the average of the upper excore detector calibrated outputs, or the ratio of the maximum lower excore detector calibrated output to the average of the lower excore detector calibrated outputs, whichever is greater .
RATED THERMAL POWER RTP shall be a total reactor core heat transfer (RTP) rate to the reactor coolant of 3586 .6 MWt .
REACTOR TRIP The RTS RESPONSE TIME shall be that time interval SYSTEM (RTS) RESPONSE from when the monitored parameter exceeds its RTS TIME trip setpoint at the channel sensor until loss of stationary gripper coil voltage . The response time may be measured by means of any series of sequential, overlapping, or total steps so that the entire response time is measured . In lieu of measurement, response time may be verified for selected components provided that the components and methodology for verification have been previously reviewed and approved by the NRC .
BYRON --UNITS 1 & 2 1 .1 - 6 Amendment TA
Reporting Requirements 5 .6 5 .6 Reporting Requirements 5 .6 .6 Reactor Coolant System (RCS) PRESSURE AND TEMPERATURE LIMITS REPORT (PTLR~
- a. RCS pressure and temperature limits for heat up, cooldown, low temperature operation, criticality, and hydrostatic testing as well as heatup and cooldown rates, and Power Operated Relief Valve (PORV) lift settings shall be established and documented in the PTLR for the following :
he following ~) LCO 3 :4 .3, "RCS Pressure and Temperature (PIT) Limits," and documents : NCO 3 .4 .12, "Low Temperature Overpressure Protection (LTOP)
System",
The analytical methods used to determine the RCS pressure and temperature limits shall be those previously reviewe and,aDDroved by the NRC, specifically those described inNRC lettedh dated January 21, 1998, "Byron Station Units I and 2, and Braidwood Station, units 1 and a, Acceptance for "2 . NRC letter Referencing of Pressure Temperature Limits Report," 2M*--
q1 1dated kAugust 8, 2001, "Issuance of Exemption from the requirements of 10 CFR 50 Part bu and Appendix U, far Byron Station, and 210 EofD
-Units I and 2 and Braidwood Station, Units 1 The PTLR shall be provided to the NRC upon issuance for each reactor vessel fluence period and for any revision or supplement thereto .
5 .6 .7 Post Accident Monitoring Report When a report is required by Condition C or H of LCO 3 .3 .3, "Post Accident Monitoring (PAM) Instrumentation," a report shall be submitted within the following 14 days . The report shall outline the prebanned alternate method of monitoring, the cause of the inopera ility, and the plans and schedule for restoring the instrumentation channels of the Function to OPERABLE status .
(3 . Westinghouse WCAP-16143, "Reactor Vessel Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," and 4 . The PTLR will contain the complete identification for each of the TS referenced Topical Reports used to prepare the PTLR (i .e ., report number, title, revision, date, and an_y supglements> : and BYRON - UNITS 1 & 2 5 .6 - 5 Amendmen
Attachment 3-A BRAIDWOOD STATION UNITS 1 AND 2 Docket Nos. 50-456 and 50-457 License Nos . NPF-72 and NPF-77 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Revised Technical Specifications Pages 1 .1-6 5.6-5
Definitions 1 .1 1 .1 Definitions PRESSURE AND The PTLR is the unit specific document that TEMPERATURE LIMITS provides the reactor vessel pressure and REPORT (PTLR) temperature limits including heatup and cooldown rates, and the pressurizer Power Operated Relief Valve (PORV) lift settings for the current reactor vessel fluence period . These pressure and temperature limits shall be determined for each fluence period in accordance with Specification 5 .6 .6 .
QUADRANT POWER TILT QPTR shall be the ratio of the maximum upper RATIO (QPTR) excore detector calibrated output to the average of the upper excore detector calibrated outputs, or the ratio of the maximum lower excore detector calibrated output to the average of the lower excore detector calibrated outputs, whichever is greater .
RATED THERMAL POWER RTP shall be a total reactor core heat transfer (RTP) rate to the reactor coolant of 3586 .6 MWt .
REACTOR TRIP The RTS RESPONSE TIME shall be that time interval SYSTEM (RTS) RESPONSE from when the monitored parameter exceeds its RTS TIME trip setpoint at the channel sensor until loss of stationary gripper coil voltage . The response time may be measured by means of any series of sequential, overlapping, or total steps so that the entire response time is measured . In lieu of measurement, response time may be verified for selected components provided that the components and methodology for verification have been previously reviewed and approved by the NRC .
BRAIDWOOD - UNITS 1 & 2 1 .1 - 6 Amendment
Reporting Requirements 5 .6 5 .6 Reporting Requirements 5 .6 .6 Reactor Coolant System (RCS) PRESSURE AND TEMPERATURE LIMITS REPORT (PTLQ
- a. RCS pressure and temperature limits for heat up, cooldown,, low temperature operation, criticality, and hydrostatic testing as well as heatup and cooldown rates, and Power Operated Relief Valve (PORV) lift settings shall be established and documented in the PTLR for the following :
LCO 3 .4 .3, "RCS Pressure and Temperature (P/T) Limits," and LCO 3 .4 .12, "Low Temperature Overpressure Protection (LTOP)
System",
- b. The analytical methods used to determine the RCS pressure and temperature limits shall be those previously reviewed and approved by the NRC, specifically those described in the following documents :
- 1. NRC letter dated January 21, 1998, "Byron Station Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for Referencing of Pressure Temperature Limits Report ;"
NRC letter dated August 8, 2001, "Issuance of Exemption from the requirements of 10 CFR 50 Part 60 and Appendix G for Byron Station, Units 1 and 2 and Braidwood Station, Units 1 and 2,"
- 3. Westinghouse WCAP-16143, "Reactor Vessel Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," and The PTLR will contain the complete identification for each of the TS referenced Topical Reports used to prepare the PTLR (i .e ., report number, title, revision, date, and any supplements) ; and
- c. The PTLR shall be provided to the NRC upon issuance for each reactor vessel fluence period and for any revision or supplement thereto .
5 .6 .7 Post Accident Monitoring Report When a report is required by Condition C or H of LCO 3 .3 .3, "Post Accident Monitoring (PAM) Instrumentation," a report shall be submitted within the following 14 days . The report shall outline the preplanned alternate method of monitoring, the cause of the inoperability, and the plans and schedule for restoring the instrumentation channels of the Function to OPERABLE status .
BRAIDWOOD - UNITS 1 & 2 5 .6 - 5 Amendment
Attachment 3-113 BYRON STATION UNITS 1 AND 2 Docket Nos. 50-454 and 50-455 License Nos . NPF-37 and NPF-66 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Revised Technical Specifications Pages 1 .1-6 5.6-5
Definitions 1 .1 1 .1 Definitions PRESSURE AND The PTLR is the unit specific document that TEMPERATURE LIMITS provides the reactor vessel pressure and REPORT (PTLR) temperature limits including heatup and cooldown rates, and the pressuriZer Power Operated Relief Valve (PORV) lift settings for the current reactor vessel fluence period . These pressure and temperature limits shall be determined for each fluence period in accordance with Specification 5 .6 .6 .
QUADRANT POWER TILT QPTR shall be the ratio of the maximum upper RATIO (OPTR) excore detector calibrated output to the average of the upper excore detector calibrated outputs, or the ratio of the maximum lower excore detector calibrated output to the average of the lower excore detector calibrated outputs, whichever is greater .
RATED THERMAL POWER RTP shall be a total reactor core heat transfer (RTP) rate to the reactor coolant of 3586 .6 MWt .
REACTOR TRIP The RTS RESPONSE TIME shall be that time interval SYSTEM (RTS) RESPONSE from when the monitored parameter exceeds its RTS TIME trip setpoint at the channel sensor until loss of stationary gripper coil voltage . The response time may be measured by means of any series of sequential, overlapping, or total steps so that the entire response time is measured . In lieu of measurement, response time may be verified for selected components provided that the components and methodology for verification have been previously reviewed and approved by the NRC .
