ML061730002: Difference between revisions

From kanterella
Jump to navigation Jump to search
(Created page by program invented by StriderTol)
 
(Created page by program invented by StriderTol)
 
(2 intermediate revisions by the same user not shown)
Line 2: Line 2:
| number = ML061730002
| number = ML061730002
| issue date = 06/26/2006
| issue date = 06/26/2006
| title = Browns Ferry, Unit 1, RAI, Extended Power Uprate Round 6 (TAC MC3812) (TS-431)
| title = RAI, Extended Power Uprate Round 6 (TAC MC3812) (TS-431)
| author name = Chernoff M H
| author name = Chernoff M
| author affiliation = NRC/NRR/ADRO/DORL/LPLD
| author affiliation = NRC/NRR/ADRO/DORL/LPLD
| addressee name = Singer K W
| addressee name = Singer K
| addressee affiliation = Tennessee Valley Authority
| addressee affiliation = Tennessee Valley Authority
| docket = 05000259
| docket = 05000259
Line 19: Line 19:


=Text=
=Text=
{{#Wiki_filter:June 26, 2006Mr. Karl W. Singer Chief Nuclear Officer and Executive Vice President Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN 37402-2801
{{#Wiki_filter:June 26, 2006 Mr. Karl W. Singer Chief Nuclear Officer and Executive Vice President Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN 37402-2801


==SUBJECT:==
==SUBJECT:==
BROWNS FERRY NUCLEAR PLANT, UNIT 1 - REQUEST FOR ADDITIONALINFORMATION FOR EXTENDED POWER UPRATE - ROUND 6 (TS-431) (TAC NO. MC3812)  
BROWNS FERRY NUCLEAR PLANT, UNIT 1 REQUEST FOR ADDITIONAL INFORMATION FOR EXTENDED POWER UPRATE - ROUND 6 (TS-431)
(TAC NO. MC3812)


==Dear Mr. Singer:==
==Dear Mr. Singer:==


By letter dated June 28, 2004, as supplemented by letters dated August 23, 2004, February 23,April 25, June 6, and December 19, 2005, February 1 and 28, March 7, 9, 23, and 31, April 13,May 5, 11, 15, and 16, and June 2, 2006, the Tennessee Valley Authority (TVA, the licensee),submitted to the U.S. Nuclear Regulatory Commission (NRC) an amendment request forBrowns Ferry Nuclear Plant, Unit 1. The proposed amendment would change the operating license to increase the maximum authorized power level from 3293 to 3952 megawatts thermal.
By letter dated June 28, 2004, as supplemented by letters dated August 23, 2004, February 23, April 25, June 6, and December 19, 2005, February 1 and 28, March 7, 9, 23, and 31, April 13, May 5, 11, 15, and 16, and June 2, 2006, the Tennessee Valley Authority (TVA, the licensee),
This change represents an increase of approximately 20 percent above the current maximum authorized power level for Unit 1. The proposed amendment would also change the Unit 1 licensing bases and associated Technical Specifications to credit 3 pounds per square inch gauge (psig) for containment overpressure following a loss-of-coolant accident and increase the reactor steam dome pressure by 30 psig. With regards to the requests for additional information (RAIs) in the APLA section, the NRCstaff reviewed the response to its original RAI (SPSB-A.11 - October 3, 2005, request) involving the use of containment accident pressure in the calculation of net positive suction headavailable to the core spray and low pressure coolant injection pumps. The response was provided in a letter dated March 23, 2006. The NRC staff notes that the licensee requestedadditional time to respond, provided the response later than committed, and failed to fully answer the question. As indicated in the March 1, 2006, letter to TVA, the timeliness andquality of the responses to the NRC staff's RAIs are essential to support the timely completionof this review. Further delays of this nature will significantly chall enge the NRC staff's ability tosupport the requested completion date.
submitted to the U.S. Nuclear Regulatory Commission (NRC) an amendment request for Browns Ferry Nuclear Plant, Unit 1. The proposed amendment would change the operating license to increase the maximum authorized power level from 3293 to 3952 megawatts thermal.
K. Singer-2-A response to the enclosed RAI is needed before the NRC staff can complete the review. Thisrequest was discussed with your staff on June 14, 2006, and it was agreed that a response would be provided by June 30, 2006. If you have any questions, please contact Ms. Eva Brown at (301) 415-2315.Sincerely,/RA/Margaret H. Chernoff, Project ManagerPlant Licensing Branch II-2 Division of Operating Reactor Licensing Office of Nuclear Reactor RegulationDocket No. 50-259
This change represents an increase of approximately 20 percent above the current maximum authorized power level for Unit 1. The proposed amendment would also change the Unit 1 licensing bases and associated Technical Specifications to credit 3 pounds per square inch gauge (psig) for containment overpressure following a loss-of-coolant accident and increase the reactor steam dome pressure by 30 psig.
With regards to the requests for additional information (RAIs) in the APLA section, the NRC staff reviewed the response to its original RAI (SPSB-A.11 - October 3, 2005, request) involving the use of containment accident pressure in the calculation of net positive suction head available to the core spray and low pressure coolant injection pumps. The response was provided in a letter dated March 23, 2006. The NRC staff notes that the licensee requested additional time to respond, provided the response later than committed, and failed to fully answer the question. As indicated in the March 1, 2006, letter to TVA, the timeliness and quality of the responses to the NRC staffs RAIs are essential to support the timely completion of this review. Further delays of this nature will significantly challenge the NRC staffs ability to support the requested completion date.
 
