2CAN070701, Emergency Core Cooling System Performance Analysis.
ML072200528 | |
Person / Time | |
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Site: | Arkansas Nuclear |
Issue date: | 07/31/2007 |
From: | Mitchell T Entergy Operations |
To: | Document Control Desk, Office of Nuclear Reactor Regulation |
References | |
2CAN070701, 2CAN070702 | |
Download: ML072200528 (42) | |
Text
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418 S.R 333 Ruse!1v0e. AR 72802 T . 7-8I . 97 z Timothy G. Mitchell Vice Presidenl, Operarvws Arkans. s Nucleir One 2CAN070702 July 31, 2007 U.S. Nuclear Regulatory Commission Attn: Document Control Desk Washington, DC 20555
SUBJECT:
Emergency Core Cooling System Performance Analysis Arkansas Nuclear One, Unit 2 Docket No. 50-368 License No. NPF-6
REFERENCES:
Entergy letter to the NRC "License Amendment Request to Revise Technical Specification 6.6.5, Core Operating Limits Report" dated July 31, 2007 (2CAN070701)
Dear Sir or Madam:
Pursuant to 10 CFR 50.46, Acceptance criteriafor emergency core cooling systems for light water nuclearpower reactors,and the draft Nuclear Regulatory Commission (NRC) Safety Evaluation for Westinghouse topical report WCAP-16500, CE [Combustion Engineering] 16 x 16 Next Generation Fuel Core Reference Report, Entergy Operations, Inc. (Entergy) hereby requests an NRC review of the Arkansas Nuclear One, Unit 2 (ANO-2) revised Emergency Core Cooling System (ECCS) Performance Analysis that supports the implementation of CE 16 x 16 Next Generation Fuel (NGF) described in WCAP-16500. A license amendment request was submitted (Reference 1) to address the ANO-2 Technical Specification changes for NGF.
Entergy requests approval of the revised analysis by February 14, 2008 in order to support the spring 2008 refueling outage. Once approved and following startup from the spring 2008 refueling outage, the analysis shall become the analysis of record. Although this request is neither exigent nor emergency, your prompt review is requested.
If you have any questions or require additional information, please contact David Bice at 479-858-5338.
2CAN070702 Page 2 of 2 I declare under penalty of perjury that the foregoing is true and correct. Executed on July 31, 2007.
Sincerely, TGM/DM Attachments:
- 1. ECCS Performance Analysis cc: Dr. Bruce S. Mallett Regional Administrator U. S. Nuclear Regulatory Commission Region IV 611 Ryan Plaza Drive, Suite 400 Arlington, TX 76011-8064 NRC Senior Resident Inspector Arkansas Nuclear One P. 0. Box 310 London, AR 72847 U. S. Nuclear Regulatory Commission Attn: Mr. Alan B. Wang MS 0-7 D1 Washington, DC 20555-0001 Mr. Bernard R. Bevill Director Division of Radiation Control and Emergency Management Arkansas Department of Health & Human Services P.O. Box 1437 Slot H-30 Little Rock, AR 72203-1437
Attachment 1 2CAN070702 ECCS Performance Analysis to 2CAN070702 Page 1 of 39 ECCS Performance Analysis 1.0 Introduction This report summarizes the Emergency Core Cooling System (ECCS) performance analyses performed for the full core implementation of Combustion Engineering (CE) 16 x 16 Next Generation Fuel (NGF) assemblies into Arkansas Nuclear One, Unit 2 (ANO-2). CE 16 x 16 NGF as defined in WCAP-1 6500-P (Reference 1-15) will be implemented at ANO-2 beginning in Cycle 20 commencing after the spring 2008 refueling outage.
Limitations and Conditions number 7 of the draft Safety Evaluation (SE) for WCAP-16500-P, which has been provided to Westinghouse by the NRC, states: "Implementationof CE 16 x 16 NGF assemblies necessitate re-analysisof the plant-specific LOCA [Loss of Coolant Accident]
analyses. Licensees are requiredto submit a license amendment containing the revised LOCA analyses for NRC review. Upon approval, the revised LOCA analyses constitute the analysis-of-record and baseline for which future changes will be measured againstin accordance with 10 CFR 50.46(a)(3)." Entergy committed to provide the results of these re-analyses as part of the ANO-2 license amendment request submitted July 31, 2007 (2CAN070701).
The ECCS performance analyses were performed to demonstrate conformance to the acceptance criteria for ECCS for light water nuclear power reactors, 10 CFR 50.46 (Reference 1-1). Analyses were performed for a spectrum of Large Break (LB) and Small Break (SB) LOCAs.
The fuel design changes for NGF which are important for ECCS performance analyses are compared to standard fuel assembly characteristics as follows:
" The NGF design contains Optimized ZIRLOTM clad fuel rods. In contrast, the standard fuel assemblies are comprised of ZIRLOTM clad fuel rods.
- The NGF rod cladding and U0 2 fuel pellet radial dimensions are reduced compared to the standard fuel rod design. This produces an increase in the fuel rod pitch-to-diameter ratio compared to the standard 16 x 16 fuel assembly design and an increase in the core cross-sectional area for coolant flow. Also, the NGF rod cladding diameter-to-thickness ratio is increased relative to the standard 16 x 16 fuel rod design. This ratio is used in calculating the engineering hoop stress across the fuel rod cladding for analyzing any mechanical deformation of the cladding.
- The NGF assembly hydraulic resistance is increased relative to the standard fuel assembly due to the addition of mixing grids. As a result, a transition mixed core assessment for NGF was performed in order to address the impact of co-resident hydraulically dissimilar fuel assemblies (i.e., NGF and standard fuel assemblies) on ECCS performance.
to 2CAN070702 Page 2 of 39 2.0 Objective The objective of the ECCS performance analysis is to demonstrate conformance to the ECCS acceptance criteria of 10 CFR 50.46(b):
Criterion 1: Peak Cladding Temperature: The calculated maximum fuel element cladding temperature shall not exceed 2200 OF.
Criterion 2: Maximum Cladding Oxidation: The calculated total oxidation of the cladding shall nowhere exceed 0.17 times the total cladding thickness before oxidation.
Criterion 3: Maximum Hydrogen Generation: The calculated total amount of hydrogen generated from the chemical reaction of the cladding with water or steam shall not exceed 0.01 times the hypothetical amount that would be generated if all of the metal in the cladding cylinders surrounding the fuel, excluding the cladding surrounding the plenum volume, were to react.
Criterion 4: Coolable Geometry: Calculated changes in core geometry shall be such that the core remains amenable to cooling.
Criterion 5: Long-Term Cooling: After any calculated successful initial operation of the ECCS, the calculated core temperature shall be maintained at an acceptably low value and decay heat shall be removed for the extended period of time required by the long-lived radioactivity remaining in the core.
3.0 Regulatory Basis As required by 10 CFR 50.46(a)(1)(i), the ECCS performance analysis must conform to the ECCS acceptance criteria identified in Section 2.0. Additionally, the ECCS performance must be calculated in accordance with an acceptable evaluation model and must be calculated for a number of postulated LOCAs of different sizes, locations, and other properties sufficient to provide assurance that the most severe postulated LOCAs are calculated. The evaluation model may either be a realistic evaluation model as described in 10 CFR 50.46(a)(1)(i) or must conform to the required and acceptable features of Appendix K ECCS Evaluation Models (Reference 1-2). The evaluation models used to perform the ECCS performance analyses documented herein are Appendix K evaluation models.
