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- Acceptance, Acceptance, Acceptance
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MONTHYEARML21090A1852021-03-31031 March 2021 Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Request ML21125A0452021-05-0404 May 2021 NRR E-mail Capture - LIC-109 Acceptance Review (Unacceptable for Review with Opportunity to Supplement) - Callaway Plant, Unit 1 - License Amendment Request - Final Resolution to Address Concerns of GSI-191 - EPID L-2021-LLA-0059 Project stage: Acceptance Review ML21130A5882021-05-11011 May 2021 Supplemental Information Needed for Acceptance of Requested Licensing Actions to Adopt a Risk-Informed Approach to Address GSI-191 and Respond to Generic Letter 2004 02 Project stage: Acceptance Review ULNRC-06664, Supplement to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014)2021-05-27027 May 2021 Supplement to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Supplement ML21160A1482021-06-10010 June 2021 Acceptance of Requested Licensing Actions License Amendment and Regulatory Exemptions for a Risk Informed Approach to Address Generic Safety Issue 191 and Respond to Generic Letter 2004-02 Project stage: Acceptance Review ML21203A1922021-07-22022 July 2021 Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL-2004-02 (LDCN 19-0014) Project stage: Request ML21203A1932021-07-22022 July 2021 Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL-2004-02 (LDCN 19-0014) Project stage: Request ML21197A0632021-07-23023 July 2021 Audit Plan and Setup of Online Reference Portal for License Amendment Request Risk-Informed Approach for Closure of Generic Safety Issue-191 Project stage: Other ML21237A1352021-08-23023 August 2021 Amendment Request Regarding Risk-Informed Approach to Closure of Generic Safety Issue 191 Project stage: Request ML21237A1362021-08-23023 August 2021 Amendment Request Regarding Risk-Informed Approach to Closure of Generic Safety Issue 191 Project stage: Other ML21238A1382021-09-14014 September 2021 Audit Summary for License Amendment Request and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 Project stage: Other ML21280A3782021-10-0707 October 2021 Third Supplement to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL-2004-02 (LDCN 19-0014) Project stage: Request ML21280A3792021-10-0707 October 2021 Third Supplement to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL-2004-02 (LDCN 19-0014) Project stage: Supplement ML22027A8042022-01-27027 January 2022 Fourth (Post-Audit) Supplement to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Request ML22027A8052022-01-27027 January 2022 Fourth (Post-Audit) Supplement to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Supplement ULNRC-06721, Fifth (Post-Audit) Supplement Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014)2022-03-0808 March 2022 Fifth (Post-Audit) Supplement Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Supplement ML22068A0292022-03-0808 March 2022 Response to Audit Question/Item 23 in NRC Letter Dated September 14, 2021 Project stage: Other ML22068A0272022-03-0808 March 2022 Fifth (Post-Audit) Supplement Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Request ML22087A4022022-03-28028 March 2022 NRR E-mail Capture - Callaway - Draft RAIs - License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address Generic Safety Issue - 191 and Respond to Generic Letter 2004-02 (EPIDs L-2021-LLA-0059 and L-2021-LLE-0021) Project stage: Draft RAI ML22096A0232022-04-0505 April 2022 NRR E-mail Capture - Callaway Plant - Final RAIs - License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address Generic Safety Issue - 191 and Respond to GL 2004-02 (EPIDs L-2021-LLA-0059 and L-2021-LLE-0021) Project stage: RAI ML22146A3392022-05-26026 May 2022 Enclosure 1: Ameren Missouri Response to NRC RAIs Project stage: Response to RAI ML22146A3372022-05-26026 May 2022, 27 May 2022 Response to Request for Additional Information Regarding Request for License Amendment and Regulatory Exemptions for Risk-Informed Approach to Address GSI-191 and Respond