K. Singer                                   A response to the enclosed RAI is needed before the NRC staff can complete the review. This request was discussed with your staff on June 14, 2006, and it was agreed that a response would be provided by June 30, 2006. If you have any questions, please contact Ms. Eva Brown at (301) 415-2315.
Sincerely,
                                          /RA/
Margaret H. Chernoff, Project Manager Plant Licensing Branch II-2 Division of Operating Reactor Licensing Office of Nuclear Reactor Regulation Docket No. 50-259


==Enclosures:==
==Enclosures:==
: 1. RAI, Redacted Version                     2. RAI, Proprietary Versioncc w/enclosure 1: See next page  
: 1. RAI, Redacted Version
: 2. RAI, Proprietary Version cc w/enclosure 1: See next page


ML061730002Enclosure 2: ML061840282   NRR-088OFFICELPL2-2/PMLPL2-2//PMLPL2-2//LAAPLA/BCNAMEEBrownMChernoffBClaytonMRubin by memo DATE06/22/0606/22/0606/22/066/08/06OFFICEACVB/BCSBWB/BCLPL2-2/BCNAMERDennig by memoGCranston by memoMMarshall DATE6/15/066/15/0606/26/06  
ML061730002            Enclosure 2: ML061840282             NRR-088 OFFICE    LPL2-2/PM            LPL2-2//PM              LPL2-2//LA        APLA/BC NAME      EBrown                MChernoff              BClayton          MRubin by memo DATE      06/22/06              06/22/06              06/22/06          6/08/06 OFFICE    ACVB/BC              SBWB/BC                LPL2-2/BC NAME      RDennig by memo      GCranston by memo      MMarshall DATE      6/15/06              6/15/06                06/26/06


==SUBJECT:==
==SUBJECT:==
BROWNS FERRY NUCLEAR PLANT, UNIT 1 - REQUEST FOR ADDITIONALINFORMATION REGARDING EXTENDED POWER UPRATE (TAC NO. MC3812)Document Date: June 26, 2006Distribution w/ Enclosure 1
BROWNS FERRY NUCLEAR PLANT, UNIT 1 REQUEST FOR ADDITIONAL INFORMATION REGARDING EXTENDED POWER UPRATE (TAC NO. MC3812)
:PUBLICLPLII-2 R/F RidsOgcRp RidsAcrsAcnwMailCenter RidsNrrPMEBrown RidsNrrPMMChernoff RidsNrrLABClayton (hard copy)
Document Date: June 26, 2006 Distribution w/ Enclosure 1:
PUBLIC LPLII-2 R/F RidsOgcRp RidsAcrsAcnwMailCenter RidsNrrPMEBrown RidsNrrPMMChernoff RidsNrrLABClayton (hard copy)
RidsNrrDorlLpl2-2 (MMarshall)
RidsNrrDorlLpl2-2 (MMarshall)
RidsNrrDorl (CHaney/CHolden)
RidsNrrDorl (CHaney/CHolden)
TAlexion GThomas MRazzaque THuang ZAbdullahi MRubin MStutzke SLaur RLobel RDennig RGoel REQUEST FOR ADDITIONAL INFORMATION EXTENDED POWER UPRATETENNESSEE VALLEY AUTHORITYBROWNS FERRY NUCLEAR PLANT, UNIT 1DOCKET NO. 50-259APLA (Previously SPSB-A)22.It is recognized that the need to have containment accident pressure for emergencycore cooling system (ECCS) net positive suction head (NPSH) should be based on arealistic analysis consistent with current probabilistic risk assessment (PRA) practices,as contrasted to a deterministic, design-basis calculation that employs excessive conservatism. Discuss which typical PRA accident sequences realistically require containment accident pressure in order to ensure that the ECCS pumps remain functional. This should include sequences currently modeled in the Browns Ferry PRA models or similar sequences, not currently modeled, that could be risk-significant if containment accident pressure is necessary and not available. This should also consider realistic fire scenarios, such as those considered in the Individual Plant Evaluation of External Events for Severe Accident Vulnerabilities study. 23.For each PRA accident sequence that realistically requires containment accidentpressure, describe how much pressure is required and for what period of time.24.For each accident sequence in #23 above, estimate the risk associated with the needfor that accident pressure (i.e., the risk above the level that would exist if the ECCSpumps could function satisfactorily without the need for containment accident pressure).
TAlexion GThomas MRazzaque THuang ZAbdullahi MRubin MStutzke SLaur RLobel RDennig RGoel
While a realistic core damage frequency and large early release frequency are the desired metrics for this risk estimate, the licensee may utilize sensitivity studies, bounding analyses or qualitative arguments, where appropriate, provided all conclusions are substantially supported by the discussion.ACVB37.The term design flow rate is used to describe the core spray pump flow rate and theresidual heat removal (RHR) pump flow rate assumed in the NPSH analyses. Defineprecisely the "design flow rate" in terms of the pum p and system curves. 38.The current Updated Final Safety Analyses Report Table 14.6-4 shows a higher drywellvolume for Case 3, the limiting case for drywell pressure and temperature, than for Cases 1, 2 and 4. Discuss why there is a larger drywell volume assumed for this case, and whether the same assumption is made for the extended power uprate (EPU). 39.Provide the calculations used to determine the containment conditions (drywell, wetwelland suppression pool) for the loss-of-coolant accident (LOCA), Anticipated Transient Without Scram (ATWS), Station Blackout (SBO) and Appendix R Fire events.40.Describe how the proposed crediting of containment accident pressure in determiningavailable NPSH compares with the positions of Section 2.1.1 of Regulatory Guide 1.82, Water Sources for Long-Term Recirculation Cooling Following a Loss-of-Coolant Accident, Revision 3, dated November 2003.41.The units have drywell coolers which operate during normal plant operation. Addresswhether the drywell coolers are conservatively assumed to continue operation following accident initiation for the LOCA, ATWS, SBO and Appendix R Fire events. 42.Section 4.2.5 of the General Electric (GE) Analysis Report, PUSAR, states that theNPSH margins were calculated based on conservatively assuming RHR maximum flow rates and containment spray design flow rates in the short term analyses and RHR andcontainment spray design flow rates in the long term analyses. Describe the design provisions or operator actions that limit the pump flows to these values.43.Describe how the make-up of nitrogen to the drywell and wetwell atmospheres couldserve as a verification of containment integrity during normal operation. 44.Describe the measures taken to ensure that all containment penetrations are properlyisolated prior to and during operation. 45.Describe any other actions/programs which contribute to assurance that thecontainment is isolated. 46.Address whether the RHR and core spray pumps can be throttled to increase availableNPSH and decrease required NPSH. Discuss what, if any, guidance is provided in the emergency operating instructions (EOIs) or abnormal operating instructions regarding throttling these pumps to preserve NPSH margin during accident conditions.47.Discuss whether any of the units have features to automatically terminate drywell orwetwell spray. Describe the conditions under which the operator would terminate drywell and/or wetwell spray under accident conditions in accordance with the EOIs. Address those measures put in place to prevent an operator from reducing wetwell pressure below that needed for adequate available NPSH. 48.In a letter dated September 4, 1998, Tennessee Valley Authority (TVA) requested theuse of containment overpressure for Units 2 and 3. The letter stated that the short termNPSH analysis assumes a double-ended recirculation pump discharge line break while the long term analysis assumes a double-ended suction line break. Address whether this is the case for the EPU analyses. Any difference in assumptions should be explained.49.Address the criteria in the EOIs for initiating drywell and wetwell sprays. Discuss how the timing of the actions resulting from these criteria compares with the 10-minute assumption in the accident analyses for initiating suppression pool cooling. Discuss how the times for initiating drywell and wetwell sprays using the EOI criteria comparewith times obtained in simulator training.50.Using Figure ACVB 7-1 of the March 7, 2006, letter, explain the physical occurrenceswhich result in (1) the reduction in the steep slope at approximately 2 seconds; (2) the small sudden increase at approximately 8 seconds; and (3) the following steep decrease. Discuss at what time the torus-to-drywell vacuum breakers to actuate.51.Page E1-3 of the letter dated September 4, 1998, indicates that containment pressure isonly needed in the short term for the RHR pump at the maximum flow conditions andthat "other pathways are available and functional without containment overpressurebeing relied upon.Discuss whether this is still true with the EPU NPSH analyses. Ifstill true, elaborate on this statement.52.In the safety evaluation dated September 3, 1999, on the credit for containment accidentpressure in determining available NPSH, TVA discussed a 10-year frequency for suppression pool cleaning. Discuss whether suppression pool cleaning is st ill done on a10-year frequency.53.For Figures ACVB 7-3 and ACVB 7-4 from the March 7, 2006, letter, explain thephysical occurrences that produce the significant changes in the shape of the curves asa function of time.54.Table ACVB 22-1, in response to ACVB 22 from the March 7, 2006, letter, states thatthe licensing basis calculation of NPSH assumes no heat sinks while the realistic calculation does. Address whether the reverse should be true to ensure conservatism.
 