BYRON - UNITS 1 & 2 1 .1 - 6 Amendment
Reporting Requirements 5 .6 5 .6 Reporting Requirements 5 .6 .6 Reactor Coolant System (RCS) PRESSURE AND TEMPERATURE LIMITS
.REPORTS PTLR)
- a. RCS pressure and temperature limits for heat up, cooldown, low temperature operation, criticality, and hydrostatic testing as well as heatup and cooldown rates, and Power Operated Relief Valve (PORV) lift settings shall be established and documented in the PTLR for the following :
LCO 3 .4 .3, "RCS Pressure and Temperature (P/T) Limits," and LCO 3 .4 .12, "Low Temperature Overpressure Protection (LTOP)
System",
- b. The analytical methods used to determine the RCS pressure and temperature limits shall be those previously reviewed and approved by the NRC, specifically those described in the following documents :
- 1. NRC letter dated January 21, 1998, "Byron Station Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for Referencing of Pressure Temperature Limits Report,"
- 2. NRC letter dated August 8, 2001, "Issuance of Exemption from the requirements of 10 CFR 50 Part 60 and Appendix G, for Byron Station, Units 1 and 2 and Braidwood Station, Units 1 and 2,"
- 3. Westinghouse WCAP-16143, "Reactor Vessel Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," and
- 4. The PTLR will contain the complete identification for each of the TS referenced Topical Reports used to prepare the PTLR (i .e ., report number, title, revision, date, and any supplements) ; and The PAR shall be provided to the NK upon issuance for each reactor vessel fluence period and for any revision or supplement thereto .
5 .6 .7 Post Accident Monitoring Report When a report is required by Condition C or H of LCO 3 .3 .3, "Post Accident Monitoring (PAM) Instrumentation," a report shall be submitted within the following 14 days . The report shall outline the preplanned alternate method of monitoring, the cause of the inoperability, and the plans and schedule for restoring the instrumentation channels of the Function to OPERABLE status .
BYRON - UNITS 1 & 2 5 .6 - 5 Amendment
Attachment 4 BRAIDWOOD STATION UNITS 1 AND 2 Docket Nos. 50-456 and 50-457 License Nos . NPF-72 and NPF-77 and BYRON STATION UNITS 1 AND 2 Docket Nos . 50-454 and 50-455 License Nos. NPF-37 and NPF-66 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Justification for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation'
Attachment 4 Justification for Exemption from 10 CFR 50.60 Specific Exemption Request In accordance with 10 CFR 50.12, "Specific exemptions," Exelon Generation Company, LLC (EGC) is requesting an exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation ."
Specifically, the requested exemption will allow the use of Westinghouse Electric Company Report, WCAP-1 6143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," in calculating the reactor pressure vessel (RPV) pressure-temperature (P-T) limits for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, in lieu of 10 CFR 50, Appendix G, "Fracture Toughness Requirements," paragraph IV.A.2.c as required by 10 CFR 50.60(a).
Basis For Exemption Request The previous methodology used to generate the Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, Pressure Temperature Limits Report (PTLR), which contains the P-T curves and the low temperature overpressure protection (LTOP) system limits, is based on the methodology approved in a Safety Evaluation transmitted to EGC in a letter from R. A. Capra (USNRC) to 0 . D. Kingsley (Commonwealth Edison Company),
"Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, Acceptance for Referencing of Pressure Temperature Limits Report," dated January 21, 1998. This approved methodology includes the use of Westinghouse Electric Company Report, WCAP-14040-NP-A, "Methodology Used to Develop Cold Overpressure Mitigating System Setpoints and RCS Heatup and Cooldown Limit Curves," Revision 1 ; American Society of Mechanical Engineers (ASME), Boiler and Pressure Vessel (B&PV) Code Case N-514, "Low Temperature Overpressure,Section XI, Division 1 ;" and ASME B&PV Code,Section XI, Appendix G, 1996 Addenda .
EGC received approval to use ASME B&PV Code Cases N-640, "Alternative Reference Fracture Toughness for Development of P-T Limit Curves,Section XI, Divisionl," and N-588, "Alternative to Reference Flaw Orientation of Appendix G for Circumferential Welds in Reactor Vessels,Section XI, Division 1," in a letter from M . Chawla (USNRC) to
- 0. D. Kingsley (Exelon Generation Company, LLC), "Issuance of Exemption from the Requirements of 10 CFR 50 Part 60 and Appendix G for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2," dated August 8, 2001 . EGC performed a change applying Code Cases N-640 and N-588 to the Byron Station and Braidwood Station PTLRs under 10 CFR 50 .59, "Changes, tests, and experiments," to extend the applicability time of the Byron Station and Braidwood Station heat up and cool down curves by two effective full power years . The revised Byron Station and Braidwood Station PTLRs were submitted to the NRC in letters from S . E. Kuczynski (Exelon Generation Company, LLC) to USNRC, "Issuance of Reactor Coolant System Pressure and Temperature Limits Reports for Byron Station Units 1 and 2," dated November 12, 2004, and K. J . Poison (Exelon Generation Company, LLC) to USNRC, "Pressure and Temperature Limits Reports, Revision 3, Braidwood Station, Units 1 and 2," dated January 24, 2005, respectively.
Although Code Case N-640 provides higher allowable pressure limits through the entire range of operating temperatures, the metal temperature requirement of the RPV closure head flange specified in 10 CFR 50, Appendix G, restricts the allowable pressure at temperatures below the reference nil-ductility transition temperature (RTNDT)+120'F . The Page 1 of 6
Attachment 4 Justification for Exemption from 10 CIFIR 50.60 continued operation with these P-T limits, without the relief provided by WCAP-16143, would unnecessarily restrict the FvT operating window for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2. Approval of the requested exemption will allow the Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, LTOP system setpoints to be established at 100% of the allowable pressure established by the P-T limit curve instead of the ASME B&PV Code Case NOW seQoint of 110% of the allowable pressure .
10 CFR 50 .12(a) Requirements The requested exemption to allow use of WCAP-16143, in conjunction with ASME B&PV Code, Section X1, Appendix G, to determine the P-T limits meets the criteria of 10 CFR 50 .12 as discussed below.
10 CFR 50.12 states that the NRC may grant an exemption from requirements contained in 10 CFR 50 provided that the following is satisfied .
1 . The requested exemption is authorized by law No law exists which precludes the activities covered by this exemption request.
10 CFR 50,60(b) allows the use of alternatives to 10 CFR 50, Appendices G and H when an exemption is granted by the NRC under 10 CFR 50.12 .
2 . The requested exemption does not present an undue risk to the public health and safety 10 CFR 50, Appendix G, contains requirements for the metal temperature of the closure head flange and vessel flange regions. This rule states that the metal temperature of the closure flange regions must exceed the material unirradiated RTNDT by at least 120°F for hydrostatic normal operation when the pressure exceeds 20 percent of the pre-service pressure test . The margin of 120OF and the pressure limitation of 20 percent of hydrotest pressure were developed using the Kia fracture toughness, in the mid 1970s, to ensure that appropriate margins would be maintained . Since 1974, additional knowledge has been gained about RPV materials, which demonstrates the lower bound fracture toughness provided by the Kia curve is well beyond the margin of safety required to protect against potential RPV failure .
The proposed methodology for the Byron Station and Braidwood Station P-T limits relies, in part, on ASME B&PV Code Case N-640, which allows the use of KI, fracture toughness curve rather than the KI, curve. P-T limits developed using the Kic fracture toughness curve permit a much higher allowable pressure through the entire range of temperatures . The benefit is negated ; however, at temperatures below RTNDT +120OF because of the additional flange requirement of 10 CFR 50, Appendix G . 10 CFR 50, Appendix G, restricts the ability to raise the pressurizer power operated relief valve (PORY) setpodt as temperature rises by restricting the setpoint to the flange temperature limit rather than the ASME Code Case N-640 P-T limit.
Using the Q fracture toughness, WCAP-16143 presents analyses that show that there is significant margin between the applied stress intensity factor at boltup and the material fracture toughness at cracks postulated to exist in the highest stress region of the closure head/flange region . The analyses also showed the boltup temperature Page 2 of 6
Attachment 4 Justification for Exemption from 10 CFR 50.60 requirement for Braidwood, Units 1 and 2, and Byron, Units 1 and 2, could be performed at 60OF or higher, easily justifying bolt up at ambient temperature. The results presented in WCAP-1 6143 demonstrate that the 10 CFR 50, Appendix G RPV closure head flange requirement can be eliminated and appropriate fracture margins are still maintained .