As previously stated Optimized ZIRLOTM fuel rod cladding material will be used in the design of NGF assemblies. The acceptance criteria and requirements of 10 CFR 50.46 and 10 CFR Part 50, Appendix K currently are limited in applicability to the use of fuel rods clad with Zircaloy or ZIRLOTM. 10 CFR 50.46 and 10 CFR Part 50, Appendix K cannot apply to the proposed use of NGF assemblies since Optimized ZIRLOTM has a slightly different composition than Zircaloy or ZIRLOTM. Therefore an exemption request has been submitted (Reference 1-20) to apply these regulations to Optimized ZIRLOTM.
4.0 Method(s) of Analysis WCAP-16500 (Reference 1-15) is the Core Reference Report for CE 16 x 16 Next Generation Fuel, pending NRC approval. Section 5.2 of Reference 1-15 documents the ECCS performance methods suitable for use to analyze the implementation of NGF. The methods used for the ECCS performance analyses of ANO-2 are summarized in the following sections.
to 2CAN070702 Page 3 of 39 The CE 16 x 16 NGF design utilizes Optimized ZIRLO TM , an advanced cladding alloy. The implementation of Optimized ZIRLOTM in CE plants is documented in Reference 1-16 and approved by the NRC in Reference 1-17. As required by the SER limitations in Reference 1-17, the ECCS performance analysis computer codes have been updated to include the Optimized ZIRLOTM cladding property changes detailed in the topical report.
The Westinghouse ECCS Performance Appendix K Evaluation Model for CE plants is the 1999 Evaluation Model (1999 EM) for LBLOCA (Reference 1-3). The 1999 EM for LBLOCA is augmented by CENPD-404-P-A for analysis of ZIRLOTM cladding (Reference 1-18) and by Addendum 1 to CENPD-404-P-A for analysis of Optimized ZIRLO M cladding (Reference 1-16).
Also, the 1999 EM is supplemented by WCAP-1 6072-P-A, (Reference 1-19) for implementation of ZrB 2 IFBA fuel assembly designs.
The 1999 EM for LBLOCA includes the following computer codes. The CEFLASH-4A computer code (Reference 1-5) is used to perform the blowdown hydraulic analysis of the reactor coolant system (RCS) and the COMPERC-I1 computer code (Reference 1-6) is used to perform the RCS refill/reflood hydraulic analysis and to calculate the containment minimum pressure. It is also used in conjunction with the methodology described in Reference 1-7 to calculate the FLECHT-based reflood heat transfer coefficients used in the hot rod heatup analysis. The HCROSS (Reference 1-8) and PARCH (Reference 1-9) computer codes are used to calculate steam cooling heat transfer coefficients. The hot rod heatup analysis, which calculates the peak cladding temperature and maximum cladding oxidation, is performed with the STRIKIN-Il computer code (Reference 1-10). Core-wide cladding oxidation is calculated using the COMZIRC computer code (Appendix C of Supplement 1 of Reference 1-6). The initial steady state fuel rod conditions used in the analysis are determined using the FATES3B computer code (Reference 1-11). Computer code process improvements have been made to facilitate the implementation of NGF assemblies in the LBLOCA analysis. These improvements will be reported to NRC in the Westinghouse generic yearly letter of 2007 in compliance with 10 CFR 50.46(a)(3)(ii) (Reference 1-1).
The Appendix K steam cooling heat transfer component model for less than 1 in/sec core reflood in the 1999 EM has been modified to include spacer grid heat transfer effects. The details of this improvement to the 1999 EM are documented in Reference 1-4. For ANO-2, the LBLOCA analysis does not credit the use of the modified model including spacer grid heat transfer effects.
In performing the LBLOCA calculations, conservative assumptions are made concerning the availability of safety injection flow. It is assumed that offsite power is lost and all pumps must await diesel startup before they can begin to deliver flow. (It is assumed, however, that offsite power is available for the Containment Spray System and containment fan coolers). Also, it is assumed that all safety injection flow delivered to the broken cold leg is lost directly to the containment.
The limiting initial fuel rod conditions used in the LBLOCA analysis (i.e., the conditions that result in the highest calculated peak cladding temperature) were determined by performing burnup dependent calculations with the 1999 EM using initial fuel rod conditions calculated by FATES3B. The LBLOCA analysis included both UO2 and ZrB 2 burnable absorber fuel rods in both the NGF and standard fuel rod designs.
to 2CAN070702 Page 4 of 39 A study was performed to determine the most limiting single failure of ECCS equipment. The study analyzed no failure, failure of an emergency diesel generator, failure of a high pressure safety injection (HPSI) pump, and a failure of a low pressure safety injection (LPSI) pump consistent with approved topical reports. Maximum safety injection pump flow rates were used in the no failure case; minimum safety injection pump flow rates were used in the emergency diesel generator, HPSI or LPSI pump failure cases. The pumps were actuated on a safety injection actuation signal (SIAS) generated by low pressurizer pressure with appropriate startup delay. Minimum refueling water storage pool temperature was used in all four cases as a result of a sensitivity study of the refueling water storage pool water temperature. The study also investigated the impact of variation in safety injection tank (SIT) pressure, water temperature and water volume on peak cladding temperature and peak local cladding oxidation.
A spectrum of guillotine breaks in the reactor coolant pump discharge leg was analyzed. As described in Section 3.4 of Reference 1-3 Supplement 4-P-A, the discharge leg is the most limiting break location and a guillotine break is more limiting than a slot break. In particular, the 0.3, 0.4, 0.6, 0.8, and 1.0 Double-Ended Guillotine breaks in the reactor coolant Pump Discharge leg (DEG/PD) were analyzed for ANO-2.
Since the CE 16 x 16 NGF assembly has a higher pressure drop, a transition mixed core assessment was performed to address the effect of flow redistribution on the CE 16 x 16 NGF assemblies during the transition cycles consisting of co-resident hydraulically dissimilar fuel assemblies.
The small break LOCA ECCS performance analysis used the Supplement 2 version (referred to as the S2M or Supplement 2 Model) of the Westinghouse small break LOCA evaluation model for Combustion Engineering PWRs (Reference 1-12). The S2M for SBLOCA is augmented by CENPD-404-P-A for analysis of ZIRLOTM cladding (Reference 1-18), and by Addendum 1 to CENPD-404-P-A for analysis of Optimized ZIRLOTM cladding (Reference 1-16). Also, the S2M is supplemented by WCAP-16072-P-A for implementation of ZrB 2 IFBA fuel assembly designs (Reference 1-19).
The S2M for SBLOCA uses the following computer codes: The CEFLASH-4AS computer program (Reference 1-13) is used to perform the hydraulic analysis of the RCS until the time the SITs begin to inject. After injection from the SITs begins, the COMPERC-I1 computer program (Reference 1-6) is used to perform the hydraulic analysis. COMPERC-II is only used in the SBLOCA evaluation model for larger break sizes that exhibit prolonged periods of SIT flow and significant core voiding. The hot rod cladding temperature and maximum cladding oxidation are calculated by the STRIKIN-Il computer program (Reference 1-10) during the initial period of forced convection heat transfer and by the PARCH computer program (Reference 1-9) during the subsequent period of pool boiling heat transfer. Core-wide cladding oxidation is conservatively represented as the rod-average cladding oxidation of the hot rod. The initial steady state fuel rod conditions used in the analysis are determined using the FATES3B computer program (Reference 1-11).
The small break LOCA analysis was performed for the fuel rod conditions that result in the maximum initial stored energy in the fuel. The calculations included the analysis of both U0 2 and ZrB 2 burnable absorber fuel rods in both the NGF and standard fuel rod designs.
to 2CAN070702 Page 5 of 39 For ANO-2, the analysis was performed using the failure of an emergency diesel generator as the most limiting single failure of the ECCS. The emergency diesel generator failure causes the loss of a HPSI pump and a LPSI pump, and results in a minimum of safety injection water being available to cool the core. The LPSI pumps are not explicitly credited in the SBLOCA analysis since the RCS pressure never decreases below the LPSI pump shutoff head during the portion of the transient that is analyzed.