to Generic Letter 2004-02 (LDCN 19-0014) Project stage: Request ULNRC-06735, Response to Request for Additional Information Regarding Request for License Amendment and Regulatory Exemptions for Risk-Informed Approach to Address GSI-191 and Respond to Generic Letter 2004-02 (LDCN 19-0014).2022-05-27027 May 2022 Response to Request for Additional Information Regarding Request for License Amendment and Regulatory Exemptions for Risk-Informed Approach to Address GSI-191 and Respond to Generic Letter 2004-02 (LDCN 19-0014). Project stage: Response to RAI ML22182A4012022-08-23023 August 2022 Callaway - Environmental Assessment & Finding of No Significant Impact Requests for Amendment & Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (EPID L-2021-LLA-0059 & L-2021-LLE-0021) Project stage: Request ML22182A4062022-08-23023 August 2022 FRN - Environmental Assessment & Finding of No Significant Impact Requests for Amendment & Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (EPID L-2021-LLA-0059 & L-2021-LLE-0021) Project stage: Other ML22182A4112022-08-23023 August 2022 Letter - Environmental Assessment & Finding of No Significant Impact Requests for Amendment & Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (EPID L-2021-LLA-0059 & L-2021-LLE-00021) Project stage: Other ML22251A3432022-09-0808 September 2022 Correction of Text Contained in Enclosures Provided with Supplements to Request for License Amendment and Regulatory Exemptions for a Risk-Informed Approach to Address GSI-191 and Respond to GL 2004-02 (LDCN 19-0014) Project stage: Supplement ML22220A1302022-10-21021 October 2022 Exemptions from the Requirements of 10 CFR 50.46 and 10 CFR Part 50 Appendix a, General Design Criteria 35, 38, and 41 (EPID L-2021-LLE-0021) (Cover Letter) Project stage: Other ML22220A1312022-10-21021 October 2022 Exemptions from the Requirements of Title 10 of the Code of Federal Regulations (10 CFR) Section 50.46, 10 CFR 50 Appendix a General Design Criteria 35, 38, and 41 (EPID L-2021-LLE-0021) (Exemptions) Project stage: Other ML22220A1322022-10-21021 October 2022 Issuance of Amendment No. 228 Re; Revise Technical Specifications to Address Generic Safety Isusue-191 and Respond to Generic Letter 2004-02 Using Risk-Informed Approach Project stage: Approval ML22220A1292022-10-25025 October 2022 Exemptions from the Requirements of Title 10 of the Code of Federal Regulations (10 CFR) Section 50.46, 10 CFR 50 Appendix a General Design Criteria 35, 38, and 41 (EPID L-2021-LLE-0021) (FRN) Project stage: Other 2021-09-14
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Category:Response to Request for Additional Information (RAI)
MONTHYEARULNRC-06824, Response to Request for Additional Information Regarding Operating Quality Assurance Manual (Oqam) Revision 36A2023-08-17017 August 2023 Response to Request for Additional Information Regarding Operating Quality Assurance Manual (Oqam) Revision 36A ULNRC-06821, Post-Audit Follow-Up Information in Support of Callaways License Amendment Request and Proposed Exemption to Allow Use of Framatome Gaia Fuel (LDCN 22-0002) (EPID L-2022-LLA-0150 and EPID L-2022-LLE-00301)2023-06-21021 June 2023 Post-Audit Follow-Up Information in Support of Callaways License Amendment Request and Proposed Exemption to Allow Use of Framatome Gaia Fuel (LDCN 22-0002) (EPID L-2022-LLA-0150 and EPID L-2022-LLE-00301) ML23156A6372023-06-0505 June 2023 Response to Request for Additional Information Regarding License Amendment Request for Permanent Extension of Type a and Type C Leak Rate Test Frequencies ML23129A7972023-05-0909 May 2023 Response to Audit Questions ML23088A1322023-03-29029 March 2023 Response to Request for Additional Information Regarding Results of Steam Generator Tube In-Service Inspection ML23052A0442023-02-21021 February 2023 Enclosure 2 - Supplement to License Amendment Request ML23052A0422023-02-21021 February 2023 Response to Request for Additional Information and Supplement to License Amendment Request Regarding Spent Fuel Storage (LDCN 22-0015) ML23052A0432023-02-21021 February 2023 Enclosure 