Also, see TVA reply to ACVB 27 and Table SPSB-A.11-2, which states that not crediting heat sinks is conservative.55.Table ACVB 22-1, in response to ACVB 22 from the March 7, 2006, letter, gives valuesof wetwell airspace and suppression pool volume that sum to different values for the realistic and the licensing basis values. Discuss whether the sums should be the same and equal to the total volume of the wetwell.56.The response to RAI ACVB 18 provided curves of pressures and temperatures for theevents crediting containment accident pressure for available NPSH. The curves for ATWS and Appendix R Fire should be extended to provide the total time that containment accident pressure is needed for available NPSH.57.The response to RAI SPSB-A.11 provided Table SPSB-A.11-2, which containscalculations of suppression pool temperature with various assumptions. The cases are identified as either GE or TVA. Describe the analytical methods used for the TVA calculations and the steps taken to ensure a meaningful comparison with SHEX.58.In Table 6 of Calculation MD-Q0999-970046, Rev. 8, provided in the March 23, 2006,response, the NPSH required (NPSHR) of the RHR pumps varies even when the pumpshave the same flow rate. The Core Spray pumps, all with the same flow rate, also have the same value of NPSHR. Explain why the NPSHR varies even when the pumps have the same flow rate. SBWB26. Provide the following bundle operating conditions with exposure:
REQUEST FOR ADDITIONAL INFORMATION EXTENDED POWER UPRATE TENNESSEE VALLEY AUTHORITY BROWNS FERRY NUCLEAR PLANT, UNIT 1 DOCKET NO. 50-259 APLA (Previously SPSB-A)
!maximum bundle power, !maximum bundle power/flow ratio, !exit void fraction of maximum power bundle, !maximum channel exit void fraction, !peak linear heat generation rate, and
: 22. It is recognized that the need to have containment accident pressure for emergency core cooling system (ECCS) net positive suction head (NPSH) should be based on a realistic analysis consistent with current probabilistic risk assessment (PRA) practices, as contrasted to a deterministic, design-basis calculation that employs excessive conservatism. Discuss which typical PRA accident sequences realistically require containment accident pressure in order to ensure that the ECCS pumps remain functional. This should include sequences currently modeled in the Browns Ferry PRA models or similar sequences, not currently modeled, that could be risk-significant if containment accident pressure is necessary and not available. This should also consider realistic fire scenarios, such as those considered in the Individual Plant Evaluation of External Events for Severe Accident Vulnerabilities study.
!peak end-of-cycle (EOC) nodal exposure.Provide the maximum bundle operating conditions relative to EPU plants. Include theplant-specific data in the plots containing the high density and EPU plants maximumbundle operating conditions. Since there are no recent Unit 1 pre-EPU data and the units are similar, include the Units 2 and 3 pre-EPU data in the plots.27.Provide quarter core map (assuming core symmetry) showing the bundle maximumlinear heat generation rate and the minimum critical power ratio for beginning-of-cycle,middle-of-cycle and EOC. Similarly, show the associated bundle powers andexposures.28.Figure 2-4 of licensing topical report, NEDC-33173P, Applicability of GE Methods toExpanded Operating Domain, shows the cold critical eigenvalues of reference plants.
: 23. For each PRA accident sequence that realistically requires containment accident pressure, describe how much pressure is required and for what period of time.
Figure 2-5 of NEDC -33173P shows the measured and predicted eigenvalues for Reference Plants. Provide the pre-EPU Units 2 and 3 cold critical eigenvalues measured and predicted differences for previous cycles based on the GE methods. Provide evaluation of any available local critical and startup shutdown calculations. 29. Provide a discussion addressing whether the traversing-in-core probes (TIPs) aregamma or thermal TIPs.30. Based on the EPU Cycle core design, establish whether Unit 1 will experience bypassvoiding [                                                  ]. Specify the peak bypass calculated for any four bundle bypass zone at EPU conditions. Discuss why the bypass voiding is [           
: 24. For each accident sequence in #23 above, estimate the risk associated with the need for that accident pressure (i.e., the risk above the level that would exist if the ECCS pumps could function satisfactorily without the need for containment accident pressure).
While a realistic core damage frequency and large early release frequency are the desired metrics for this risk estimate, the licensee may utilize sensitivity studies, bounding analyses or qualitative arguments, where appropriate, provided all conclusions are substantially supported by the discussion.
ACVB
: 37. The term design flow rate is used to describe the core spray pump flow rate and the residual heat removal (RHR) pump flow rate assumed in the NPSH analyses. Define precisely the design flow rate in terms of the pump and system curves.
: 38. The current Updated Final Safety Analyses Report Table 14.6-4 shows a higher drywell volume for Case 3, the limiting case for drywell pressure and temperature, than for Cases 1, 2 and 4. Discuss why there is a larger drywell volume assumed for this case, and whether the same assumption is made for the extended power uprate (EPU).
Enclosure 1
: 39. Provide the calculations used to determine the containment conditions (drywell, wetwell and suppression pool) for the loss-of-coolant accident (LOCA), Anticipated Transient Without Scram (ATWS), Station Blackout (SBO) and Appendix R Fire events.
: 40. Describe how the proposed crediting of containment accident pressure in determining available NPSH compares with the positions of Section 2.1.1 of Regulatory Guide 1.82, Water Sources for Long-Term Recirculation Cooling Following a Loss-of-Coolant Accident, Revision 3, dated November 2003.
: 41. The units have drywell coolers which operate during normal plant operation. Address whether the drywell coolers are conservatively assumed to continue operation following accident initiation for the LOCA, ATWS, SBO and Appendix R Fire events.
: 42. Section 4.2.5 of the General Electric (GE) Analysis Report, PUSAR, states that the NPSH margins were calculated based on conservatively assuming RHR maximum flow rates and containment spray design flow rates in the short term analyses and RHR and containment spray design flow rates in the long term analyses. Describe the design provisions or operator actions that limit the pump flows to these values.
: 43. Describe how the make-up of nitrogen to the drywell and wetwell atmospheres could serve as a verification of containment integrity during normal operation.
: 44. Describe the measures taken to ensure that all containment penetrations are properly isolated prior to and during operation.
: 45. Describe any other actions/programs which contribute to assurance that the containment is isolated.
: 46. Address whether the RHR and core spray pumps can be throttled to increase available NPSH and decrease required NPSH. Discuss what, if any, guidance is provided in the emergency operating instructions (EOIs) or abnormal operating instructions regarding throttling these pumps to preserve NPSH margin during accident conditions.
: 47. Discuss whether any of the units have features to automatically terminate drywell or wetwell spray. Describe the conditions under which the operator would terminate drywell and/or wetwell spray under accident conditions in accordance with the EOIs. Address those measures put in place to prevent an operator from reducing wetwell pressure below that needed for adequate available NPSH.
: 48. In a letter dated September 4, 1998, Tennessee Valley Authority (TVA) requested the use of containment overpressure for Units 2 and 3. The letter stated that the short term NPSH analysis assumes a double-ended recirculation pump discharge line break while the long term analysis assumes a double-ended suction line break. Address whether this is the case for the EPU analyses. Any difference in assumptions should be explained.
: 49. Address the criteria in the EOIs for initiating drywell and wetwell sprays. Discuss how the timing of the actions resulting from these criteria compares with the 10-minute assumption in the accident analyses for initiating suppression pool cooling. Discuss
 