A spectrum of three break sizes in the reactor coolant pump discharge (PD) leg was analyzed to bracket the limiting break size, which for ANO-2 was the 0.04 ft 2/PD break. The reactor coolant pump discharge leg is the limiting break location because it maximizes the amount of spillage from the ECCS. The limiting SBLOCA is the largest small break for which the hot rod cladding heatup transient is terminated solely by injection from a HPSI pump.
No SBLOCA mixed-core analysis is necessary during transition core cycles due to the negligible effect of variations in core hydraulic losses on SBLOCA analysis results.
4.3 Post-LOCA Long Term Cooling As documented in Reference 1-15, the analyses performed with the Westinghouse post-LOCA long-term cooling evaluation model for CE plants (CENPD-254-P-A, Reference 1-14) are not sensitive to the fuel assembly changes being introduced for the CE 16 x 16 NGF design. As a result, no plant-specific post-LOCA long-term cooling analyses were required to support the introduction of the CE 16 x 16 NGF assembly.
5.0 Results for ANO-2 5.1 Plant Design Data Important core, RCS, ECCS, and containment design data used in the LBLOCA analysis are listed in Tables 5-1 and 5-2. The listed fuel rod conditions are for rod average burnup of the hot rod that produced the highest calculated peak cladding temperature. In particular, the results of this ECCS Performance analysis support a peak linear heat generation rate of 13.7 kW/ft. Plant design data for the containment (e.g., data for the containment initial conditions, containment volume, containment heat removal systems, and containment passive heat sinks) were selected to minimize the transient containment pressure. The core inlet temperature was the minimum RCS cold leg temperature at the full power including uncertainty.
Important core, RCS, and ECCS design data used in the SBLOCA analysis are listed in Tables 5-7 and 5-8. The listed fuel rod conditions are for the hot rod burnup that produces the maximum initial stored energy.
5.2 Large Break LOCA Table 5-3 lists the peak cladding temperature and oxidation percentages for the spectrum of large break LOCAs. Times of interest are listed in Table 5-4. The variables listed in Tables 5-5 are plotted as functions of time in Figures 5-1 through 5-8 for the 1.0 DEG/PD break. The variables listed in Table 5-5 are plotted as functions of time for the 0.8 DEG/PD break, in Figures 5-9 through 5-16. The variables listed in Table 5-5 are plotted for the 0.6 DEG/PD in Figures 5-17 through 5-24. The variables listed in Tables 5-5 and 5-6 are plotted for the to 2CAN070702 Page 6 of 39 0.4 DEG/PD, the limiting large break LOCA, in Figures 5-25 through 5-46. The variables listed in Table 5-5 are plotted for the 0.3 DEG/PD in Figures 5-47 through 5-54. The results for the full core implementation of NGF demonstrate conformance to the ECCS acceptance criteria as summarized below. The results for the current analysis-of-record (AOR) for ZrB 2 IFBA fuel are provided for comparison.
Current NGF AOR Parameter Criterion Results Results Peak Cladding Temperature < 2200°F 2144 OF 2168 OF Maximum Cladding Oxidation < 17% 14.5% 12.93%
Maximum Core-Wide Oxidation < 1% < 1% < 0.99%
Coolable Geometry Yes Yes Yes The results are applicable to ANO-2 for a rated core power of 3026 MWt (3087 MWt including a 2% power measurement uncertainty) for the implementation of CE 16 x 16 NGF. These results support a peak linear heat generation rate (PLHGR) of 13.7 kW/ft.
5.3 Small Break LOCA Table 5-9 lists the peak cladding temperature and oxidation percentages for the spectrum of small break LOCAs. Times of interest are listed in Table 5-10. The variables listed in Table 5-11 are plotted as a function of time for each break in Figures 5-55 through 5-78. The results for the 0.04 ft2/PD break, the limiting small break LOCA, demonstrate conformance to the ECCS acceptance criteria as summarized below.
Current NGF AOR Parameter Criterion Results Results Peak Cladding Temperature < 2200°F 2111 OF 2137 OF Maximum Cladding Oxidation _ 17% 16.77% 16.5%
Maximum Core-Wide Oxidation _ 1% < 0.88% < 0.85%
Coolable Geometry Yes Yes Yes The results are applicable to ANO-2 for a PLHGR of 13.7 kW/ft and a core power of 3087 MWt (including a 2% power measurement uncertainty) for the implementation of CE 16 x 16 NGF.
5.4 Post-LOCA Long Term Cooling There is no significant impact of NGF implementation on the post-LOCA LTC analysis results.
The results of the AOR for post-LOCA long term cooling (LTC) continue to apply.
to 2CAN070702 Page 7 of 39 5.5 Transition Mixed Core A transition mixed core assessment was performed for NGF in order to address the impact of co-resident hydraulically dissimilar fuel assemblies (i.e., NGF and standard fuel assemblies) on ECCS performance. The NGF core hydraulic resistance is greater than the standard fuel assembly due to the addition of mixing grids. Therefore, adjacent NGF and standard assemblies will experience a net redistribution of flow from the higher resistant NGF assembly to the lower resistant standard assembly.
This flow redistribution in the NGF mixed transition cores produces a slight penalty on the NGF assembly ECCS performance during the LBLOCA. However, a smaller cross-sectional core area for coolant flow (relative to a full core of NGF assemblies) is credited in the transition core assessment to improve the core hydraulics behavior during the blowdown period. Also, the smaller cross-sectional core area increases the core reflooding rates during the reflood period relative to the bounding full core NGF analysis. The net impact on ECCS performance is a slight reduction in the peak cladding temperature, peak cladding oxidation, and core-wide cladding oxidation percentages.
For ANO-2, one mixed core configuration was examined to address core loading differences that are expected in the coming cycles of operation assuming a half core loading pattern for NGF assemblies. The transition mixed core ECCS performance assessment determined that the results were bounded by the results of the full core NGF implementation analysis.
6.0 Conclusions An ECCS performance analysis was completed for ANO-2 at the core power of 3087 MWt (including a 2% power measurement uncertainty) for the full core implementation of CE 16 x 16 NGF. The calculations included the analysis of both U0 2 and ZrB 2 IFBA rods in both the NGF and standard fuel rod designs, including a mixed core assessment. The analysis included consideration of large break LOCA, small break LOCA, and post-LOCA long term cooling. The limiting break size, i.e., the break size that resulted in the highest peak cladding temperature, was determined to be the 0.4 DEG/PD break.
The results of the analysis demonstrate conformance to the ECCS acceptance criteria at a PLHGR of 13.7 kW/ft as follows.
Criterion 1: Peak Cladding Temperature: The calculated maximum fuel element cladding temperature shall not exceed 2200 OF.
Result: The ECCS performance analysis calculated a peak cladding temperature of 2144 OF for the 0.4 DEG/PD break.
Criterion 2: Maximum Cladding Oxidation: The calculated total oxidation of the cladding shall nowhere exceed 0.17 times the total cladding thickness before oxidation.
Result: The ECCS performance analysis calculated a maximum cladding oxidation of 0.168 times the total cladding thickness before oxidation for the 0.04 ft2/PD break.
to 2CAN070702 Page 8 of 39 Criterion 3: Maximum Hydrogen Generation: The calculated total amount of hydrogen generated from the chemical reaction of the cladding with water or steam shall not exceed 0.01 times the hypothetical amount that would be generated if all of the metal in the cladding cylinders surrounding the fuel, excluding the cladding surrounding the plenum volume, were to react.