Applying WCAP-16143 methodology to the P-T curves will enhance overall plant safety by expanding the P-T operating window, especially in the region of low temperature operations . The two primary safety benefits that would be realized are a reduction in the potential challenges to the LTCOP system and a reduction in the risk of damaging the reactor coolant pump seals . This will produce a significant improvement in plant safety by reducing the probability of an inadvertent reduction in reactor coolant inventory, and in easing the burden on the operators.
- 3. The requested exemption is consistent with the common defense and security Implementation of this exemption request (i .e., WCAP-16143) will have no effect on the common defense and security.
- 4. Special circumstances are present which necessitate the request for an exemption to the regulations of 10 CFR 50 .60 In accordance with 10 CFFR 50 .12(a)(2), the N RC will consider granting an exemption to the regulations if special circumstances are present. This exemption meets the special circumstances of paragraphs :
(a)(2)(ii) - Application of the regulation is not necessary to achieve the underlying purpose of the rule; and (a)(2)(iv) - Would result in benefit to the public health and safety that compensates for any decrease in safety that may result from the grant of the exemption .
10 CFR 50 .12(a)(2)(ii)
The underlying purpose of the rule (i .e ., 10 CIFIR 50, Appendix G) will continue to be achieved . 10 CIFIR 50, Appendix G contains requirements for the P-T limits for pressure-retaining components of the reactor coolant pressure boundary, and requirements for the minimum metal temperature of the RPV closure head flange and reactor vessel flange regions. The FvT limits are determined using the methodology of ASME B&PV Code,Section XI, Appendix G, with additional, more restrictive, flange temperature requirements specified in 10 CFR 50, Appendix G . This rule states that the metal temperature of the highly stressed region of the closure assembly must exceed the material unirradiated RTNDT by at least 120OF for normal operation when the pressure exceeds 20 percent of the pre-service hydrostatic test pressure .
This requirement was originally based on concerns regarding the fracture margin in the closure flange region . During the boltup process, outside surface stresses in this region typically reach over 70 percent of the steady state stress, without being at steady state temperature . The margin of 120'F and the pressure limitation of 20 percent of Page 3 of 6
Attachment 4 Justification for Exemption from 10 CIFIR 50.60 hydrostatic test pressure were developed in the mid-1970s using the Kla fracture toughness to ensure that appropriate margins would be maintained .
WCAP-16143 presents analysis results using the KI, fracture toughness for the flange region which show that flange fracture margins are still maintained for boltup without the RT NDT +120'Frequ&emek. Use of the newly accepted Kic fracture toughness for flange boltup limits leads to the conclusion that the 10 CFR 50, Appendix G flange region requirement can be eliminated.
Another objective of the requirements of 10 CFR 50, Appendix G is to ensure that fracture margins are maintained to protect against service induced cracking due to environmental effects . Because the governing flaw is on the outside surface where there are no environmental effects, there is even greater assurance of fracture margin .
Note that the inside surface is in compression. It may therefore be concluded that the integrity of the RPV closure head flange region is not a concern for any operating plants using the Kic fracture toughness .
There are no known mechanisms of degradation for the RPV closure head flange region .
Because the design fatigue usage factor for this region is less than 0.1, it may be concluded that flaws are unlikely to initiate in this region .
Therefore, the underlying purpose of the regulation, to maintain the appropriate fracture margin in the RPV closure head flange region, will continue to be achieved .
10 CFR 50 .12(a)(2)fM The RPV P-T operating window is defined by the P-T operating and test limits developed in accordance with the ASME B&PV Code,Section XI, Appendix G procedures . EGC has received approval to use ASIVIE B&PV Code Case N-640, which provides higher allowable pressure limits through the entire range of operating temperatures . The metal temperature requirement of the RPV closure head flange specified in 10 CFR 50, Appendix G; however, restricts the allowable pressure at temperatures below RTNDT+120'F. The continued operation with these P-T limits, without the relief provided by VVCAPd 6143, would unnecessarily restrict the P-T operating window for Byron Station Units, 1 and 2, and Braidwood Station, Units 1 and 2. This operating window is defined by the area between the LTOP system setpoint and the minimum pressure for reactor coolant pump operation. The more restricted this space is, the greater the potential for inadvertent pressurizer PORV actuation or reactor coolant pump seal damage due to pump operation under conditions in which it is difficult to maintain adequate seal differential pressure to ensure proper pump operation .
The present methodology provides a more restrictive setpoint, which constitutes an unnecessary challenge that can be alleviated by application of WCAP-16143 .
Implementation of the P-T limits as allowed by WCAP-16143 does not reduce the margin of safety originally contemplated by either the NRC or ASIVIE . Applying WCAP-16143 decreases the possibility of inadvertent pressurizer PORV actuation or reactor coolant pump set damage and, thereby, is of benefit to the public health and safety .
Page 4 of 6
Attachment 4 Justification for Exemption from 10 CFR 50 .60 Environmental Assessment In accordance with 10 CFR 51 .30, "Environmental assessment," and 10 CFR 51 .32, "Finding of no significant impact," the following information is provided in support of an environmental assessment and finding of no significant impact for the proposed action .
The proposed action would grant an exemption from requirements of 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation ." The requested exemption will specifically allow the use of Westinghouse [Electric Company Report, WCAP-1 6143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2," in calculating the RPV pressure-temperature (P-T) limits for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, in lieu of 10 CFR 50, Appendix G, "Fracture Toughness Requirements," paragraph IV.A.2 .c as required by 10 CFR 50 .60(a) .
The requested exemption is needed because utilization of WCAP-16143 will enhance overall plant safety by widening the P-T operating window, especially in the region of low temperature operations . The two primary safety benefits that would be realized are a reduction in the potential challenges to the low temperature overpressure protection system resulting in an inadvertent opening of a power operated relief valve and a reduction in the risk of damaging the reactor coolant pump sets due to pump operation under conditions in which it is difficult to maintain adequate seal differential pressure to ensure proper pump operation.
The principal alternative to the proposed action would be to deny the requested exemption and require adherence to the current 10 CFR 50 .60 requirements . Denial of the exemption request would result in no change in environmental impacts .
Regarding alternative use of resources, granting the requested exemption will not involve we use of resources not previously considered in the Final Environmental Statements for Byron Station and Braidwood Station (i .e., NUREG-0848, "Final Environmental Statement related to the operation of Byron Station, Units 1 and 2," dated April 1982 and NUREG-1026, "Final Environmental Statement related to the operation of Braidwood Station, Units 1 and 2," dated June 1984).
The proposed action (i .e., granting the exemption request) will not increase the probability or consequences of accidents, no changes are being made in the types or quantities of any radiological effluents that may be released offsite, and there is no significant increase in occupational or public radiation exposure. Therefore, there are no significant radiological environmental impacts associated with the proposed action .
The proposed action does not affect non-radiological plant effluents and has no other environmental impact . Therefore, there are no significant non-radiological impacts associated with the proposed action .
The environmental impacts of the proposed action and the alternative action are similar.
Based on the assessment presented above, the proposed action will not have a significant effect on the quality of the human environment.
Page 5 of 6
Attachment 4 Justification for Exemption from 10 CFR 50.60 Conclusion Compliance with the specified requirement of 10 CFR 50 .60(a) would unnecessarily restrict the P-T operating window and result in hardship and unusual difficulty without a compensating increase in the level of quality and safety . Compliance with the 10 CFR 50, Appendix G RPV closure head flange limit would be inconsistent with the use of Code Case 10641 Code Case N&40 uses Q fracture toughness methodology and the present RPV closure head flange limit is based on KI, fracture toughness methodology.
WCAP-16143 provides a valid basis for changing the RPV closure head flange limit and maintains the relative margin of safety commensurate with that which existed at the time the 10 CFR 50, Appendix G requirement was issued . There is a further, positive benefit to the public health and safety by reducing potential inadvertent challenges to the pressurizer PORV and increasing the operating margin for the reactor coolant pump seals. Therefore, application of WCAP-16143 for Byron Station, Units 1 and 2, and Braidwood Station, Units 1 and 2, will ensure an acceptable margin of safety and does not present an undue risk to the public health and safety .