1 - Response to Request for Additional Information ML22342B2662022-12-0808 December 2022 Enclosure - Ameren Missouri Response to NRC RAIs ML22335A4992022-11-16016 November 2022 Enclosure 1: Responses to Requested Information ULNRC-06764, Updated Response to RAT HFE-l2022-09-0101 September 2022 Updated Response to RAT HFE-l ULNRC-06755, Enclosure 2: Ameren Missouri Verification Ofagreement Letters with State and EPZ Counties for Proposed Revision to Radiological Emergency Response Plan Regarding Response and Notification Goals2022-07-13013 July 2022 Enclosure 2: Ameren Missouri Verification Ofagreement Letters with State and EPZ Counties for Proposed Revision to Radiological Emergency Response Plan Regarding Response and Notification Goals ML22194A8022022-07-13013 July 2022 Enclosure 1: Ameren Missouri Response to NRC Requests for Additional Information ULNRC-06754, Response to Request for Additional Information Regarding Licensee Amendment Request for Adoption of Alternate Source Term and Revision of Technical Specifications2022-07-0505 July 2022 Response to Request for Additional Information Regarding Licensee Amendment Request for Adoption of Alternate Source Term and Revision of Technical Specifications ML22186A1052022-07-0505 July 2022 Response to Request for Additional Information Regarding Licensee Amendment Request for Adoption of Alternate Source Term and Revision of Technical Specifications ML22146A3392022-05-26026 May 2022 Enclosure 1: Ameren Missouri Response to NRC RAIs ML22068A0292022-03-0808 March 2022 Response to Audit Question/Item 23 in NRC Letter Dated September 14, 2021 ML21286A6822021-10-13013 October 2021 Response to Request for Additional Information Regarding License Amendment Request to Adopt 10 CFR 50.69, Risk-Informed Categorization and Treatment of Structures, Systems and Components for Nuclear Power Reactors ULNRC-06629, Response to Request for Additional Information Pertaining to Additional Request for Exemption from Specific Requirements of 10 CFR Part 26, Fitness for Duty Programs2021-01-0707 January 2021 Response to Request for Additional Information Pertaining to Additional Request for Exemption from Specific Requirements of 10 CFR Part 26, Fitness for Duty Programs ULNRC-06602, Response to Request for Addition Information Pertaining to Revision to Technical Specification (TS) 5.3.1 and Deletion of TS 5.3.1.1 and TS 5.3.1.2 -2020-09-0202 September 2020 Response to Request for Addition Information Pertaining to Revision to Technical Specification (TS) 5.3.1 and Deletion of TS 5.3.1.1 and TS 5.3.1.2 - ML20238C1072020-08-25025 August 2020 Response to Request for Additional Information (Redacted) ULNRC-06591, Supplemental Information for Response to March, 2012 Information Request, Seismic Probabilistic Risk Assessment for Recommendation 2.12020-07-10010 July 2020 Supplemental Information for Response to March, 2012 Information Request, Seismic Probabilistic Risk Assessment for Recommendation 2.1 ML19325D6732019-11-21021 November 2019 Attachment 2 - Callaway Energy Center Seismic Probabilistic Risk Assessment in Response to 50.54(F) Letter with Regard to NTTF 2.1 Seismic - Supplemental Information ML19051A1372019-02-20020 February 2019 Attachment 1: Response to Request for Additional Information ULNRC-06482, Response to Request for Additional Information Pertaining to License Amendment Request for Addition of New Technical Specification 3.7.20, Class 1E Electrical Equipment Air Conditioning (A/C) System.2019-02-0808 February 2019 Response to Request for Additional Information Pertaining to License Amendment Request for Addition of New Technical Specification 3.7.20, Class 1E Electrical Equipment Air Conditioning (A/C) System. ML19039A3542019-02-0808 February 2019 RAI Questions and Responses ML19025A0712019-01-25025 January 2019 Response to Request for Additional Information Pertaining to Relief Request 14R-05 for Relief from Requirements of ASME Code Case N-770-2 Regarding Inspection Intervals for Reactor Vessel Nozzle Dissimilar Metal Welds ULNRC-06479, Attachment a - Mitsubishi