Result: The ECCS performance analysis calculated a maximum hydrogen generation of less than 0.01 times the hypothetical amount for the break sizes analyzed.
Criterion 4: Coolable Geometry: Calculated changes in core geometry shall be such that the core remains amenable to cooling.
Result: The cladding swelling and rupture models used in the ECCS performance analysis account for the effects of changes in core geometry that would occur if cladding rupture is calculated to occur. Adequate core cooling was demonstrated for the changes in core geometry that were calculated to occur as a result of cladding rupture. In addition, the transient analysis was performed to a time when cladding temperatures were decreasing and the RCS was depressurized, thereby precluding any further cladding deformation.
Therefore, a coolable geometry was demonstrated.
Criterion 5: Long-Term Cooling: After any calculated successful initial operation of the ECCS, the calculated core temperature shall be maintained at an acceptably low value and decay heat shall be removed for the extended period of time required by the long-lived radioactivity remaining in the core.
Result: The large break and small break LOCA ECCS performance analyses demonstrated that the ANO-2 ECCS successfully maintains the fuel cladding temperature at an acceptably low value in the short term. Subsequently, for the extended period of time required by the long-lived radioactivity remaining in the core, the ECCS continues to supply sufficient cooling water from the refueling water tank and then from the sump to remove decay heat and maintain the core temperature at an acceptably low value. In addition, at the appropriate time, the operator realigns a HPSI pump for simultaneous hot and cold leg injection in order to maintain the core boric acid concentration below the solubility limit.
Attachment I to 2CAN070702 Page 9 of 39 Table 5-1 Large Break LOCA ECCS Performance Analysis Core and Plant Design Data Quantity Value Units Reactor power level (102 %of rated power) 3087 MWt Peak linear heat generation rate (PLHGR) of the hot rod 13.7 kW/ft PLHGR of the average rod in assembly with hot rod 12.91 kW/ft Gap conductance at the PLHGR 2474 BTU/hr-ft 2-OF Fuel centerline temperature at the PLHGR 3172.9 OF Fuel average temperature at the PLHGR 1967.2 OF Hot rod gas pressure 401.79 psia Moderator temperature coefficient at initial density +0.5 x 10.4 ApPF RCS flow rate 118.00 x 106 Ibm/hr Core flow rate 113.86 x 106 Ibm/hr RCS pressure 2200 psia Cold leg temperature 540.0 OF Hot leg temperature 607.1 OF Plugged tubes per steam generator 1064 Low pressurizer pressure SIAS setpoint 1400 psia Safety injection tank pressure (min/max) 550/650 psia Safety injection tank water volume (min/max) 1000/1600 ft3 Safety injection tank water temperature (min/max) 40/140 OF Maximum SI pump flow rate (LPSI + HPSI at 25 psia) 9131.38 gpm LPSI pump flow rate (min, 1 pump at 40 psia) 3544.20 gpm HPSI pump flow rate (min, 1 pump at 40 psia) 767.28 gpm Containment pressure (min) 13.2 psia Containment temperature (min) 60 OF Containment humidity (max) 100 Containment net free volume 1.82 x 106 ft3 Containment spray pump flow rate (max) 2515.5 gpm/pump Refueling water tank temperature (min/max) 38/120 OF Containment passive heat sinks Table 5-2
- These quantities correspond to the rod average burnup of the hot rod that yields the highest peak cladding temperature.
to 2CAN070702 Page 10 of 39 Table 5-2 Large Break LOCA ECCS Performance Analysis Containment Passive Heat Sink Data Wall Thickness Surface Area No. Description Material (ft) (ft2) 1 Containment' Walls and Dome Type B Coating 0.0004 62,050 Steel 0.0225 Concrete 3.56 2 Containment1 Walls Type A Coating 0.0004 20,000 Steel 0.0224 Concrete 3.78 3 Base Slab Type C Coating 0.0107 10,000 Concrete 1.5 Steel 0.0208 Concrete 9.0 4 Refueling Canal 2 Stainless Steel 0.0217 10,000 Concrete 2.02 5 Sheet Metal1' 2 and Pipes Galvanized 0.00008 110,500 Coating Steel 0.0049 6 Concrete Walls 1' 2 and Floor Type C Coating 0.0063 28,000 Slabs Concrete 1.38 7 Structural Steel" 2 Type A Coating 0.0004 119,300 Steel 0.0349 8 Crane Girders' 2 Type D Coating 0.0005 67,000 Steel 0.0098 9 Concrete' 2 Concrete 2.70 68,000 10 Stainless Steel" 2 Stainless Steel 0.0179 7,000 1 Thickness is effective thickness as a result of combining similar thickness walls.
2 One side of wall is exposed to containment atmosphere, one side is insulated.
to 2CAN070702 Page 11 of 39 Table 5-3 Large Break LOCA ECCS Performance Analysis Results Peak Cladding Maximum Cladding Maximum Core-Wide Break Size Temperature Oxidation Cladding Oxidation (OF) (%) (%)
Spectrum Results for Peak Cladding Temperature**
1.0 DEG/PD* 2034 7.3 < 1 0.8 DEG/PD* 2085 9.2 < 1 0.6 DEG/PD* 2107 9.2 < 1 0.4 DEG/PD* 2144 12.6 < 1 0.3 DEG/PD* 1987 5.9 < 1 Case Results for Maximum Local Cladding Oxidation***
0.4 DEG/PD* 2124 14.5 < 1
- DEG/PD: Double Ended Guillotine Break at Pump Discharge Leg
End of Start of SITs SI Pumps Hot Rod Break Size [ SITs On J Blowdown Reflood Empty on Rupture Spectrum Results for Peak Cladding Temperature**
1.0 DEG/PD* 9.4 16.6 27.6 78.8 46.7 60.1
'0.8 DEG/PD* 10.3 17.5 28.4 79.7 46.8 52.8 0.6 DEG/PD* 12.0 19.2 30.1 81.4 46.8 47.8 0.4 DEG/PD* 15.1 22.8 33.5 85.1 47.1 76.7 0.3 DEG/PD* 18.6 27.0 37.6 89.4 47.4 127.7 Case Results for Maximum Local Cladding Oxidation***
0.4 DEG/PD* 15.1 22.8 33.5 85.1 47.1 52.6
- DEG/PD: Double Ended Guillotine Break at Pump Discharge Leg
- Results are for ZrB 2 fuel type at Burnup of 500 MWD/MTU Results are for U0 2 fuel type at Burnup of 500 MWD/MTU to 2CAN070702 Page 12 of 39 Table 5-5 Large Break LOCA ECCS Performance Analysis Each Break Variables Plotted as a Function of Time Variable Core Power Pressure in Center Hot Assembly Node Leak Flow Rate Hot Assembly Flow Rate (Below and Above Hot Spot)
Hot Assembly Quality Containment Pressure Mass Added to Core During Reflood Peak Cladding Temperature Table 5-6 Large Break LOCA ECCS Performance Analysis Limiting Break Variables Plotted as a Function of Time Variable Mid Annulus Flow Rate Quality Above and Below the Core Core Pressure Drop Safety Injection Flow Rate into Intact Discharge Legs Water Level in Downcomer During Reflood Hot Spot Gap Conductance Maximum Local Cladding Oxidation Percentage Fuel Centerline, Fuel Average, Cladding, and Coolant Temperature at the Hot Spot Hot Spot Heat Transfer Coefficient Hot Pin Pressure Core Bulk Channel Flow Rate Effective Spray and Spillage to Containment Containment (steam) Temperature Containment (water) Temperature to 2CAN070702 Page 13 of 39 Table 5-7 Small Break LOCA ECCS Performance Analysis Core and Plant Design Data Quantity Value Units Reactor power level (including uncertainty) 3087 MWt Peak linear heat generation rate (PLHGR) 13.7 kW/ft Axial shape index -0.3 Gap conductance at PLHGR(1 ) 1853 BTU/hr-ft2 -OF Fuel centerline temperature at PLHGR(1) 3303 OF Fuel average temperature at PLHGR(1) 2070 OF 1
Hot rod gas pressure( ) 710 psia Moderator temperature coefficient at initial density 0.0x104 Ap/°F 6
RCS flow rate 117.4x 10 Ibm/hr 6
Core flow rate 113.3x10 Ibm/hr RCS pressure 2200 psia Cold leg temperature 556.7 OF Hot leg temperature 621.1 OF Plugged tubes per steam generator 1064 count MSSV first bank opening pressure 1130.9 psia Low pressurizer pressure reactor trip setpoint 1400 psia Low pressurizer pressure SIAS setpoint 1400 psia HPSI Flow Rate Table 5-8 gpm Safety injection tank pressure 500.0 psia Note:
(1) These quantities correspond to the rod average burnup of the hot rod (500 MWD/MTU) that yields the maximum initial stored energy.