how the times for initiating drywell and wetwell sprays using the EOI criteria compare with times obtained in simulator training.
: 50. Using Figure ACVB 7-1 of the March 7, 2006, letter, explain the physical occurrences which result in (1) the reduction in the steep slope at approximately 2 seconds; (2) the small sudden increase at approximately 8 seconds; and (3) the following steep decrease. Discuss at what time the torus-to-drywell vacuum breakers to actuate.
: 51. Page E1-3 of the letter dated September 4, 1998, indicates that containment pressure is only needed in the short term for the RHR pump at the maximum flow conditions and that other pathways are available and functional without containment overpressure being relied upon. Discuss whether this is still true with the EPU NPSH analyses. If still true, elaborate on this statement.
: 52. In the safety evaluation dated September 3, 1999, on the credit for containment accident pressure in determining available NPSH, TVA discussed a 10-year frequency for suppression pool cleaning. Discuss whether suppression pool cleaning is still done on a 10-year frequency.
: 53. For Figures ACVB 7-3 and ACVB 7-4 from the March 7, 2006, letter, explain the physical occurrences that produce the significant changes in the shape of the curves as a function of time.
: 54. Table ACVB 22-1, in response to ACVB 22 from the March 7, 2006, letter, states that the licensing basis calculation of NPSH assumes no heat sinks while the realistic calculation does. Address whether the reverse should be true to ensure conservatism.
Also, see TVA reply to ACVB 27 and Table SPSB-A.11-2, which states that not crediting heat sinks is conservative.
: 55. Table ACVB 22-1, in response to ACVB 22 from the March 7, 2006, letter, gives values of wetwell airspace and suppression pool volume that sum to different values for the realistic and the licensing basis values. Discuss whether the sums should be the same and equal to the total volume of the wetwell.
: 56. The response to RAI ACVB 18 provided curves of pressures and temperatures for the events crediting containment accident pressure for available NPSH. The curves for ATWS and Appendix R Fire should be extended to provide the total time that containment accident pressure is needed for available NPSH.
: 57. The response to RAI SPSB-A.11 provided Table SPSB-A.11-2, which contains calculations of suppression pool temperature with various assumptions. The cases are identified as either GE or TVA. Describe the analytical methods used for the TVA calculations and the steps taken to ensure a meaningful comparison with SHEX.
: 58. In Table 6 of Calculation MD-Q0999-970046, Rev. 8, provided in the March 23, 2006, response, the NPSH required (NPSHR) of the RHR pumps varies even when the pumps have the same flow rate. The Core Spray pumps, all with the same flow rate, also have the same value of NPSHR. Explain why the NPSHR varies even when the pumps have the same flow rate.