Responses to NRC Wjp RAIs2019-01-25025 January 2019 Attachment a - Mitsubishi Responses to NRC Wjp RAIs ULNRC-06440, Response to Generic Letter 2016-01, Monitoring of Neutron-Absorbing Materials in Spent Fuel Pools - Request for Supplemental Information2018-05-31031 May 2018 Response to Generic Letter 2016-01, Monitoring of Neutron-Absorbing Materials in Spent Fuel Pools - Request for Supplemental Information ULNRC-06410, Callaway Plant, Unit 1 - Response to Request for Additional Information Concerning Proposed Revision of FSAR-Described Compliance with Regulatory Guide 1.106 Regarding MOV Thermal Overload Protection (Ldcn 16-0001)2018-02-0505 February 2018 Callaway Plant, Unit 1 - Response to Request for Additional Information Concerning Proposed Revision of FSAR-Described Compliance with Regulatory Guide 1.106 Regarding MOV Thermal Overload Protection (Ldcn 16-0001) ML18036A6762018-02-0505 February 2018 Enclosure 6: Response to Request for Additional Information (RAI) 1.d (MOV Performance Indicator Report for Cycle 21) ML18036A6742018-02-0505 February 2018 Enclosure 5: Response to Request for Additional Information (RAI) 1.d (MOV Performance Indicator Report for Cycle 20) ML18036A6732018-02-0505 February 2018 Enclosure 4: Response to Request for Additional Information (RAI) 1.d (MOV Performance Indicator Report for Cycle 19) ML18036A6722018-02-0505 February 2018 Enclosure 3: Response to Request for Additional Information (RAI) 1.c ULNRC-06410, Response to Request for Additional Information Concerning Proposed Revision of FSAR-Described Compliance with Regulatory Guide 1.106 Regarding MOV Thermal Overload Protection (LDCN 16-0001)2018-02-0505 February 2018 Response to Request for Additional Information Concerning Proposed Revision of FSAR-Described Compliance with Regulatory Guide 1.106 Regarding MOV Thermal Overload Protection (LDCN 16-0001) ML18036A6692018-02-0505 February 2018 Enclosure 1: Responses to Requests for Additional Information ML18036A6712018-02-0505 February 2018 Enclosure 2: Response to Request for Additional Information (RAI) Item 1.a ULNRC-06381, Spent Fuel Pool Evaluation Supplemental Report, Response to NRC Request for Information Pursuant to 10 CFR 50.54(F) Regarding Recommendation 2.1 of the Near-Term Task Force Review of Insights from the Fukushima Dai-ichi Accident2017-10-0303 October 2017 Spent Fuel Pool Evaluation Supplemental Report, Response to NRC Request for Information Pursuant to 10 CFR 50.54(F) Regarding Recommendation 2.1 of the Near-Term Task Force Review of Insights from the Fukushima Dai-ichi Accident ML17138A2132017-05-18018 May 2017 Response to Request for Additional Information Concerning Revision of TS 5.6.5, Core Operating Limits Report (Colr), to Allow the Use of the Paragon and Nexus Core Design Methods (LDCN 16-0011) ULNRC-06357, Response to Request for Additional Information, 2016 Steam Generator Tube Inspections2017-03-23023 March 2017 Response to Request for Additional Information, 2016 Steam Generator Tube Inspections ULNRC-06321, Response to Request for Additional Information, Third 10-Year Interval Inservice Inspection Request for Relief No. I3R-082016-07-0707 July 2016 Response to Request for Additional Information, Third 10-Year Interval Inservice Inspection Request for Relief No. I3R-08 ULNRC-06275, Response to Request for Additional Information (RA) Related to Operating Quality Assurance Manual (Oqam), Revision 31, Oqam Change Notice 15-0022016-01-12012 January 2016 Response to Request for Additional Information (RA) Related to Operating Quality Assurance Manual (Oqam), Revision 31, Oqam Change Notice 15-002 ULNRC-06266, Response to Request for Additional Information, Third 10-Year Interval Inservice Inspection, Request for Relief No. 13R-112015-11-24024 November 2015 Response to Request for Additional Information, Third 10-Year Interval Inservice Inspection, Request for Relief No. 13R-11 ULNRC-06238, Response to Supplemental Request for Additional Information (RAI) Related to License Amendment Request for Emergency Action Level (EAL) Upgrade Adopting NRC-Endorsed