Attachment 5 BRAIDWOOD STATION UNITS 1 AND 2 Docket Nos. 50-456 and 50-457 License Nos. NPF-72 and NPF-77 and BYRON STATION UNITS 1 AND 2 Docket Nos . 50-454 and 50-455 License Nos . NPF-37 and NPF-66 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Application for Withholding and Affidavit
Westinghouse Westinghouse Electric Company Nuclear Services P .O. Box 355 Pittsburgh, Pennsylvania 15230-0355 USA U.S. Nuclear Regulatory Commission Direct tel: (412) 374-4643 Document Control Desk Directfax: (412) 374-4011 Washington, DC 20555-0001 e-mail: greshaja@westinghouse .co m Our ref: CAW-05-2033 July 27, 2005 APPLICATION FOR WITHHOLDING PROPRIETARY INFORMATION FROM PUBLIC DISCLOSURE Subject : WCAP-16143-P, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2" (Proprietary)
The proprietary information for which withholding is being requested in the above-referenced report is further identified in Affidavit CAW-05-2033 signed by the owner of the proprietary information, Westinghouse Electric Company LLC . The affidavit, which accompanies this letter, sets forth the basis on which the information may be withheld from public disclosure by the Commission and addresses with specificity the considerations listed in paragraph (b)(4) of 10 CFR Section 2 .390 of the Commission's regulations .
Accordingly, this letter authorizes the utilization of the accompanying affidavit by Exelon Corporation .
Correspondence with respect to the proprietary aspects of the application for withholding or the Westinghouse affidavit should reference this letter, CAW-05-2033, and should be addressed to J. A. Gresham, Manager, Regulatory Compliance and Plant Licensing, Westinghouse Electric Company LLC, P.O. Box 355, Pittsburgh, Pennsylvania 15230-0355 .
Very truly yours,
. A. Gresham, Manager Regulatory Compliance and Plant Licensing closures cc: B . Benney L. Feizollahi A BNFL Group company
CAW-05-2033 bcc: J. A . Gresham (ECE 4-7A) 1L R. Bastien, 1L (Nivelles, Belgium)
C. Brinkman, 1 L (Westinghouse Electric Co ., 12300 Twinbrook Parkway, Suite 330, Rockville, MD 20852)
RCPL Administrative Aide (ECE 4-7A) IL, 1A (letter and affidavit only)
J. J. DeBlasio A BNFL Group company
CAW-OS-2033 AFFIDAVIT COMMONWEALTH OF PENNSYLVANIA :
ss COUNTY OF ALLEGHENY:
Before me, the undersigned authority, personally appeared J . A. Gresham, who, being by me duly sworn according to law, deposes and says that he is authorized to execute this Affidavit on behalf of Westinghouse Electric Company LLC (Westinghouse), and that the averments of fact set forth in this Affidavit are true and correct to the best of his knowledge, information, and belief:
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Attachment 6 BRAIDWOOD STATION UNITS 1 AND 2 Docket Nos. 50-456 and 50-457 License Nos . NPF-72 and NPF-77 and BYRON STATION UNITS 1 AND 2 Docket Nos. 50-454 and 50-455 License Nos. NPF-37 and NPF-66 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Non-proprietary Version of WCAP-16143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2"
Westinghouse Non-Proprietary Class 3 WCAP-16143-NP Novernber 2003 Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2
WCAP-16143-NP Reactor Vessel Closure HeadNessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2 Warren Bamford K. Robert Hsu Joseph 11 Petscdhe November 2003 Reviewer: - 6 C Y.
Piping Analysis and Fracture Mechanics Piping Analysis and Fracture Mechanics Westinghouse Electric Company LLC P.O . Box 355 Pittsburgh, PA 15DOOM5 0 2003 Westinghouse Electric Company LILXC All Rights Reserved 6295-NP.doc-11/12/03
TABLE OF CONTENTS INTRODUCTION ............... ... .. .......... ... .... . .... ............. ... ...... ........... . ........ ........ ..... ................. . ..... 1-1 2 TECHNICAL APPROACH . . ......... ... ........ ... ........ ............... ... ........ ...... .. ...... .. ............................ 2-1 FRACTURE ANALYSIS METHODS AND MATERIAL PROPERTIES ........... .. ................... ... 3-1 3.1 STRESS INTENSITY FACTOR CALCULATIONS ..............,............... .. ..........,........ . . .3-1 3.2 FRACTURE TOUGHNESS . . . . . . . . . .... ... ...... ........... ... ... ............. .................. ...... 3-1 3.3 IRRADIATION EFFECTS ....... .... ..... ...................... ......................... .......... .......... ..... ...... 3-2 FLANGE INTEGRITY ..... ....... ... ........ ............ ..... ........ ... ... ...... ..... ... ... ........ ........... ..... ........ ......... . 4-1 5 ARE FLANGE REQUIREMENTS NECESSARY?
6 SAFETY IMPLICATIONS OF THE FLANGE REQUIREMENT ... ... .... .... ........ ............. ..... ...... 6-1 7 REFERENCES ............. ... ............. ............................ ........... . . ....................................... ... ... ........ .. 7-1 APPENDIX A REACTOR PRESSURE VESSEL INSPECTION RELIABILITY* ...................... .. ...... A-1 APPENDIX B THERMAL AGING OF FERRITIC RPV STEELS AT REACTOR OPERATING TEMPERATITRES . ... ................. ....................... ..... ..... .................. . ... ....... B-1 APPENDIX C STRESS DISTRIBUTIONS IN THE CLOSURE HEAD REGION ------------- 01 APPENDIX I) FLANGE INSPECTION RESULTS : BYRON AND BRAIDWOOD PLANTS ----D-1 WCAP-16143-NP NovenTsT 2003 6295-NP.doc-11/12/03
INTRODUCTION 10 CFR Part 50, Appendix G contains requirements for pressure-temperature limits for the primary system, and requirements for the metal temperature of the closure head flange and vessel flange regions.
The pressure-temperature limits are to be determined using the methodology of ASME Section XI, Appendix Q but the flange temperature requirements are specified in l OCFR50 Appendix G This rule states that the metal temperature at the closure flange regions must exceed the material unirradiated RTNDT by at least 120°F for normal operation when the pressure exceeds 20 percent of the pre-service hydrostatic test pressure, which is 621 psig for a typical MR, and 300 psig for a typical BWR.
This requirement was originally based on concerns about the fracture margin in the closure flange region.
During the boltup process, outside surface stresses in this region typically reach over 70 percent of the steady state stress, without being at steady state temperature. The margin of 120°F and the pressure limitation of 20 percent of hydrotest pressure were developed using the Ku fracture toughness, in the mid 1970s, to ensure that appropriate margins would be maintained .
Improved knowledge of fracture toughness and other issues which affect the integrity of the reactor vessel have led to the recent change to allow the use of Ku in the development of pressure-temperature curves, as contained in ASME Code Case N640, "Alternative Reference Fracture Toughness for Development of P-T Limit Curves for Section XI, Division l ."
Figure 1-1 illustrates the problem created by the flange requirements for a typical PWR heatup curve. It is easy to see that the heatup curve using KIc provides for a much higher allowable pressure through the entire range of temperatures. For this plant, however, the benefit is negated at temperatures below RTNDT
+120°F because of the flange requirement of 10 CFR Part 50, Appendix G The flange requirement of 10 CFR 50 was originally developed using the Kia fracture toughness, and this report will show that use of the newly accepted Kic fracture toughness for flange considerations leads to the conclusion that the flange requirement can be eliminated for Byron/Braidwood Units 1 and 2.
WCAP-16143-NP November 2003 6295-1VP.doc-11!12103
Figure 1-1 Illustration of the Impact of the Flange Requirement for a Typical PWR Plant WCAP-16143-NP November 2003 09"AWWWAD/D3
51 TECHNICAL APPROACH The evaluation presented here is intended to cover the Byron/Braidwood Units 1 and 2 reactor vessels.