to 2CAN070702 Page 14 of 39 Table 5-8 High Pressure Safety Injection Pump Minimum Delivered Flow to RCS (Assuming Failure of an Emergency Diesel Generator)
RCS Pressure, psia Flow Rate, gpm 14.7 738.7 22.0 736.6 31.0 733.3 35.0 732.2 46.0 729.0 191.0 680.4 327.0 631.8 456.0 583.2 577.0 534.6 692.0 486.0 800.0 437.4 899.0 388.8 990.0 340.2 1071.0 291.6 1142.0 237.6 1201.0 172.8 1248.0 102.6 1268.8 54.0 1281.4 0.0 Notes:
- 1. The flow is split equally to each of the four discharge legs.
- 2. The flow to the broken discharge leg spills out the break.
to 2CAN070702 Page 15 of 39 Table 5-9 Small Break LOCA ECCS Performance Analysis Results Peak Cladding Maximum Cladding Maximum Core-Break Size Temperature Oxidation Wide Cladding (OF) (%) Oxidation (%)
0.03 ft2/PD 1971 12.42 < 0.69 0.04 ft2/PD 2111 16.77 < 0.88 0.05 ft2/PD 1992 13.18 < 0.73 Table 5-10 Small Break LOCA ECCS Performance Analysis Times of Interest HPSI Flow LPSI Flow SIT Flow Peak Cladding Delivered to Delivered to Delivered to Temperature RCS RCS RCS Occurs (seconds after (seconds after (seconds after (seconds after Break Size break) break) break) break) 0.03 ft2 /PD 280 (a) (b) 2273 0.04 ft2/PD 224 (a) (b) 1852 0.05 ft 2/PD 190 (a) 1755 1625 (a) Calculation completed before LPSI flow delivery to RCS begins.
(b) Calculation completed before SIT injection begins.
to 2CAN070702 Page 16 of 39 Table 5-11 Small Break LOCA ECCS Performance Analysis Variables Plotted as a Function of Time for Each Break Variable Core Power Inner Vessel Pressure Break Flow Rate Inner Vessel Inlet Flow Rate Inner Vessel Two-Phase Mixture Level Heat Transfer Coefficient at Hot Spot Coolant Temperature at Hot Spot Cladding Temperature at Hot Spot to 2CAN070702 Page 17 of 39 Figure 5-2 Figure 5-1 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 1.0 DEG/PD Break 1.0 DEGIPD Break Pressure in Center Hot Assembly Node Core Power 1.2 2400 1.0 2000 IL 08 1600 z a.
0- IL 0 0.6 1200 LU a.
0 0.4 800 a-0.2 400 00 0 0 1 2 3 4 5 0 5 10 15 20 25 TIME, SECONDS TIME. SECONDS Figure 5-4 Figure 5-3 ANO-2 NGF LBLOCA ANO-2 NGF LBLOCA ECCS Performance Analysis ECCS Performance Analysis 1.0 DEG/PD Break 1.0 DEG/PD Break Hot Assembly Flow Rate Leak Flow Rate (Below and Above Hot Spot) 120000 30 100000 20 PUMP SI E
.. VESSEL DIDE 80000 10 Q
cc S60000 0
0 40000 -10 20000 -20
-30 0 5 10 15 20 25 5 10 15 20 25 TIME. SECONDS TIME. SECONDS to 2CAN070702 Page 18 of 39 Figure 5-5 Figure 5-6 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 1.0 DEG/PD Break 1.0 DEG/PD Break Hot Assembly Quality Containment Pressure 1.2 60 ....... ........
1.0 50 0.8 40 z
0 4O 30 u- 0.6 L
20 0.4 10 0.2 0.0 L 0 L' 0 5 10 15 20 25 0 100 200 300 400 500 TIME. SECONDS TIME AFTER BREAK. SECONDS Figure 5-7 Figure 5-8 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 1.0 DEG/PD Break 1.0 DEG/PD Break Mass Added to Core During Reflood Peak Cladding Temperature 150000 .... ......... ... 2400 125000 2100 LL LU100000 (3 1800 w
m 0 a 0
a w WJ 75000 0
<Ci w 50000 S1200 25000 900 0 600 0 100 200 300 400 500 0 100 200 300 400 500 TIME AFTER CONTACT. SECONDS TIME, SECONDS to 2CAN070702 Page 19 of 39 Figure 5-10 Figure 5-9 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.8 DEG/PD Break 0.8 DEG/PD Break Pressure in Center Hot Assembly Node Core Power 1.2 2400 ... ..... ..
1.0 2000 p- 0.8 1600 U< CL a-cc 0 0.6 D 1200 Q V)
.,, ('0 0 0.4 800
(-
0.2 400 N
0.0 0 2 3 5 0 5 10 15 20 25 TIME. SECONDS TIME. SECONDS Figure 5-12 Figure 5-11 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.8 DEG/PD Break 0.8 DEG/PD Break Hot Assembly Flow Rate Leak Flow Rate (Below and Above Hot Spot) 120000 30 100000 20 80000 10 UJ U LU (n
60000 0 0 L0 40000 -10 20000 -20
-30 0 10 15 20 25 0 10 15 20 25 TIME, SECONDS TIME, SECONDS to 2CAN070702 Page 20 of 39 Figure 5-13 Figure 5.14 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.8 DEG/PD Break 0.8 DEG/PD Break Hot Assembly Quality Containment Pressure 1.2 . . . . . . . . . . . . . . . . . . . . . . . . . 60 . . . . . . . . . . . .
1.0 50 4f 0.8 40 z
0 0d
.- 0.6 - 30 (1.
0 0.4 - ' - ,
20 10 L____
NODE 13 BELOW HOTTEST REGION
I NODE 14 AT HOTTEST REGON NODE 15 ABOVE HOTTI ST REGION 0 .0 . . .. .. . . . ... .. . . .
10 15 20 25 100 200 300 400 500 TIME, SECONDS TIME AFTER BREAK. SECONDS Figure 5-15 Figure 5-16 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.8 DEG/PD Break 0.8 DEG/PD Break Mass Added to Core During Reflood Peak Cladding Temperature 15 0 0 0 0 . . . . . . . . .. . . . . . .. . . . . . . . . .. . . . . . .. . . . . . . 2 4 00 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . . . . . . .
125000 2100 ZL :
L.