NEI 99-01, Revision 62015-08-31031 August 2015 Response to Supplemental Request for Additional Information (RAI) Related to License Amendment Request for Emergency Action Level (EAL) Upgrade Adopting NRC-Endorsed NEI 99-01, Revision 6 ULNRC-06230, Response to Request for Additional Information (RAI) Related to License Amendment Request for Emergency Action Level (EAL) Upgrade Adopting NRC-Endorsed NEI 99-01, Revision 62015-07-16016 July 2015 Response to Request for Additional Information (RAI) Related to License Amendment Request for Emergency Action Level (EAL) Upgrade Adopting NRC-Endorsed NEI 99-01, Revision 6 ULNRC-06233, Submittal of Requested Information on FSAR Section 3.1.2., Per July 9, 2015 Telephone Call2015-07-13013 July 2015 Submittal of Requested Information on FSAR Section 3.1.2., Per July 9, 2015 Telephone Call ULNRC-06227, Response to Request for Additional Information Related to License Amendment Request for Emergency Action Level Upgrade Adopting NRC-Endorsed NEI 99-01, Rev 62015-07-0606 July 2015 Response to Request for Additional Information Related to License Amendment Request for Emergency Action Level Upgrade Adopting NRC-Endorsed NEI 99-01, Rev 6 2023-08-17
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Attachment to ULNRC-06721 Page 1 of 5
- 23. Provide fiber penetration test results and penetration model assumptions that are based on the testing to the extent that the NRC staff can perform confirmatory calculations to validate the in-vessel fiber values used in the analysis.
The NRC staff reviewed the fiber penetration test report. The licensee performed three preliminary tests and a final quality assured test (Test 2) to quantify penetration. The NRC staff was unable to confirm that the model used to calculate the amount of penetration at various strainer loads was realistic or conservative compared to the test results. Specifically, the NRC staff identified that Equation A-50 in the strainer penetration test report (ALION-CAL-CEC-9345-003, Rev. 0) underpredicted the amount of fiber penetration when compared to strainer fiber penetration Test 2 data. The licensee stated that equation A-50 was not directly used to calculate the fiber amounts in the core for the submittal, but that the issue would be investigated because Equation A-50 was pertinent for conditions in the tests. Differences between Equation A-50 and Test 2 results may indicate artifacts in estimates of parameters of empirical fiber penetration functions. The licensee will provide information in a supplement that includes details on the method used to calculate the fiber penetration as the strainer fiber loading changes so that the staff can confirm that the values are realistic when compared to the test results.
Ameren Missouri Response:
Laboratory test data measuring fiber penetration through Callaway Plant ECCS strainer modules are analyzed in ALION-CAL-CEC-9345-003, Rev. 0 (Reference [1]) to determine two model parameters describing prompt penetration while the debris bed is building and two parameters describing long-term shedding during continued flow erosion. Data available for analysis and comparison include three 3-hour duration tests (Test 1a, Test 1b, and Test 1c) that were performed as non-safety-related exploratory exercises to examine possible effects of pH on fiber penetration, and one 20-hour test (Test 2) that was performed as the safety-related test of record under the Alden Research Laboratory Appendix B quality assurance program and Nuclear Procurement Issues Committee (NUPIC) guidelines. Test 1c bag-filter masses indicated the largest amount of fiber penetration, so Test 2 used the same pH and initial fiber loading schedule but continued with additional fiber batch loads and additional filter collections during shedding. The Test 2 fiber load spans the 300-lbm equivalent determined by full-debris-load testing to be the RoverD fiber capacity for a single ECCS strainer and includes shedding rate data over a much longer time needed to more accurately model shedding during 30-days of core cooling.