Fracture evaluations have been performed on the closure head geometry specific to these units, and results will be tabulated and discussed. The geometry of the closure head region for Byron/Braidwood Units 1 and 2 is shown in Figure 24 .
Stress analyses have been performed, and these stress results were used to perform fracture mechanics evaluations. Details of the finite element stress analysis results are provided in Appendix C. The highest stress location in the closure head and vessel flange region is in the head, just above the bolting flange.
This corresponds with the location of two welds as shown in Figure 2-l . The highest stressed location is near the outside surface of the head in that region, and so the fracture evaluations have assumed a flaw at the outside surface.
The goal of the evaluation is to compare the structural integrity of the closure head during the boltup, the plant heatup and plant cooldown processes, to structural integrity during steady state operation. The question to be addressed is: With the higher Ky fracture toughness now known to be applicable, is there still a concern about the structural integrity of the closure head during boltup?
WCAi'-16143-NP November 2003 6295-NP.doc-11n1/%03
02 TOP HEAD DOME TO TORUS WELD (CUT 2)
VESSEL FLANGE TO UPPER SHELL WELD ER HEAD REGION Byron Braidwood Units I and 2 Units 1 and 2 A 8&3 88.3 B 6.625 6X25 C 30.05 3111 D 17588 17188 NOTE: ALL DIMENSIONS ARE IN INCHES Figure 2-1 Geometry of the Upper Head/Flange Region of the Byron/Braidwood Units 1 and 2 Reactor Vessels WCAP-16143-NP Tqovemher 2003 6295-NPAw11/11103
3 FRACTURE ANALYSIS METHODS AND MATERIAL PROPERTIES The fracture evaluation was carried out using the approach suggested by Section XI Appendix G (Ref. 1).
A semi-elliptic surface flaw was postulated to exist in the highest stressed region, which is at the outside surface of the closure flange. The flaw depth was assumed to encompass a range of depths into the wall thickness, and the shape was set at a length six times the depth.
3.1 STRESS INTENSITY FACTOR CALCULATIONS One of the key elements of a fracture evaluation is the determination of the driving force or stress intensity factor (KI). In most cases, the stress intensity factor for the structural integrity calculations utilized a representation of the actual stress profile rather than a linearization. The stress profile was represented by a cubic polynomial :
a(x) = AQ + x+A2x where:
x = the coordinate distance into the wall, in.
stress perpendicular to the plane of the crack, coefficients of the cubic fit For the surface flaw with length six times its depth, the stress intensity factor expression of Raju and Newman (Ref. 2) was used. The stress intensity factor KI can be calculated anywhere along the crack front. The point of maximum crack depth is represented by ~ = 0, and this location was found to also be the point of maximum KI for the cases considered here . The following expression is used for calculating KI as a function of the angular location around the crack front ($). The units of KI are ksi in .
0.5 3 (3-2) jG j (a/c, a/t, t/R, ~) A j a1 j=0 The boundary correction factors Go, G1, G2, and G3 are obtained by the procedure outlined in reference (2). The dimension "a" is the crack depth, "c" is the crack half length, "t" is the wall thickness, "R" is the inside radius, and "Q" is the flaw shape factor, which can be approximated by Q = 1 + 1 .464 (a/c) L65, 3.2 FRACTURE TOUGHNESS Another key element in a fracture evaluation is the fracture toughness of the material . The fracture toughness has been taken directly from the reference curves of Appendix A, Section Xl. In the transition temperature region, these curves can be represented by the following equations:
KI, = 33.2 + 20.734 exp. [0.02 (TRT (3-3) 26.8 + 12.445 exp. [0.0145 (TRTNDT)] (3-4) where are in ksi in .
WCAP-16143-NP November 2003 6245-NPAoc-11/12103
3-2 The upper shelf temperature regime requires utilization of a shelf toughness which is not specified in the ASME Code. A value of 200 ksi in has been used here . This value is consistent with general practice in such evaluations, as shown for example in reference 3, which provides the background and technical basis of Appendix A of Section XI.
The final key element in the determination of the fracture toughness is the value of RTNDT , which is a material parameter determined from Charpy V-notch and drop-weight tests.
The value of RTNDT for the closure flange region of the ByronBraidwood units was obtained from the certified material test reports or determined from Charpy tests and drop weight tests [12]. The results are shown in Table 3-1 . The highest value was 60°F and so this value was used for the illustrations to be discussed in Sections 4 and 5.
3.3 IRRADIATION EFFECTS Neutron irradiation has been shown to produce embrittlement which reduces the toughness properties of reactor vessel steels . The decrease in the toughness properties can be assessed by determining the shift to higher temperatures of the reference nil-ductility transition temperature, RTNDT .
The location of the closure flange region is such that the irradiation levels are very low and therefore the fracture toughness is not measurably affected .
a,c,e WCAP-16143-NP November 2003 6295-NP .doe-11/12/43
FLANGE INTEGRITY The first step in evaluation of the closure head/flange region is to examine the stresses. The stresses which are affected by the boltup event are the axial, or meridional stresses, which are perpendicular to the nominal plane of the closure head to flange weld . The stresses in this region during the entire heatup and cooldown process are summarized in Appendix C.
The boltup is the key condition to review here, in comparison with the heatup and cooldown operation, since the flange requirement applies to boltup conditions. No other transients result in stresses in this region at low temperatures . One might suggest that the cooldown might be of similar concern, but the boltup is governing for a number of reasons:
The heatup and cooldown transient is structured to ensure generous margins are maintained (SF = 2) for a large flaw in the irradiated beltline region, not for the unirradiated flange region .
- 2. The cooldown transient has much higher temperatures in the head region than the boltup, and
- 3. The thermal stresses caused by the cooldown transient tend to counteract the boltup stresses; cooldown thermal stresses are tensile on the inside surface and compressive on the outside surface.
Table 4-1 provides a comparison of the stresses at boltup with those at the governing time step of heatup and cooldown which is end of heatup. It is easy to see that the stresses at boltup are mostly bending, with a very small membrane stress . As the vessel is pressurized, the membrane stresses increase. These results were taken from a finite element analysis of the heatup/cooldown process, and the boltup stress alone was compared with the most limiting time step of the entire heatup/cooldown transient, which includes pressure, thermal, and boltup stresses.
The relative impact of these stresses can best he addressed through a fracture evaluation. A semi-elliptic surface flaw was postulated at the outer surface of the closure head flange, and the stress intensity factor, KI, (or crack driving force) was calculated. The results are shown for cut 3 weld region in Figure 4-1, and for the cut 2 weld region in Figure 4-2. For a semi-elliptic surface flaw with depth equal to 10 percent of the wall thickness postulated in the highest stress region of the head, the following values were determined for the stress intensity factor.
Boltup: = 24.84 ksi (for alt = 0.1)
End of Heatup : KI = 49.58 ksi in (for a/t = 0.1)
It will be useful to highlight the difference in the integrity for the head region using the two values of fracture toughness. The boltup temperature for a typical PWR is 60°F, so if RTi, Dr = 60°F the ASME reference toughness values are Kh = 39 .2 ksi in and KI, = 50 .9 ksi in . Using the Kh toughness (which was the basis for the original flange requirements) it can be seen that the toughness exceeds the applied stress intensity factor for boltup for flaws of any depth in the head thickness. From Figure 4-1, the smallest margin = 1- KI/Kh = 0.24, when a/t = 0.36. For the heatup and cooldown transient, the coolant WCAP-16143-NP November 2003 6295-NP.dcx-11112/43
4-2 temperature at the governing time steps, near the end of heatup, is 557°F. The fracture toughness is therefore 200 ksi~ , so again the margin is very large.
Using the K,, toughness, which has now been adopted by Section XI for P-T Curves, it can be seen that there is also a significant margin between the fracture toughness and the applied stress intensity factor, for both the boltup and the heatup cooldown transient. Another objective of the requirements in Appendix G is to assure that fracture margins are maintained to protect against service induced cracking due to environmental effects. Since the governing flaw is on the outside surface (the inside is in compression) where there are no environmental effects, there is even greater assurance of fracture margin. Therefore, it may be concluded that the integrity of the closure head/flange region is not a concern for the Byron/Braidwood units using the Ki, toughness. There are two possible mechanisms of degradation for this region, thermal aging and fatigue.