L 100000 0 1800 0
0 Z Cr 0
d:
w 75000 1500 0
0 CL
< I-0 50000 __ 1200 25000 900 0 L ...... . ........ .... ... ... .. ,..... . . .. . . . . . . . . . . . . . .. ... .. .
6 00 ... .. .. . . . ... .. .. .
0 100 200 300 400 500 100 200 300 400 500 TIME AFTER CONTACT, SECONDS TIME. SECONDS to 2CAN070702 Page 21 of 39 Figure 5-18 Figure 5-17 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.6 DEG/PD Break 0.6 DEG/PD Break Pressure in Center Hot Assembly Node Core Power 1.2 2400 ... .... .. ..... ......
1.0 2000 I:
0.8 1600 0 0.
L-LU4 T-0.6 S: 1200 In (0
I:"
0 a.
0 0.4 800 0.2 400 0.0 0 1 2 3 4 5 0 5 10 15 20 25 TIME. SECONDS TIME, SECONDS Figure 5-20 Figure 5-19 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.6 DEG/PD Break 0.6 DEG/PD Break Hot Assembly Flow Rate Leak Flow Rate (Below and Above Hot Spot) 120000 30 100000 20 PUMP SIDE BELOWI OT SPOT
.......-- - . VESSEL :IDE
--- . ... ABOVE
. SPOT .T 80000 10 1U) 60000 L) 0 U.
0 40000 -10 20000 -20 0 .30 0 5 10 15 20 25 0 5 10 15 20 25 TIME. SECONDS TIME. SECONDS to 2CAN070702 Page 22 of 39 Figure 5-21 Figure 5-22 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.6 DEG/PD Break 0.6 DEG/PD Break Hot Assembly Quality Containment Pressure 1.2 60 1.0 50 0.8 40 z
03 U- 0.6 30 F- 2)
U)
U) 0LI a,3 0.4 20 0.2 10 NODE 13 BELOW HO'rr ST REGION
-. NODE 14 ATHOTTEST EGION
. . NODE 151ABOVEHO-I ST REGION 0
00 0 5 10 15 20 25 100 200 300 400 500 TIME. SECONDS TIME AFTER BREAK. SECONDS Figure 5-23 Figure 5-24 AND-2 NGF LBLOCA ECCS Performance Analysis AND-2 NGF LBLOCA ECCS Performance Analysis 0.6 DEG/PD Break 0.6 DEG/PD Break Mass Added to Core During Reflood Peak Cladding Temperature 150000 2400 125000 2100 A
~ ~ . . .........
U-w 100000 0 1800 14 0
oc 0
0 W LI 1 75000 CL 1500 0 H 0 '0 Cl) 50000 1200 25000 900 L
0 0 100 200 300 400 500 0 100 200 300 400 500 TIME AFTER CONTACT, SECONDS TIME, SECONDS to 2CAN070702 Page 23 of 39 Figure 5-26 Figure 5-25 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Pressure in Center Hot Assembly Node Core Power 1.2 2400 .... .... . .. . .. ... ..
1.0 2000 0.8 1600 0~
- a. a:
S 1200 0 0.6 800 0 0.4 a.
U, 400 0.2 0.0 0 0 1 2 3 4 5 0 5 10 15 20 25 TIME. SECONDS TIME, SECONDS Figure 5-28 Figure 5-27 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Hot Assembly Flow Rate Leak Flow Rate (Below and Above Hot Spot) 120000 30 100000 20 80000 10 U) 60000 U, 0 a:
0 0 40000 -10 20000 -20
-30 0 10 15 20 25 10 15 20 25 TIME, SECONDS TIME.SECONDS to 2CAN070702 Page 24 of 39 Figure 5-29 Figure 5-30 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Hot Assembly Quality Containment Pressure 1.2 60 1.0 50 08 40 A
z 0
(<
LL 0.6 nw 30 (L3 0.
.. . 1I. . . .. .. . ..
0.4 20 0.2 10 NODE13 BELOWHOIT' STREGION
--- ----- NODE14ATHOTTEST FEGION
-- NODE15ABOVEHOfl ST,RE.G ION 0.0 0
0 5 10 15 20 25 0 100 200 300 400 500 TIME. SECONDS TIME AFTER BREAK, SECONDS Figure 5-31 Figure 5-32 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Mass Added to Core During Reflood Peak Cladding Temperature 150000 2400 125000 2100 100000 (9 1800 w
a iI S
to 75000 1500 w
0 50000 5 1200 25000 900 600 100 200 300 400 500 0 100 200 300 400 500 TIME AFTER CONTACT. SECONDS TIME, SECONDS
1.
Attachment 1 to 2CAN070702 Page 25 of 39 Figure 5-33 Figure 5-34 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Mid Annulus Flow Rate Quality Above and Below the Core 10000 1.2 5000 0 0.8 z
0 L-LU" -5000
>.- 0.6 0
- 10000 0.4
-15000 0.2
-20000 0 0 5 10 15 20 25 0 5 10 15 20 25 TIME, SECONDS TIME. SECONDS Figure 5-35 Figure 5-36 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEGIPD Break Core Pressure Drop Safety Injection Flow Rate into Intact Discharge Legs 30 24000 20 20000 LU 10 16000 5
cr 0 (n
U) z 12000 U, 0 Cc M C,)
-10 8000 U)
-20 4000
-30 0 10 15 20 25 20 40 60 80 100 TIME. SECONDS TIME AFTER BREAK, SEC to 2CAN070702 Page 26 of 39 Figure 5-37 Figure 5-38 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Water Level in Downcomer During Reflood Hot Spot Gap Conductance 24 2400 20 2OO0 LU 16100 16
-i w
12 1200 z
0 L) 8 < 800 0
4 400 0
~~
,l il . . . . . . . i . . . . . . . . . . . . . . . .. . . . . . . . ..
0 100 200 300 400 500 0 100 200 300 400 500 TIME AFTER CONTACT. SECONDS TIME, SECONDS Figure 5-40 Figure 5-39 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEGIPD Break 0.4 DEG/PD Break Fuel Centerline, Fuel Average, Cladding, and Coolant Maximum Local Cladding Oxidation Percentage Temperature at the Hot Spot 18 2400 15 2000 1 -'
12 1600 z L(
0
_o 4L cc S1200 COOLANF 0 FUEL AV :RAGE 5 w CLAD L) FUEL CE TERLINE 6 800 400 3
0 0 0ý 0 100 200 300 400 500 100 200 300 400 500 TIME. SECONDS TIME. SECONDS to 2CAN070702 Page 27 of 39 Figure 5-41 Figure 5-42 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Hot Spot Heat Transfer Coefficient Hot Pin Pressure 120o 1200 . . . . ..
100 1000 U- 80 800 0 D i- u)
(.3 60 600 W U) w cc 40 400 20 200 0
100 200 300 400 5C10 0 20 40 60 80 100 TIME. SECONDS TIME AFTER BREAK. SEC Figure 5-43 Figure 5-44 ANO 1-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis
. 0.4 DEG/PD Break 0.4 DEG/PD Break Core Bulk Channel Flow Rate Effective Spray and Spillage to Containment 30000 6000 . . . . . . . . . . . . . . . . . . . . . . . .