Figure Q23.1 illustrates cumulative fiber penetration data for all four tests. Although Test 1c and Test 2 used the same solution pH and loading schedule, Test 2 results are fully consistent with Test 1a and Test 1b data, indicating a negligible pH effect on fiber penetration at the tested flow velocity. At all fiber loads, Test 1c cumulative fiber penetration mass lies above the 95th percentile of cumulative fiber penetration mass obtained from the other three tests, indicating a possible anomaly in fiber preparation or test procedure implementation under the exploratory, abbreviated test format. Because the close agreement between Test 1a, Test 1b, and Test 2, is typical of replicates performed under the same test procedure, Test 1c is not considered to represent a realistic fiber penetration result.
Attachment to ULNRC-06721 Page 2 of 5 Figure Q23.1. Cumulative fiber penetration mass from four independent tests.
First-order differential equations describing fiber inventory on the strainer were used to fit four model parameters in an optimization search that minimizes the sum of squared errors between Test 2 measured bag-filter masses and simulated bag-filter masses. Separate equations were used to simulate bag-filter measurements when fiber was being loaded (loading filters) and bag-filter measurements when only shedding occurred (shedding filters), but squared errors were minimized over all Test 2 data points combined. A correlation coefficient of 0.96 was obtained for Test 2 filter data. Although not as strong as the coefficients obtained for Test 1a and Test 1b, the fit is judged to be relatively good for a simple four-parameter model describing complex dynamic debris-bed phenomena. Model parameters were not fit to sequentially cumulative fiber penetration mass, because cumulative mass is a derived quantity that can smooth variability present in direct measurements.
Simulation accuracy is improved by using separate equations to model shedding and penetration during a fiber load, but global minimum least squares optimization tends to emphasize better model agreement with large filter bag masses arising from direct penetration observed during early fiber batches. Less precise agreement is obtained for the smaller shedding-only filter-bag measurements, which affects the two model parameter values that predict shedding.
Equation A-50 in Reference [1] was developed to provide a high-level estimate of total fiber penetration occurring after infinite sump recirculation time using model parameters calibrated to individual downstream filter-bag masses collected during strainer testing and assuming that prompt penetration and delayed shedding proceed as two separate process that do not interact.
In a real debris bed, prompt penetration and delayed shedding both depend on the amount of fiber resident in the debris bed as a function of time, so a solution of the coupled differential equations is needed to obtain the highest fidelity comparisons to time-dependent test data.
However, Equation A-50 is useful for confirming the reasonableness of Test 2 fiber penetration
Attachment to ULNRC-06721 Page 3 of 5 parameters because the test procedure intentionally separates, to the maximum extent practical, direct penetration that occurs during fiber loading from continual shedding.
Figure Q23.2 (left graph) shows the correlation between measured cumulative fiber penetration (x axis) and cumulative fiber penetration modeled by Eq. A-50 (y axis) using reported Test 2 optimized parameters. The later, small-increment measurements controlled by shedding phenomena (upper right correlation points) are underestimated by the model prediction.
Equation A-50 essentially adds the entire sheddable fiber inventory (a fixed fraction of the sequential cumulative load) to the cumulative prompt penetration mass, so the graph suggests that the Test 2 parameter describing the amount of sheddable fiber is too small to provide a close fit to the data. (It should be noted that full solutions of the time-dependent equations show the same trend, confirming that Eq. A-50 is a useful approximation).
Figure Q23.2 (right graph) shows the improved correlation obtained by doubling the Test 2 sheddable inventory. The agreement between Eq A-50 predictions of total fiber penetration and test data for cumulative fiber penetration is now very good. It is possible that the same result can be obtained by separately minimizing the sum of squared errors for filter data obtained during fiber loading and filter data obtained for shedding only.
Figure Q23.2. Comparison of Test 2 cumulative fiber penetration correlation with derived sheddable fiber (left) and doubled sheddable fiber (right).