Effect of Fatigue. The calculated design fatigue usage for this region is less than 0.1, so it may be concluded that flaws are unlikely to initiate in this region .
I ac,e CAP-46443-NP November 2003 6295-NP.doc-11/12/03
4- 3 Table 4-1 Stress Distributions at the Closure Flange Region - Byron/Braidwood Units 1 and 2 Distance Boltup Stress at Cut 3 Heatup* (344 minutes) at Cut 2 (Tit) (ksi) (at p=2317 psig, t=557'F) 0 (IUD) -1138 -1613 Al W77 01 -713 0.3 -5 .14 0.4 -216 0.5 -016 46 -116 1771233071 0.7 432 0.8 7.54 2163 49 1114 1 .0 (OD) 1930 4180
- With boltup stress superimposed . I Notes: Cut 3 has the highest boltup, stress.
Cut 2 has the highest transient stress.
WCAP-16143-MV 2003 6295-NP.doc-11/12/03
Stress Intensity Factor vs aft for Outside Surface Flaw (Aped Ratio=6 :1) at Cut 3 0 0 .1 0.2 03 0 .4 0 .5 0.6 0 .7 0 .8 aft ratio (flaw depth/wall thickness)
Figure 4-1 Crack Driving Force as a Function of Flaw Size: Outside Surface Flaw in the Torus to Flange Region Weld for Byron/Braidwood Units 1 & 2)
WCAP-16143-NP November 2003 6295-NP.doe-1 1/12/03
Stress Intensity Factor vs aft for Outside Surface Flaw (Aped Ratio=6:1) at Cut 2 sit ratio (flaw depthtwall thickness)
Figure 4-2 Crack Driving Force as a Function of Flaw Size: Outside Surface Flaw in the Dome to Torus Region Weld for Byron/Braidwood Units I & 2)
WCAP-16143-NP KWwmM2W3 6295-NP.doc-11/12/03
ARE FLANGE REQUIREMENTS NECESSARY?
Using the Kic curve can support the elimination of the flange temperature requirement. This can be illustrated by examining the stress intensity factor change for a postulated flaw as the vessel is heated and pressurized after boltup, progressing up to steady state operation.
The stresses at the region of interest are shown in Table 4-1, for the end of heatup, as well as boltup .
Included here are the stress distributions through the wall, showing that the highest stress location for this region is the outer surface.
As the vessel is pressurized, the stresses in the closure flange region gradually change from mostly bending stresses to a combination of bending and membrane stresses . The stress intensity factor, or driving force, increases for a postulated flaw at the outside surface, as the vessel is pressurized.
A direct comparison between the original basis for the boltup requirement and the new Kic approach is provided in Table 5-1. This table provides calculated boltup requirements for all the designs, using a safety factor of 2, and a reference flaw depth of alt = 0.10, which was used by Randall as the basis for the original requirement (Ref . 11). Before discussing the table, it will be helpful to discuss the basis for the reference flaw, in light of current technology, and using the results of the Performance Demonstration Initiative .
Basis far the Reference Flaw Size. Regulatory Guide 1 .150 stimulated improvement in examinations of the clad to base-metal interface. The same techniques have been used for more than 10 years for reactor vessel head examinations performed from the outside surface. Capability demonstrations for the clad to base-metal interface have been conducted at the EPRI NDE Center since 1983. These demonstrations were performed initially for the belt-line region. However, similar techniques are used for both the vessel belt-line and the reactor vessel head, although the head exams are done manually.
Ia c,e WCAP-16143-NP November 2003 6295-NP.doc-13/12103
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13 Table 5-1 Comparison of Various Plant Designs Boltup Requirements Ki (ksi~) T - RTE (OF) T - RTE (OF)
K, (ksi4i;) (with alt = OJ, using Ki.
using Ku Plant (8/t = .1) SF = 2) (alt = .10) (aft = .10)
CE 310 610 13 68 B&W 39.4 718 41 100 Byron/Braidwood 24.9 448 0* 43 W 3 Loop 28 .7 57 .5 8 63 GE {C$1251") 38.7 714 38 97 GE (B&NV 251") 48.0 96.0 56 118 GE (CE 218") 25.1 542 0* 43
- The calculated value of TRIE)i A negative, so zero is used for conservatism.
WCAP-16143-NP November 2003 65XNR&n4V12M3
Figure 5-1 Probability of Correct Rejection/Reporting (PCR) Considering Passed plus Failed Candidates, Appendix VIII Supplement 4, Detection from the Outside Surface.
Reporting Criterion A' = 0.15 inch, TWE Represents Flaw Depth.
WCAP-16143-NP November 2003 6295-NP.doc-11/12103
Figure 5-2 Probability of Correct Rejection/Reporting (PCR) Considering Only Passed Candidates, Appendix VIII Supplement 4, Detection from the Outside Surface.
Reporting Criterion A'= 0.15 inch, TWE Represents Flaw Depth.
WCAP-16143-NP November 2003 6295-NP.dm-1 1112/03
SAFETY IMPLICATIONS OF THE FLANGE REQUIREMENT There are important safety implications which are associated with the flange requirement, as illustrated by Figure 6-1 . The safety concern is the narrow operating window at low temperatures forced by the flange requirement . The flange requirement sets a pressure limit of 621 psi for a PWR (20 percent of hydrotest pressure) . Thus, no matter how good the toughness of the vessel, the P-T limit curve may be superceded by the flange requirement for temperatures below RTNDr + 120°R This requirement was originally imposed to ensure the integrity of the flange region during boltup, but Section 4 has shown that this is no longer a concern .
The flange requirement can cause severe operational limitations when instrument uncertainties are added to the lower temperature range limit (621 psi), for the Low Temperature Overpressure Protection system of PWRs. The minimum pressure required to cool the seals of the main coolant pumps is 325 psi, so the operating window sometimes becomes very small, as shown schematically in Figure 6-l . If the operator allows the pressure to drop below the pump seal limit, the seals could fail, causing the equivalent of a small break LOCA, a significant safety problem. Elimination of the flange requirement will significantly widen the operating window for most PWRs.
An example will be provided to illustrate this situation for Byron Unit 1. This is a forging-limited vessel at 12 EFPY, with a low leakage core, and low copper weld material in the core region. The vessel has excellent fracture toughness, which means that the flange notch is very prominent, as shown in the vessel heatup curve of Figure 6-2 . As illustrated before in Figure 6-1, Byron has the LTOP setpoints significantly below the flange requirement of 621 psi, because of a relatively large instrument uncertainty.
The setpoints of the two power operated relief valves are staggered by about 16 psi to prevent a simultaneous activation. The two PORVs have different instrument uncertainties, and for conservatism the higher uncertainty is used. A similar situation exists for cooldown, as shown in Figure 6-3 .
Elimination of the flange requirement for the case of Byron Unit 1 would mean that the PORV curve could become level at 6041587 psig, which are the leading/trailing setpoints to protect the PORV downstream piping, through the temperature range of the 350°F down to boltup at 60°F. The operating window between the leading PORV and the pump seal limit rises from 121 psig (446-325) to 262 psig (587-325) . This change will make a significant improvement in plant safety by reducing the probability of a small LOCA, and easing the burden on the operators .
This is only one example of the impact of the flange requirement. Every operating PWR plant will have a different situation, but the operational safety level will certainly be generally improved by the elimination of this unnecessary requirement.
WCAP-16143-NP November 2003 6295-NP.doc-11/12/0 3
Heatup Curve z
Instrument Uncertainty LTOP se"im /
Vr
\ - ,
621 WhXxIOMW Pump Sea!
Limit 325 psi r Temperature RT,&+120 Figure 6-1 Illustration of the Flange Requirement and its Effect on the Operating Window for a Typical Heatup Curve WCAP-16143-NP November 20Q3 6295-NP.doc-11/12/03
LIMITING MATERIAL: INTERMEDIATE SHELL FORGING 5P-5933 (ui3np iunr. daft)
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-,- -~---~ - r--- r-0 50 100 150 200 250 300 350 400 450 500 Indicated Temperature (Deg .F)
Figure 6-2 Illustration of the Actual Operating Window for Heatup of Byron Unit a Low Copper Plant at 12 EFPY YJCAP-16143-NP November 2003 6295-NP.doc-11112/03
LIMITING MATERIAL: INTERMEDIATE SHELL FORGING ASP'-5933 (usirp stxv. caQsuwe data)
LIMITING ART VALUES AT 12 EFPY : 114T, 70°F 3t4T,60°F ansessuman a
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RUNS Indicated Temperature (Deg .F)
Figure 6-3 Illustration of the Actual Operating Window for Cooldown of Byron Unit l, a Low Copper Plant at 12 EFPY WCAP-16143-NP November 2003 6295-NP .doc-11112103
7 REFERENCES
- 1. ASME Boiler and Pressure Vessel Code,Section XI, Appendix G, 1996 Addenda, ASME, New York.