_ SPRAY(1) 5000............. SPRAY(2) 20000 0- - SPRAY(3) --
-oral Spray CORE IN ET
COREE IT 10000 4000 0
Lu 0 0 wL 3000 05 Cr
-10000 2000
-20000 1000 BULK CHA ENL REPRES NTS 98%
OF THE T AL CORE FLI 1WAREA
-30000 0 5 10 15 20 25 20 40 660 80 100 TIME. SECONDS TIME. SEC to 2CAN070702 Page 28 of 39 Figure 5-45 Figure 5-46 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.4 DEG/PD Break 0.4 DEG/PD Break Containment (steam) Temperature Containment (water) Temperature 300 300 250 250 200 LL 200 LU (0 (0 a
0i ct 150 cr w 150 wU 0W I-100 100 50 50 0
100 200 300 400 500 0 100 200 300 400 500 TIME. SEC TIME, SEC to 2CAN070702 Page 29 of 39 Figure 5-48 Figure 5-47 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.3 DEG/PD Break 0.3 DEG/PD Break Pressure in Center Hot Assembly Node Core Power 1.2 2400 1.0 2000 0
0.8 1600 Z
0- -C 0.6 0 Ca 1200 D-LU 0.4 800 a-0 0.2 400 0.0 L 0 0 2 3 5 0 5 10 15 20 25 TIME. SECONDS TIME,SECONDS Figure 5-50 Figure 5-49 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.3 DEGIPD Break 0.3 DEGIPD Break Hot Assembly Flow Rate (Below and Above Hot Spot)
Leak Flow Rate 120000 30 100000 20 PUMP SIVE
.-- VESSEL IDE 80000 10 0
LU 60000 0 0
40000 -10 20000 -20 0 -30 0 5 10 15 20 25 10 15 20 25 TIME. SECONDS TIME. SECONDS to 2CAN070702 Page 30 of 39 Figure 5-51 Figure 5-52 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.3 DEG/PD Break 0.3 DEG/PD Break Hot Assembly Quality Containment Pressure 1.2 60 1.0 5o 0.8 40 z
0 (L
Lu-cr LL 0.6 -- 30 0 U)
CD (L
0.4 20 0.2 10 0.0 0!
0 5 10 15 20 25 0 100 200 300 400 500 TIME, SECONDS TIME AFTER BREAK. SECONDS Figure 5-53 Figure 5-54 ANO-2 NGF LBLOCA ECCS Performance Analysis ANO-2 NGF LBLOCA ECCS Performance Analysis 0.3 DEG/PD Break 0.3 DEG/PD Break Mass Added to Core During Reflood Peak Cladding Temperature 150000 2400 125000 2100 LL U 100000 0 1800 (r
0 00 0
w 75000 (r 15DO 1200 50000 900 25000 600 0
0 100 200 300 400 500 0 100 200 300 400 500 TIME AFTER CONTACT, SECONDS TIME, SECONDS to 2CAN070702 Page 31 of 39 Figure 5-55 Figure 5-56 ANO-2 NGF SBLOCA 0.03 ft 2/PD Break 2 ANO-2 NGF SBLOCA 0.03 ft /PD Break Core Power Inner Vessel Pressure 1.50 . ......... . 2400 1.25 2000 S1 00 1600 0
(L 0 a
- 075 1200 N Lu C')
a_
z0 0.50 800 0.25 400 0.00 0 0 100 200 300 400 500 0 600 1200 1800 2400 3000 TIME. SEC TIME, SEC Figure 5-57 Figure 5-58 ANO-2 NGF SBLOCA 0.03 ft /PD Break ANO-2 NGF SBLOCA 0.03 ft 2/PD Break Break Flow Rate Inner Vessel Inlet Flow Rate 1200 50000 1000 40000 800 30000 C.)
Lu LuJ 6600
- 20000 Cr Lu 400 10000 200 0
-10000 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME, SEC TIME. SEC to 2CAN070702 Page 32 of 39 Figure 5-59 Figure 5-60 ANO-2 NGF SBLOCA 0.03 ft/PD Break ANO-2 NGF SBLOCA 0.03 ft 2/PD Break Inner Vessel Two-Phase Mixture Level Heat Transfer Coefficient at Hot Spot 48 10 40 10 104 32 J
w 0 10 C, 24
.n CM n"
r 0 I-102 16 8 10 1001 0 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME, SEC TIME. SEC Figure 5-61 Figure 5-62 ANO-2 NGF SBLOCA 0.03 ft2/PD Break ANO-2 NGF SBLOCA 0.03 ft2/PD Break Coolant Temperature at Hot Spot Cladding Temperature at Hot Spot 2200 2200 1900 1900 0
LI-LII Hc D
w_
Ir wU 1600 1300 1000 LL 0usJ H
Z-w H
1600 1300 1000 700 700 400 400 0 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME. SEC TIME. SEC to 2CAN070702 Page 33 of 39 Figure 5-63 Figure 5-64 ANO-2 NGF SBLOCA 0.04 ft2 /PD Break ANO-2 NGF SBLOCA 0.04 ft2/PD Break Core Power Inner Vessel Pressure 1.50 2400 1.25 2000 i-LL 1.00 1600 0
EL (L
I- Lii 1200 U, 0U a.
0 0.50 Z 800 0.25 400 0.00 0
0 100 200 300 400 500 600 1200 1800 2400 3000 TIME. SEC TIME. SEC Figure 5-65 Figure 5-66 ANO-2 NGF SBLOCA 0.04 ft2/PD Break ANO-2 NGF SBLOCA 0.04 ft2IPD Break Break Flow Rate Inner Vessel Inlet Flow Rate 1200 50000 1000 40000 800 30000 U,
-j -o S 600 20000 0 0 400 10000 200 0
-10000 0 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME. SEC TIME. SEC to 2CAN070702 Page 34 of 39 Figure 5-67 Figure 5-68 ANO-2 NGF SBLOCA 0.04 ft21PD Break ANO-2 NGF SBLOCA 0.04 ft2 lPD Break Inner Vessel Two-Phase Mixture Level Heat Transfer Coefficient at Hot Spot 48 10 6
40 10 32 In I
-j a w1 wj 24 105 0n Im-CD 10 16 10 0
600 1200 1800 2400 3000 10 0 600 1200 1800 2400 3000 TIME. SEC TIME. SEC Figure 5-69 Figure 5-70 ANO-2 NGF SBLOCA 0.04 ft 21PD Break ANO-2 NGF SBLOCA 0.04 ft21PD Break Coolant Temperature at Hot Spot Cladding Temperature at Hot Spot 2200 2200 1900 1900 1600 1600 0 0 U- uL n(
1300 W 1300
<C n" a=
H in aU ,i, 1000 1000 700 700 Ut,,/ 400 0 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME. SEC TIME. SEC to 2CAN070702 Page 35 of 39 Figure 5-71 Figure 5-72 ANO-2 NGF SBLOCA 0.05 ft2/PD Break ANO-2 NGF SBLOCA 0.05 ftf/PD Break Core Power Inner Vessel Pressure 1.50 2400 1.25 2000 W 00 1600 0 i6o ui 0
00 0.75 1200 N w (r
zo 0.50 800 0,25 400 0.00 0 0 100 200 300 400 500 0 600 1200 1800 2400 3000 TIME. SEC TIME, SEC Figure 5-73 Figure 5-74 ANO-2 NGF SBLOCA 0.05 ft'/PD Break ANO-2 NGF SBLOCA 0.05 ft2IPD Break Break Flow Rate Inner Vessel Inlet Flow Rate 1200 50000 1000 40000 800 30000 Uj - 0 CO, 600 10000 0
400 0
200 -10000 0 600 1200 1800 2400 3000 600 1200 1800 2400 3000 TIME, SEC TIME. SEC to 2CAN070702 Page 36 of 39 Figure 5-75 Figure 5-76 ANO-2 NGF SBLOCA 0.05 ft 2/PD Break 2 ANO-2 NGF SBLOCA 0.05 ft /PD Break Inner Vessel Two-Phase Mixture Level Heat Transfer Coefficient at Hot Spot 106 48 10 40 10 32
-J U-0
- 24 CE 10 Q
16 I o2 102 10*
6 0 l0o L 0 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME, SEC TIME. SEC Figure 5-77 Figure 5-78 ANO-2 NGF SBLOCA 0.05 ft 2/PD Break 2 ANO-2 NGF SBLOCA 0.05 ft /PD Break Coolant Temperature at Hot Spot Cladding Temperature at Hot Spot 2200 2200 .....'