Doubling the Test 2 sheddable fiber fraction parameter is observed to raise the predicted final cumulative fiber penetration mass by approximately 13% at the final plant-equivalent total fiber load of 300 lbm. The implications of this increase for downstream in-vessel effects are examined by revisiting fiber histories presented in Reference [2]. Four cases are considered in Reference.[2]: 1) dual strainer and dual spray train operation with maximum flow split to alternate flow paths, 2) dual strainer and dual spray train operation with minimum flow split to alternate flow paths, 3) Maximum Safeguards conditions with dual strainer and single spray train operation with maximum flow split to alternate flow paths, and 4) Maximum Safeguards
Attachment to ULNRC-06721 Page 4 of 5 conditions with dual strainer and single spray train operation with minimum flow split to alternate flow paths. Although dual train plant LOCA response is expected with high reliability, the Maximum Safeguards configuration having one failed CS train maximizes debris delivery to the reactor vessel, because less fiber is returned to the pool through spray flow. Therefore, Cases 3 and 4 were reevaluated to account for doubling the fraction of Test 2 sheddable fiber. Figure Q23.3 (left graph) illustrates adjusted fiber histories assuming minimum flow to alternate flow paths, and Figure Q23.3 (right graph) illustrates adjusted fiber histories assuming maximum flow to alternate flow paths.
Fig. Q23.3. Core fiber histories with Maximum Safeguards configuration (one spray train failed),
double Test 2 sheddable fiber, and minimum AFP flow (left) vs maximum AFP flow (right).
Comparison of Figure Q23.3 to Figure 3.n-4 and Figure 3n-5 in Reference [2] shows that total fiber in the vessel is now approximately 92 g/FA rather than 89 g/FA. The flow split assigned to alternate flow paths changes the partition of debris between the core inlet and the heated core region but does not change the total vessel fiber inventory. All of the WCAP-17788-P performance requirements are still satisfied even with increased Test 2 fiber shedding.
Downstream ex-vessel analyses were performed using a maximum DEGB generated and transported fiber source term of 1157 lbm. Using Eq. A-50 and the reported Test 2 sheddable fiber fraction yields a fiber penetration source term of 53.15 lbm against which all internal ex-vessel components were evaluated and found to sustain acceptable wear (Reference [3]).
Using the RoverD transported fiber load of 300 lbm in Eq. A-50 with double the reported Test 2 sheddable fiber fraction yields a fiber penetration source term of 46.5 lbm. Therefore, the increased sheddable fiber fraction cannot increase risk of core damage caused by internal wear and erosion with respect to the RoverD strainer load. Further evaluation of the maximum transported fiber source (1157 lbm) yields a fiber penetration source term of 60.8 lbm when shedding is doubled, which also passes all internal wear and erosion criteria.
This analysis confirms that a simple change to Test 2 fiber penetration parameters (doubling the sheddable fiber fraction) improves agreement of the model with cumulative fiber penetration data and does not increase risk of core blockage caused by scenarios with less than 300 lbm of fiber debris arriving at two operable strainers. The core blockage analysis is based on the most
Attachment to ULNRC-06721 Page 5 of 5 conservative pump configuration with two strainers operating at maximum ECCS flow but with only one train of spray flow. Similarly, doubling the sheddable fiber fraction does not increase the risk of core damage caused by downstream ex-vessel component failures. For the purpose of documentation simplicity, the sheddable fiber fraction applied in the baseline risk calculation has not been changed. The sensitivity cases presented here confirm that no additional risk is introduced by doubling the fiber penetration model parameter.
References:
[1] Strainer Penetration Test Report, ALION-CAL-CEC-9345-003, Rev. 0 (December 2017).
[2] ULNRC-06651, July 7, 2021, (ADAMS Accession No. ML21203A192) Enclosure 3, Section 3.n., "Downstream Effects - Fuel and Vessel," (pp.99-106 of 126).
[3] CEC Downstream Ex-Vessel Effects Evaluation for ECCS Components, ALION-CAL-CEC-9143-020, Rev 0.