Raju, I. S. and Newman, J . C. Jr., "Stress Intensity Factor Influence Coefficients for Internal and External Surface Cracks in Cylindrical Vessels," Trans. ASME, Journal of Pressure Vessel Technology, Vol. 104, pp. 293-98, 1982.
- 3. Marston, T. U., ed., "Flaw Evaluation Procedures : ASME Section XI," Elec Power Research Institute Report EPRI-NP-719 SR, August 1978 .
Mitchell, M. A., "RPV P-T Limits and RPV Flange Requirements; Potential Exemptions from the Requirements of 10 CFR Part 50, Appendix G" presentation to ASME Boiler and Pressure Vessel Code,Section XI, Working Group on Operating Plant Criteria, Hollywood, FL, September 10, 2002.
- 5. Nanstad, R. K., et al., Preliminary Review of Data Regarding Chemical Composition and Thermal Embrittlement of Reactor Vessel Steels, ORNL/NRC/LTR-95/1, Oak Ridge, TN, January 1995 .
DeVan, M. J., Lowe, Jr., A. L., and Wade, S., "Evaluation of Thermally-Aged Plates, Forgings, and Submerged Arc Weld Metals," Effects of Radiation on Materials: 16th International Symposium, ASTM STP 1175, Philadelphia, PA, 1993.
- 7. Kirk, M., "Revision of AT3o Embrittlement Trend Curves," presented at the EPRI MRP/NRC PTS Re-Evaluation meeting in Rockville, MD, August 30, 2000.
- 8. Charpy Embrittlement Correlations - Status of Combined Mechanistic and Statistical Bases for U.S. RPV Steels (MRP-45); PWR Materials Reliability Program (PWRMRP), EPRI, Palo Alto, CA: 2001, 1000705.
- 9. ASTM E 900-02, "Standard Guide for Predicting Radiation-Induced Transition Temperature Shift for Reactor Vessel Materials, E706 (11F)," Annual Book of ASTM Standards, Vol. 12.02.
- 10. Langer, R., et al., "A Survey of Results on Aging Experiments of Pressure Vessel Materials,"
presentation at the ATHENA Workshop, Madrid, September 2002.
- 11. Randall, N., Abstract of Comments and Staff Response to Proposed Revision to 10 CFR Part 50, Appendices G and H, Published for Comment in the Federal Register , November 14, 1980.
- 12. Laubham, T., "Initial RTNDT Values for Vessel Head Materials," Westinghouse Letter, LTR-RCDA-03-216, July 28, 2003.
WCAP-16143-NT November 2003 6295-NP.doc-11112103
APPENDIX A REACTOR PRESSURE VESSEL INSPECTION RELIABILITY*
F. L. Becker EPRI Charlotte NC I ABSTRACT
&AC
- Presented a the Joint EC-IAEA Technical Meeting on Improvements in Inservice Inspection Effectiveness, Pettan,fhe Netherlands, November 2002, to be published.
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A-2 3 DETECTION I
"le I
WCAP-1 6143-NP November 2443 62954M.HAV/03
A-3 3.1 OUTSIDE SURFACE DEMONSTRATION a,c,e Figure 1 Probability of Detection Performance for Passed and Passed Plus Failed Candidates for Appendix VIII Supplement 4, from the Outside Surface as a function of the flaw through wall extent (TWE). Both automated and manual techniques are included .
WCAP-16143-NP November 2003 6295-NP.dce-11112103
Figure 2 POD for Inside Surface Examinations, Pass and Pass + Failed Candidates, Passed and Pass Plus Failed Candidates are included .
a,c,e WCAP-16143-NP November 2003 6295-NP.doc-11/12103
A- 5 3.2 COMBINED ID AND OD DETECTION Ja,c,e a,c,e Figure 3 Probability of Detection for Automated RPV Examinations Considering Both Inside and Outside Access. Passed and Passed Plus Failed Candidates are shown.
WCAP-16143-NP November 2003 6295-rrn .doc-11/12/03
Figure 4 POD for Pass and Failed Candidates, Considering ID and OD Automated Demonstrations and Manual OD Demonstrations .
4 SIZING I We WEAP46143-NP November 2003 6295-1VP .doe-11/12/03
5 Histogram of Depth Successful Sizing Candidate Test Scores, Appendix VIII, Supplement 4. Examinations Were Performed Both From the Inside and Outside Surfaces .
IaAe WCAP-16143-NP November 2003 955M.&W1112103
Figure 6 Sizing Error Surface Model ax,e Figure 7 Man View of Sizing Error Surface Model WCAP46141SNP November 2003 6295-NP-doc-1 1/12tO3
A-9 5 ACCEPTABILITY EVALUATION WCAP-16143- November 2003 6295-NP.doc-11112/03
WCAP-16143-NP Nownmbber 2003 6295AR&x-l1!l2103
Figure 8 Probability of Correct Sizing for Passed Candidates, Appendix VIII Supplement 4.
Reporting Threshold A= 0.15 inch.
I&XIC WCAP-16143-NP November 2003 6295-NP.doc-11/12103
Figure 9 Probability of Correct Rejection/Reporting (PCR) for automated techniques, Considering Passed and Passed plus Failed Candidates, includes both inside and outside surface information. Reporting Criterion A' = 0.15 inch.
6
SUMMARY
]&X,C CES WCA1'-16143-PdP November 2003 6295-NP.doc-11/12103
A-13 la,c,e WCAP-16143-NP November 2003 6295-NP.doc-11112!03
APPENDIX B THERMAL AGING OF FERRITIC RPV STEELS AT REACTOR OPERATING TEMPERATURES I mle, WCAP-16143-NP November 2003 6295-NP.doc-11112/Q3
ace I
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APPENDIX C STRESS DISTRIBUTIONS IN THE CLOSURE HEAD REGION I ace WCAP-26143-NP November 2003 6295NT.doc-11112/03
me I
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C-4 SECTION 1 SECTION 2 SECTION 3 SECTION 4 gill ills gill gill Ills SECTION 5 Ills Isis gill gill Ills gill III ills 1111, Figure C-1 Finite Element Model for Closure Head Region, Byron and Braidwood Units 1 and 2 WCAP-16143-NP November 2003 6295-NP.doc-11112103
C- 5 qc,e WCAP-16143-NF' November 2003 6295-7~iP.doc-11/12103
C-6 ax,e WRAP-16143-NP November 2003 6295-NP.doc-l 1AI/03
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WRAP-163 43-NP MARWIVIVT03
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APPENDIX D FLANGE INSPECTION RESULTS:
BYRON AND BRAIDWOOD PLANTS These exams were performed using ASME Section XI and ASME Section V techniques and requirements .
As required by Section XI and as listed in Tables D-1 and D-2, the head to flange weld was examined by the magnetic particle method with no recordable indications.
The volumetric inspection, along with the surface inspection and the visual (VT2) inspections performed every refuel outage provide reasonable assurance of the continued structural integrity of the Reactor Vessel Head to Flange weld. Furthermore, past First Interval inspections, Preservice inspections, ASME Section III construction inspections and every refueling outage VT-2 inspections have revealed no recordable indications and provide reasonable assurance of the continued structural integrity of this weld.
Volumetric exams. The approved inspection procedure used was NDT-C-30 revision 7 which was in accordance with ASME Section XI 1989 Edition and in compliance with NRC Regulatory Guide 1 .150.