                                            ]. Also calculate the bypass voiding for the se cond cyclewhere the large batches of fresh fuel loaded in Unit 1 will be at the most reactive state.31.Based on the first/second EPU Cycle core design, determine the bypass voiding at thedifferent local power range monitor elevations after a recirculation pump trip. Perform the calculations on limiting conditions (initial condition, axial power distribution and in-channel voids) and provide the results.
SBWB
Mr. Karl W. SingerBROWNS FERRY NUCLEAR PLANTTennessee Valley Authority
: 26. Provide the following bundle operating conditions with exposure:
      !      maximum bundle power,
      !      maximum bundle power/flow ratio,
      !      exit void fraction of maximum power bundle,
      !      maximum channel exit void fraction,
      !      peak linear heat generation rate, and
      !      peak end-of-cycle (EOC) nodal exposure.
Provide the maximum bundle operating conditions relative to EPU plants. Include the plant-specific data in the plots containing the high density and EPU plants maximum bundle operating conditions. Since there are no recent Unit 1 pre-EPU data and the units are similar, include the Units 2 and 3 pre-EPU data in the plots.
: 27. Provide quarter core map (assuming core symmetry) showing the bundle maximum linear heat generation rate and the minimum critical power ratio for beginning-of-cycle, middle-of-cycle and EOC. Similarly, show the associated bundle powers and exposures.
: 28. Figure 2-4 of licensing topical report, NEDC-33173P, Applicability of GE Methods to Expanded Operating Domain, shows the cold critical eigenvalues of reference plants.
Figure 2-5 of NEDC -33173P shows the measured and predicted eigenvalues for Reference Plants. Provide the pre-EPU Units 2 and 3 cold critical eigenvalues measured and predicted differences for previous cycles based on the GE methods.
Provide evaluation of any available local critical and startup shutdown calculations.
: 29. Provide a discussion addressing whether the traversing-in-core probes (TIPs) are gamma or thermal TIPs.
: 30. Based on the EPU Cycle core design, establish whether Unit 1 will experience bypass voiding [                                  ]. Specify the peak bypass calculated for any four bundle bypass zone at EPU conditions. Discuss why the bypass voiding is [
                                    ]. Also calculate the bypass voiding for the second cycle where the large batches of fresh fuel loaded in Unit 1 will be at the most reactive state.
: 31. Based on the first/second EPU Cycle core design, determine the bypass voiding at the different local power range monitor elevations after a recirculation pump trip. Perform the calculations on limiting conditions (initial condition, axial power distribution and in-channel voids) and provide the results.


cc:
Mr. Karl W. Singer                              BROWNS FERRY NUCLEAR PLANT Tennessee Valley Authority cc:
Mr. Ashok S. Bhatnagar, Senior Vice President Nuclear Operations Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN  37402-2801  Mr. Larry S. Bryant, Vice PresidentNuclear Engineering & Technical Services Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN  37402-2801Brian O'Grady, Site Vice PresidentBrowns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL  35609Mr. Robert J. Beecken, Vice PresidentNuclear Support Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN 37402-2801   General CounselTennessee Valley Authority ET 11A 400 West Summit Hill DriveKnoxville, TN 37902Mr. John C. Fornicola, ManagerNuclear Assurance and Licensing Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN  37402-2801Mr. Bruce Aukland, Plant ManagerBrowns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL 35609Mr. Masoud Bajestani, Vice PresidentBrowns Ferry Unit 1 Restart Browns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL  35609Mr. Robert G. Jones, General ManagerBrowns Ferry Site Operations Browns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL  35609Mr. Larry S. MellenBrowns Ferry Unit 1 Project Engineer Division of Reactor Projects, Branch 6 U.S. Nuclear Regulatory Commission 61 Forsyth Street, SW.
Mr. Ashok S. Bhatnagar, Senior Vice President Mr. Robert G. Jones, General Manager Nuclear Operations                            Browns Ferry Site Operations Tennessee Valley Authority                   Browns Ferry Nuclear Plant 6A Lookout Place                             Tennessee Valley Authority 1101 Market Street                           P.O. Box 2000 Chattanooga, TN 37402-2801                   Decatur, AL 35609 Mr. Larry S. Bryant, Vice President          Mr. Larry S. Mellen Nuclear Engineering & Technical Services      Browns Ferry Unit 1 Project Engineer Tennessee Valley Authority                    Division of Reactor Projects, Branch 6 6A Lookout Place                              U.S. Nuclear Regulatory Commission 1101 Market Street                            61 Forsyth Street, SW.
Suite 23T85 Atlanta, GA 30303-8931 Mr. Glenn W. Morris, Manager Corporate Nuclear Licensing and Industry Affairs Tennessee Valley Authority 4X Blue Ridge 1101 Market Street Chattanooga, TN 37402-2801Mr. William D. Crouch, M anagerLicensing and Industry Affairs Browns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL 35609Senior Resident InspectorU.S. Nuclear Regulatory Commission Browns Ferry Nuclear Plant 10833 Shaw Road Athens, AL 35611-6970State Health OfficerAlabama Dept. of Public Health RSA Tower - Administration Suite 1552 P.O. Box 303017 Montgomery, AL 36130-3017ChairmanLimestone County Commission 310 West Washington Street Athens, AL 35611}}
Chattanooga, TN 37402-2801                    Suite 23T85 Atlanta, GA 30303-8931 Brian OGrady, Site Vice President Browns Ferry Nuclear Plant                    Mr. Glenn W. Morris, Manager Tennessee Valley Authority                    Corporate Nuclear Licensing P.O. Box 2000                                    and Industry Affairs Decatur, AL 35609                            Tennessee Valley Authority 4X Blue Ridge Mr. Robert J. Beecken, Vice President        1101 Market Street Nuclear Support                              Chattanooga, TN 37402-2801 Tennessee Valley Authority 6A Lookout Place                              Mr. William D. Crouch, Manager 1101 Market Street                            Licensing and Industry Affairs Chattanooga, TN 37402-2801                    Browns Ferry Nuclear Plant Tennessee Valley Authority General Counsel                              P.O. Box 2000 Tennessee Valley Authority                    Decatur, AL 35609 ET 11A 400 West Summit Hill Drive                    Senior Resident Inspector Knoxville, TN 37902                          U.S. Nuclear Regulatory Commission Browns Ferry Nuclear Plant Mr. John C. Fornicola, Manager                10833 Shaw Road Nuclear Assurance and Licensing              Athens, AL 35611-6970 Tennessee Valley Authority 6A Lookout Place                              State Health Officer 1101 Market Street                            Alabama Dept. of Public Health Chattanooga, TN 37402-2801                    RSA Tower - Administration Suite 1552 Mr. Bruce Aukland, Plant Manager              P.O. Box 303017 Browns Ferry Nuclear Plant                    Montgomery, AL 36130-3017 Tennessee Valley Authority P.O. Box 2000                                Chairman Decatur, AL 35609                            Limestone County Commission 310 West Washington Street Mr. Masoud Bajestani, Vice President          Athens, AL 35611 Browns Ferry Unit 1 Restart Browns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL 35609}}