1900 1900 1600 1600 0 0 c-i" LU
- 1300 1300 w
a:
1000 1000 700 700
. . ... . .. . .. . .. .. .. , , , , , , , , r , , , ,
400 400 0 600 1200 1800 2400 3000 0 600 1200 1800 2400 3000 TIME. SEC TIME. SEC to 2CAN070702 Page 37 of 39 7.0 References 1-1 Code of Federal Regulations, Title 10, Part 50, Section 50.46, "Acceptance Criteria for Emergency Core Cooling System for Light Water Nuclear Power Reactors."
1-2 Code of Federal Regulations, Title 10, Part 50, Appendix K, "ECCS Evaluation Models."
1-3 CENPD-132P, "Calculative Methods for the C-E Large Break LOCA Evaluation Model,"
August 1974.
CENPD-1 32P, Supplement 1, "Calculational Methods for the C-E Large Break LOCA Evaluation Model," February 1975.
CENPD-1 32-P, Supplement 2-P, "Calculational Methods for the C-E Large Break LOCA Evaluation Model," July 1975.
CENPD-1 32, Supplement 3-P-A, "Calculative Methods for the C-E Large Break LOCA Evaluation Model for the Analysis of C-E and W Designed NSSS," June 1985.
CENPD-1 32, Supplement 4-P-A, "Calculative Methods for the C-E Nuclear Power Large Break LOCA Evaluation Model," March 2001.
1-4 CENPD-1 32, Supplement 4-P-A, Addendum 1-P, "Calculative Methods for the CE Nuclear Power Large Break LOCA Evaluation Model, Improvement to 1999 Large Break LOCA EM Steam Cooling Model for Less Than 1 in/sec Core Reflood, May 2006 and Final Safety Evaluation for Westinghouse Electric Company (Westinghouse) Topical Report (TR)
CENPD-132 Supplement 4-P-A, Addendum 1-P, "Calculative Methods for the CE
[Combustion Engineering] Nuclear Power Large Break LOCA Evaluation Model -
Improvement to 1999 Large Break LOCA EM Steam Cooling Model for Less Than 1 in/sec Core Reflood" (TAC No. MD2161) dated June 27, 2007.
1-5 CENPD-133P, "CEFLASH-4A, A FORTRAN-IV Digital Computer Program for Reactor Blowdown Analysis," August 1974.
CENPD-133P, Supplement 2, "CEFLASH-4A, A FORTRAN-IV Digital Computer Program for Reactor Blowdown Analysis (Modifications)," February 1975.
CENPD-1 33, Supplement 4-P, "CEFLASH-4A, A FORTRAN-IV Digital Computer Program for Reactor Blowdown Analysis," April 1977.
CENPD-133, Supplement 5-A, "CEFLASH-4A, A FORTRAN77 Digital Computer Program for Reactor Blowdown Analysis," June 1985.
1-6 CENPD-134 P, "COMPERC-II, A Program for Emergency-Refill-Reflood of the Core,"
August 1974.
CENPD-134 P, Supplement 1, "COMPERC-II, A Program for Emergency Refill-Reflood of the Core (Modifications)," February 1975.
CENPD-134, Supplement 2-A, "COMPERC-II, A Program for Emergency Refill-Reflood of the Core," June 1985.
1-7 CENPD-213-P, "Application of FLECHT Reflood Heat Transfer Coefficients to C-E's 16 x 16 Fuel Bundles," January 1976.
to 2CAN070702 Page 38 of 39 1-8 LD-81-095, Enclosure 1-P-A, "C-E ECCS Evaluation Model, Flow Blockage Analysis,"
December 1981.
1-9 CENPD-138P, "PARCH, A FORTRAN-IV Digital Program to Evaluate Pool Boiling, Axial Rod and Coolant Heatup," August 1974.
CENPD-138P, Supplement 1, "PARCH, A FORTRAN-IV Digital Program to Evaluate Pool Boiling, Axial Rod and Coolant Heatup (Modifications)," February 1975.
CENPD-1138, Supplement 2-P, "PARCH, A FORTRAN-IV Digital Program to Evaluate Pool Boiling, Axial Rod and Coolant Heatup," January 1977.
1-10 CENPD-135P, "STRIKIN-II, A Cylindrical Geometry Fuel Rod Heat Transfer Program,"
August 1974.
CENPD-135P, Supplement 2, "STRIKIN-Il, A Cylindrical Geometry Fuel Rod Heat Transfer Program (Modifications)," February 1975.
CENPD-1 35, Supplement 4-P, "STRIKIN-Il, A Cylindrical Geometry Fuel Rod Heat Transfer Program," August 1976.
CENPD-135-P, Supplement 5, "STRIKIN-II, A Cylindrical Geometry Fuel Rod Heat Transfer Program," April, 1977.
1-11 CENPD-139-P-A, "C-E Fuel Evaluation Model," July 1974.
CEN-161(B)-P-A, "Improvements to Fuel Evaluation Model," August 1989.
CEN-161(B)-P, Supplement 1-P-A, "Improvements to Fuel Evaluation Model,"
January 1992.
1-12 CENPD-137P, "Calculative Methods for the C-E Small Break LOCA Evaluation Model,"
August 1974.
CENPD-137, Supplement 1-P, "Calculative Methods for the C-E Small Break LOCA Evaluation Model," January 1977.
CENPD-1 37, Supplement 2-P-A, "Calculative Methods for the ABB CE Small Break LOCA Evaluation Model," April 1998.
1-13 CENPD-133P, Supplement 1, "CEFLASH-4AS, A Computer Program for the Reactor Blowdown Analysis of the Small Break Loss of Coolant Accident," August 1974.
CENPD-1 33, Supplement 3-P, "CEFLASH-4AS, A Computer Program for the Reactor Blowdown Analysis of the Small Break Loss of Coolant Accident," January 1977.
1-14 CENPD-254-P-A, "Post-LOCA Long Term Cooling Evaluation Model," June 1980.
1-15 WCAP-16500-P, Rev. 0, "CE 16 x 16 Next Generation Fuel Core Reference Report,"
February 2006. (pending NRC approval) 1-16 WCAP-12610-P-A and CENPD-404-P-A Addendum 1, "Addendum 1 to WCAP-12610-P-A and CENPD-404-P-A Optimized ZIRLOTM, February 2003.
to 2CAN070702 Page 39 of 39 1-17 Letter from H. N. Berkow (NRC) to J. A. Gresham (Westinghouse), "Final Safety Evaluation for Addendum 1 to Topical Report WCAP-12610-P-A and CENPD-404-P-A, 'Optimized ZIRLOTM (TAC No. MB8041)," June 10, 2005.
1-18 CENPD-404-P-A, "Implementation of ZIRLOTM Cladding Material in CE Nuclear Power Fuel Assembly Designs," November 2001.
1-19 WCAP-16072-P-A, "Implementation of Zirconium Diboride Burnable Absorber Coatings in CE Nuclear Power Fuel Assembly Designs," August 2004.
1-20 Entergy letter to the NRC dated April 24, 2007, "License Amendment Request to Allow the Use of Optimized ZIRLOTM Fuel Rod Cladding" (2CAN040703).