The calibration standards utilized were fabricated in accordance with ASME requirements and were actual material dropouts from the component. The examination sensitivity (both straight beam and angle beam) was established from signal responses from side drilled Surface exams. The primary location of concern for the flange region is the outer surface, where the tensile stresses are the highest. This area has been inspected by the magnetic particle technique, which is very reliable.
Based upon review of past inspection data for the closure head flange region, it has been concluded that a 10% through-wall defect would have easily been detected and recorded.
WCAP-16143-N1' November 2003 6295-NP .doc-11112103
Unit 1 Ultrasonic The sensitivity of the Achieved 100% of the This examination was examination of the ultrasonic exam is ASME Section XI completed in March 1999 Reactor Vessel threads in the flange based on the signal coverage, Figure IWB- on all 54 of the flange and a 1-inch annular responses from a 2500-12 . ligament areas. This was volume around the 0.437-inch diameter the second complete flange stud holes. side drilled hole . examination of these areas during the Unit's commercial operation.
Ultrasonic sensitivity of the Achieved 100% of e ecordable e examination was last xamination using ultrasonic exams is ASME Section XI dications. performed in April 1996 .
automated technique based on the signal coverage, Figure IWB-with 0, 45, 60, and 70 esponses from a 0.125 2500-4.
degree shear and nch diameter side longitudinal wave led hole.
scans.
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D-3 Vessel Flange Examination History Component Description Examination Sensitivity Coverage Results Comments/Schedule Unit 2 surface technique No recordable This examination was is capable of detecting indications for either brmed twice during Reactor Vessel Head (ISI # 2RC-01, indications with a the surface or e Unit's commercial RVHC-01) nd major dimension of ultrasonic operation, last performed 1/16th of an inch . The volumetric examinations. in September 2002 .
examination was The sensitivity of the limited to ultrasonic exams is mately 73%
based on the signal due to configuration responses from a and 3 integrally 0.210-inch diameter mounted lifting lugs, side drilled hole. (Relief Request I2R-25).
Flange Technique requires tire flange area on There have been no This exam is performed lighting and distance ead and vessel is ordable indications each refueling outage .
sufficient to detect amined, however, at have required scratches or pits 0.001 the defect size criteria repair.
to 0.003 of an inch . are specifically applied to the o-ring seating urface areas.
Unit 2 onic The sensitivity of the Achieved 100% of the No recordable s examination was examination of the ultrasonic exam is SME Section XI indications. completed in April Reactor Vessel (ISI # 2RC-01-R, threads in the flange based on the signal coverage, Figure IWB- 200 ton all 54 of the FLG THREADS and a 1-inch annular -sponses from a 2500-12. flange ligament areas.
01-54) volume around the .437-inch diameter This was the second ge stud holes. side drilled hole. complete examination of these areas during the it's commercial operation .
Ultrasonic The sensitivity of the Achieved 100% of the examination using ultrasonic exams is ASME Section XI (ISI # 2RC-01-R, automated technique based on the signal coverage, W-07) with 0, 45, 60, and responses from a Figure IWB-2500-4.
70-degree shear and 0.125-inch diameter longitudinal wave side drilled hole .
scans .
November 2003 WCAP-16143-NP 6295-NP.doc-11/12103
D-4 Table D-2 Braidwood Reactor Vessel Flange Examination History Component Description Examination Sensitivity Coverage Results Comments/Schedule Unit 1 Flange to head weld Surface Exam The surface technique Achieved 100% No recordable This examination was is capable of detecting coverage for the indications for either performed twice during Reactor Vessel Head (ISI # 1RV-03-001) (magnetic particle) indications with a surface examination . the surface or the Unit's commercial major dimension of ultrasonic operation, last performed and The volumetric 1116th of an inch. examinations . in September 1998 .
Ultrasonic exams examination was using 0, 30, 40, 45, The sensitivity of the limited to and 60 degree scans. ultrasonic exams are approximately 88%
based on the signal due to configuration responses from a 0.210 and 3 integrally inch diameter side mounted lifting lugs, drilled hole . (see NRC approved Relief Request I2R-20.
Flange Visual examination Technique requires Entire flange area on There have been no This exam is performed lighting and distance head and vessel is recordable indications each refueling outage.
sufficient to detect examined, however, that have required scratches or pits 0.001 the defect size criteria repair .
to 0.003 of an inch. are specifically applied to the o-ring seating surface areas.
l Unit I Flange ligament Ultrasonic The sensitivity of the Achieved 100% of the No recordable This examination was examination of the ultrasonic exam is ASME Section XI indications. completed in March 2000 Reactor Vessel (ISI #1RV-02-038) threads in the flange based on the signal coverage, Figure IWB- on all 54 of the flange and a 1-inch annular responses from a 2500-12. ligament areas. This was volume around the 0.437-inch diameter the second complete flange stud holes. side drilled hole . examination of these areas during the Unit's commercial operation.
Flange to shell weld Ultrasonic The sensitivity of the Achieved 100% of the No recordable The examination was last examination using ultrasonic exams are ASME Section XI indications. performed in April 1997 (ISI # 1RV-01-005) automated technique based on the signal coverage, Figure IWB- using a technique that was with 45 and 70 degree responses from a 0.125 2500-4 . demonstrated and shear and longitudinal inch diameter side qualified to the wave scans. drilled hole . Performance Demonstration Initiative (PDI) Program.
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D-5 Table D-2 Sraidwood Reactor Vessel Flange Examination History (cont.)
Component Description Examination Sensitivity Coverage Results Comments/Schedule Unit 2 Flange to head weld Surface Exam The surface technique Achieved 100% No recordable This examination was is capable of detecting coverage for the indications for either performed twice during Reactor Vessel Head (ISI # 2RV-03-001 ) (Magnetic particle) indications with a surface examination . the surface or the Unit's commercial and major dimension of ultrasonic operation, last performed 1/16th of an inch . The volumetric examinations. in April 1999 .
Ultrasonic exams examination was using 0, 30, 40, 45, The sensitivity of the limited to and 60 degree scans. ultrasonic exams are approximately 88%
based on the signal due to configuration responses from a 0.210 and 3 integrally inch diameter side mounted lifting lugs, drilled hole. (see NRC approved Relief Request I2R-20 .
Flange Visual examination Technique requires Entire flange area on There have been no This exam is performed lighting and distance head and vessel is recordable indications each refueling outage.
sufficient to detect examined, however, that have required scratches or pits 0.001 the defect size criteria repair.
to 0.003 of an inch. are specifically applied to the o-ring seating surface areas.
Unit 2 Flange ligament Ultrasonic The sensitivity of the Achieved 100% of the No recordable This examination was examination of the ultrasonic exam is ASME Section XI indications. completed in October Reactor Vessel (ISI #2RV-02-038) threads in the flange based on the signal coverage, Figure IWB- 2000 on all 54 of the and a 1-inch annular responses from a 2500-12. flange ligament areas.
volume around the 0.437-inch diameter This was the second flange stud holes. side drilled hole . complete examination of these areas during the Unit's commercial operation.
Flange to shell weld Ultrasonic The sensitivity of the Achieved 100% of the No recordable The examination was last examination using ultrasonic exams are ASME Section XI indications. performed in October (ISI # 2RV-01-005) automated technique based on the signal coverage, Figure IWB- 1997 using a technique with 45 and 70 degree responses from a 0.125 2500-4. that was demonstrated and shear and longitudinal inch diameter side qualified to the wave scans. drilled hole. Performance Demonstration Initiative (PDI) Program.
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Attachment 7 BRAIDWOOD STATION UNITS 1 AND 2 Docket Nos. 50-456 and 50-457 License Nos. NPF-72 and NPF-77 and BYRON STATION UNITS 1 AND 2 Docket Nos. 50-454 and 50-455 License Nos. NPF-37 and NPF-66 License Amendment Request Regarding Reactor Coolant System Pressure and Temperature Limits Report and Request for Exemption from 10 CFR 50.60, "Acceptance criteria for fracture prevention measures for lightwater nuclear power reactors for normal operation" Proprietary Version of WCAP-16143, "Reactor Vessel Closure Head/Vessel Flange Requirements Evaluation for Byron/Braidwood Units 1 and 2"