Latest revision as of 17:16, 23 November 2019

RAI, Extended Power Uprate Round 6 (TAC MC3812) (TS-431)
ML061730002
Person / Time
Site: Browns Ferry Tennessee Valley Authority icon.png
Issue date: 06/26/2006
From: Chernoff M
NRC/NRR/ADRO/DORL/LPLD
To: Singer K
Tennessee Valley Authority
Shared Package
ML061840297 List:
References
TAC MC3812
Download: ML061730002 (9)
v  d  e


Text

June 26, 2006 Mr. Karl W. Singer Chief Nuclear Officer and Executive Vice President Tennessee Valley Authority 6A Lookout Place 1101 Market Street Chattanooga, TN 37402-2801

SUBJECT:

BROWNS FERRY NUCLEAR PLANT, UNIT 1 REQUEST FOR ADDITIONAL INFORMATION FOR EXTENDED POWER UPRATE - ROUND 6 (TS-431)

(TAC NO. MC3812)

Dear Mr. Singer:

By letter dated June 28, 2004, as supplemented by letters dated August 23, 2004, February 23, April 25, June 6, and December 19, 2005, February 1 and 28, March 7, 9, 23, and 31, April 13, May 5, 11, 15, and 16, and June 2, 2006, the Tennessee Valley Authority (TVA, the licensee),

submitted to the U.S. Nuclear Regulatory Commission (NRC) an amendment request for Browns Ferry Nuclear Plant, Unit 1. The proposed amendment would change the operating license to increase the maximum authorized power level from 3293 to 3952 megawatts thermal.

This change represents an increase of approximately 20 percent above the current maximum authorized power level for Unit 1. The proposed amendment would also change the Unit 1 licensing bases and associated Technical Specifications to credit 3 pounds per square inch gauge (psig) for containment overpressure following a loss-of-coolant accident and increase the reactor steam dome pressure by 30 psig.

With regards to the requests for additional information (RAIs) in the APLA section, the NRC staff reviewed the response to its original RAI (SPSB-A.11 - October 3, 2005, request) involving the use of containment accident pressure in the calculation of net positive suction head available to the core spray and low pressure coolant injection pumps. The response was provided in a letter dated March 23, 2006. The NRC staff notes that the licensee requested additional time to respond, provided the response later than committed, and failed to fully answer the question. As indicated in the March 1, 2006, letter to TVA, the timeliness and quality of the responses to the NRC staffs RAIs are essential to support the timely completion of this review. Further delays of this nature will significantly challenge the NRC staffs ability to support the requested completion date.

K. Singer A response to the enclosed RAI is needed before the NRC staff can complete the review. This request was discussed with your staff on June 14, 2006, and it was agreed that a response would be provided by June 30, 2006. If you have any questions, please contact Ms. Eva Brown at (301) 415-2315.

Sincerely,

/RA/

Margaret H. Chernoff, Project Manager Plant Licensing Branch II-2 Division of Operating Reactor Licensing Office of Nuclear Reactor Regulation Docket No. 50-259

Enclosures:

1. RAI, Redacted Version
2. RAI, Proprietary Version cc w/enclosure 1: See next page

ML061730002 Enclosure 2: ML061840282 NRR-088 OFFICE LPL2-2/PM LPL2-2//PM LPL2-2//LA APLA/BC NAME EBrown MChernoff BClayton MRubin by memo DATE 06/22/06 06/22/06 06/22/06 6/08/06 OFFICE ACVB/BC SBWB/BC LPL2-2/BC NAME RDennig by memo GCranston by memo MMarshall DATE 6/15/06 6/15/06 06/26/06

SUBJECT:

BROWNS FERRY NUCLEAR PLANT, UNIT 1 REQUEST FOR ADDITIONAL INFORMATION REGARDING EXTENDED POWER UPRATE (TAC NO. MC3812)

Document Date: June 26, 2006 Distribution w/ Enclosure 1:

PUBLIC LPLII-2 R/F RidsOgcRp RidsAcrsAcnwMailCenter RidsNrrPMEBrown RidsNrrPMMChernoff RidsNrrLABClayton (hard copy)

RidsNrrDorlLpl2-2 (MMarshall)

RidsNrrDorl (CHaney/CHolden)

TAlexion GThomas MRazzaque THuang ZAbdullahi MRubin MStutzke SLaur RLobel RDennig RGoel

REQUEST FOR ADDITIONAL INFORMATION EXTENDED POWER UPRATE TENNESSEE VALLEY AUTHORITY BROWNS FERRY NUCLEAR PLANT, UNIT 1 DOCKET NO. 50-259 APLA (Previously SPSB-A)

22. It is recognized that the need to have containment accident pressure for emergency core cooling system (ECCS) net positive suction head (NPSH) should be based on a realistic analysis consistent with current probabilistic risk assessment (PRA) practices, as contrasted to a deterministic, design-basis calculation that employs excessive conservatism. Discuss which typical PRA accident sequences realistically require containment accident pressure in order to ensure that the ECCS pumps remain functional. This should include sequences currently modeled in the Browns Ferry PRA models or similar sequences, not currently modeled, that could be risk-significant if containment accident pressure is necessary and not available. This should also consider realistic fire scenarios, such as those considered in the Individual Plant Evaluation of External Events for Severe Accident Vulnerabilities study.
23. For each PRA accident sequence that realistically requires containment accident pressure, describe how much pressure is required and for what period of time.
24. For each accident sequence in #23 above, estimate the risk associated with the need for that accident pressure (i.e., the risk above the level that would exist if the ECCS pumps could function satisfactorily without the need for containment accident pressure).

While a realistic core damage frequency and large early release frequency are the desired metrics for this risk estimate, the licensee may utilize sensitivity studies, bounding analyses or qualitative arguments, where appropriate, provided all conclusions are substantially supported by the discussion.

ACVB

37. The term design flow rate is used to describe the core spray pump flow rate and the residual heat removal (RHR) pump flow rate assumed in the NPSH analyses. Define precisely the design flow rate in terms of the pump and system curves.
38. The current Updated Final Safety Analyses Report Table 14.6-4 shows a higher drywell volume for Case 3, the limiting case for drywell pressure and temperature, than for Cases 1, 2 and 4. Discuss why there is a larger drywell volume assumed for this case, and whether the same assumption is made for the extended power uprate (EPU).

Enclosure 1

39. Provide the calculations used to determine the containment conditions (drywell, wetwell and suppression pool) for the loss-of-coolant accident (LOCA), Anticipated Transient Without Scram (ATWS), Station Blackout (SBO) and Appendix R Fire events.
40. Describe how the proposed crediting of containment accident pressure in determining available NPSH compares with the positions of Section 2.1.1 of Regulatory Guide 1.82, Water Sources for Long-Term Recirculation Cooling Following a Loss-of-Coolant Accident, Revision 3, dated November 2003.
41. The units have drywell coolers which operate during normal plant operation. Address whether the drywell coolers are conservatively assumed to continue operation following accident initiation for the LOCA, ATWS, SBO and Appendix R Fire events.
42. Section 4.2.5 of the General Electric (GE) Analysis Report, PUSAR, states that the NPSH margins were calculated based on conservatively assuming RHR maximum flow rates and containment spray design flow rates in the short term analyses and RHR and containment spray design flow rates in the long term analyses. Describe the design provisions or operator actions that limit the pump flows to these values.
43. Describe how the make-up of nitrogen to the drywell and wetwell atmospheres could serve as a verification of containment integrity during normal operation.
44. Describe the measures taken to ensure that all containment penetrations are properly isolated prior to and during operation.
45. Describe any other actions/programs which contribute to assurance that the containment is isolated.
46. Address whether the RHR and core spray pumps can be throttled to increase available NPSH and decrease required NPSH. Discuss what, if any, guidance is provided in the emergency operating instructions (EOIs) or abnormal operating instructions regarding throttling these pumps to preserve NPSH margin during accident conditions.
47. Discuss whether any of the units have features to automatically terminate drywell or wetwell spray. Describe the conditions under which the operator would terminate drywell and/or wetwell spray under accident conditions in accordance with the EOIs. Address those measures put in place to prevent an operator from reducing wetwell pressure below that needed for adequate available NPSH.
48. In a letter dated September 4, 1998, Tennessee Valley Authority (TVA) requested the use of containment overpressure for Units 2 and 3. The letter stated that the short term NPSH analysis assumes a double-ended recirculation pump discharge line break while the long term analysis assumes a double-ended suction line break. Address whether this is the case for the EPU analyses. Any difference in assumptions should be explained.
49. Address the criteria in the EOIs for initiating drywell and wetwell sprays. Discuss how the timing of the actions resulting from these criteria compares with the 10-minute assumption in the accident analyses for initiating suppression pool cooling. Discuss

how the times for initiating drywell and wetwell sprays using the EOI criteria compare with times obtained in simulator training.

50. Using Figure ACVB 7-1 of the March 7, 2006, letter, explain the physical occurrences which result in (1) the reduction in the steep slope at approximately 2 seconds; (2) the small sudden increase at approximately 8 seconds; and (3) the following steep decrease. Discuss at what time the torus-to-drywell vacuum breakers to actuate.
51. Page E1-3 of the letter dated September 4, 1998, indicates that containment pressure is only needed in the short term for the RHR pump at the maximum flow conditions and that other pathways are available and functional without containment overpressure being relied upon. Discuss whether this is still true with the EPU NPSH analyses. If still true, elaborate on this statement.
52. In the safety evaluation dated September 3, 1999, on the credit for containment accident pressure in determining available NPSH, TVA discussed a 10-year frequency for suppression pool cleaning. Discuss whether suppression pool cleaning is still done on a 10-year frequency.
53. For Figures ACVB 7-3 and ACVB 7-4 from the March 7, 2006, letter, explain the physical occurrences that produce the significant changes in the shape of the curves as a function of time.
54. Table ACVB 22-1, in response to ACVB 22 from the March 7, 2006, letter, states that the licensing basis calculation of NPSH assumes no heat sinks while the realistic calculation does. Address whether the reverse should be true to ensure conservatism.

Also, see TVA reply to ACVB 27 and Table SPSB-A.11-2, which states that not crediting heat sinks is conservative.

55. Table ACVB 22-1, in response to ACVB 22 from the March 7, 2006, letter, gives values of wetwell airspace and suppression pool volume that sum to different values for the realistic and the licensing basis values. Discuss whether the sums should be the same and equal to the total volume of the wetwell.
56. The response to RAI ACVB 18 provided curves of pressures and temperatures for the events crediting containment accident pressure for available NPSH. The curves for ATWS and Appendix R Fire should be extended to provide the total time that containment accident pressure is needed for available NPSH.
57. The response to RAI SPSB-A.11 provided Table SPSB-A.11-2, which contains calculations of suppression pool temperature with various assumptions. The cases are identified as either GE or TVA. Describe the analytical methods used for the TVA calculations and the steps taken to ensure a meaningful comparison with SHEX.
58. In Table 6 of Calculation MD-Q0999-970046, Rev. 8, provided in the March 23, 2006, response, the NPSH required (NPSHR) of the RHR pumps varies even when the pumps have the same flow rate. The Core Spray pumps, all with the same flow rate, also have the same value of NPSHR. Explain why the NPSHR varies even when the pumps have the same flow rate.

SBWB

26. Provide the following bundle operating conditions with exposure:

! maximum bundle power,

! maximum bundle power/flow ratio,

! exit void fraction of maximum power bundle,

! maximum channel exit void fraction,

! peak linear heat generation rate, and

! peak end-of-cycle (EOC) nodal exposure.

Provide the maximum bundle operating conditions relative to EPU plants. Include the plant-specific data in the plots containing the high density and EPU plants maximum bundle operating conditions. Since there are no recent Unit 1 pre-EPU data and the units are similar, include the Units 2 and 3 pre-EPU data in the plots.

27. Provide quarter core map (assuming core symmetry) showing the bundle maximum linear heat generation rate and the minimum critical power ratio for beginning-of-cycle, middle-of-cycle and EOC. Similarly, show the associated bundle powers and exposures.
28. Figure 2-4 of licensing topical report, NEDC-33173P, Applicability of GE Methods to Expanded Operating Domain, shows the cold critical eigenvalues of reference plants.

Figure 2-5 of NEDC -33173P shows the measured and predicted eigenvalues for Reference Plants. Provide the pre-EPU Units 2 and 3 cold critical eigenvalues measured and predicted differences for previous cycles based on the GE methods.

Provide evaluation of any available local critical and startup shutdown calculations.

29. Provide a discussion addressing whether the traversing-in-core probes (TIPs) are gamma or thermal TIPs.
30. Based on the EPU Cycle core design, establish whether Unit 1 will experience bypass voiding [ ]. Specify the peak bypass calculated for any four bundle bypass zone at EPU conditions. Discuss why the bypass voiding is [

]. Also calculate the bypass voiding for the second cycle where the large batches of fresh fuel loaded in Unit 1 will be at the most reactive state.

31. Based on the first/second EPU Cycle core design, determine the bypass voiding at the different local power range monitor elevations after a recirculation pump trip. Perform the calculations on limiting conditions (initial condition, axial power distribution and in-channel voids) and provide the results.

Mr. Karl W. Singer BROWNS FERRY NUCLEAR PLANT Tennessee Valley Authority cc:

Mr. Ashok S. Bhatnagar, Senior Vice President Mr. Robert G. Jones, General Manager Nuclear Operations Browns Ferry Site Operations Tennessee Valley Authority Browns Ferry Nuclear Plant 6A Lookout Place Tennessee Valley Authority 1101 Market Street P.O. Box 2000 Chattanooga, TN 37402-2801 Decatur, AL 35609 Mr. Larry S. Bryant, Vice President Mr. Larry S. Mellen Nuclear Engineering & Technical Services Browns Ferry Unit 1 Project Engineer Tennessee Valley Authority Division of Reactor Projects, Branch 6 6A Lookout Place U.S. Nuclear Regulatory Commission 1101 Market Street 61 Forsyth Street, SW.

Chattanooga, TN 37402-2801 Suite 23T85 Atlanta, GA 30303-8931 Brian OGrady, Site Vice President Browns Ferry Nuclear Plant Mr. Glenn W. Morris, Manager Tennessee Valley Authority Corporate Nuclear Licensing P.O. Box 2000 and Industry Affairs Decatur, AL 35609 Tennessee Valley Authority 4X Blue Ridge Mr. Robert J. Beecken, Vice President 1101 Market Street Nuclear Support Chattanooga, TN 37402-2801 Tennessee Valley Authority 6A Lookout Place Mr. William D. Crouch, Manager 1101 Market Street Licensing and Industry Affairs Chattanooga, TN 37402-2801 Browns Ferry Nuclear Plant Tennessee Valley Authority General Counsel P.O. Box 2000 Tennessee Valley Authority Decatur, AL 35609 ET 11A 400 West Summit Hill Drive Senior Resident Inspector Knoxville, TN 37902 U.S. Nuclear Regulatory Commission Browns Ferry Nuclear Plant Mr. John C. Fornicola, Manager 10833 Shaw Road Nuclear Assurance and Licensing Athens, AL 35611-6970 Tennessee Valley Authority 6A Lookout Place State Health Officer 1101 Market Street Alabama Dept. of Public Health Chattanooga, TN 37402-2801 RSA Tower - Administration Suite 1552 Mr. Bruce Aukland, Plant Manager P.O. Box 303017 Browns Ferry Nuclear Plant Montgomery, AL 36130-3017 Tennessee Valley Authority P.O. Box 2000 Chairman Decatur, AL 35609 Limestone County Commission 310 West Washington Street Mr. Masoud Bajestani, Vice President Athens, AL 35611 Browns Ferry Unit 1 Restart Browns Ferry Nuclear Plant Tennessee Valley Authority P.O. Box 2000 Decatur, AL 35609

Retrieved from "https://kanterella.com/w/index.php?title=ML061730002&oldid=2190143"