Response to Request for Additional Information 263, Revision 0, Relocation of Reactor Coolant System Parameters to Core Operating Limits Report & 20 Percent Steam Generator Tube Plugging

ML021690261
Person / Time
Site:	Crystal River
Issue date:	06/05/2002
From:	Roderick D Florida Power Corp
To:	Document Control Desk, Office of Nuclear Reactor Regulation
References
3F0602-05 32-1257514-01, 51-5000475-01
Download: ML021690261 (58)
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Text

j Florida Power A Progress Energy Company Crystal River Unit 3 Docket No. 50-302 Operating License No. DPR-72 Ref: 10CFR50.90 June 5, 2002 3F0602-06 U.S. Nuclear Regulatory Commission Attn: Document Control Desk Washington, DC 20555-0001

Subject:

Crystal River Unit 3, Response to Request for Additional Information LAR

1. 263, Revision 0, Relocation of Reactor Coolant System Parameters to the Core Operating Limits Report and 20 percent Steam Generator Tube Plugging

References:

1. NRC to FPC letter, 3N1201-10, dated December 27, 2001, "Crystal River Unit 3 Request For Additional Information RE: Proposed License Amendment Request No.263, Revision 0, Relocation Of Reactor Coolant System Parameters To The Core Operating Limits Report And 20 Percent Steam Generator Tube Plugging" (TAC NO. MB2499)

2. NRC to FPC letter, 3N0402-19, dated April 23, 2002, "Crystal River Unit 3 Request For Additional Information RE: Proposed License Amendment Request No.263, Revision 0, Relocation Of Reactor Coolant System Parameters To The Core Operating Limits Report And 20 Percent Steam Generator Tube Plugging" (TAC NO. MB2499)

3. FPC to NRC letter 3F0701-11, dated July 24, 2001, "License Amendment Request #263, Revision 0, Relocation Of Reactor Coolant System Parameters To The Core Operating Limits Report And 20 Percent Steam Generator Tube Plugging"

Dear Sir:

Florida Power Corporation (FPC) submits the additional information requested in References 1 and 2 concerning the License Amendment Request #263, Revision 0 (Reference 3).

Attachment A provides the responses to the Request for Additional Information (RAI).

Attachment B and Attachment D provide Framatome ANP calculations on flow induced vibration for steam generator tubes.

These calculations provide additional information concerning the RAI in Reference 2.

Attachment D contains information that Framatome ANP considers to be proprietary.

Framatome ANP requests that the proprietary information in this response (Attachment D) be withheld from public disclosure in accordance with 10 CFR 9.17(a)(4), 2.790(a)(4) and 2.790(d)(1). An affidavit supporting this request is provided in Attachment C.

ý,10 15760 West Power Line Street

• Crystal River, Florida 34428-6708 * (352) 795-6486

U.S. Nuclear Regulatory Commission 3F0602-06 Page 2 of 3 This letter makes no new regulatory commitments.

If you have any questions regarding this submittal, please contact Mr. Sid Powell, Supervisor, Licensing and Regulatory Programs at (352) 563-4883.

• Daniel L. Roderick Director Site Operations Crystal River Nuclear Plant DLR/pei Attachments:

A. Response to NRC Request for Additional Information B. FRA-ANP Engineering Information Record, CR-3 OTSG FIV Margins, document number 51-5000475-01, October 1, 2001, Non-Proprietary C. Framatome ANP Affidavit of Proprietary Information D. FRA-ANP Calculation file, "Flow Induced Vibration Analysis of TMI OTSG Tubes Due to Power Uprate," document number 32-1257514-01, June 23, 1997, PROPRIETARY xc:

Regional Administrator, Region II w/o Attachment D Senior Resident Inspector w/o Attachment D NRR Project Manager

U.S. Nuclear Regulatory Commission 3F0602-06 Page 3 of 3 STATE OF FLORIDA COUNTY OF CITRUS Daniel L. Roderick states that he is the Director Site Operations, Crystal River Nuclear Plant for Progress Energy; that he is authorized on the part of said company to sign and file with the Nuclear Regulatory Commission the information attached hereto; and that all such statements made and matters set forth therein are true and correct to the best of his knowledge, information, and belief.

Z

/7 Daniel L. Roderick Director Site Operations Crystal River Nuclear Plant The foregoing document was acknowledged before me this 54-h

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FLORIDA POWER CORPORATION CRYSTAL RIVER UNIT 3 DOCKET NUMBER 50 - 302 / LICENSE NUMBER DPR - 72 ATTACHMENT A LICENSE AMENDMENT REQUEST #263, REVISION 0 Relocation Of Reactor Coolant System Parameters To The Core Operating Limits Report And 20 Percent Steam Generator Tube Plugging Response to NRC Request for Additional Information

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 1 of 29 Response To NRC Request For Additional Information

1. NRC Request:

The license amendment request is to allow plugging of up to an equivalent of 20 percent of all Once-Through Steam Generator (OTSG) tubes.

For symmetric plugging, this allows up to 20 percent of the tubes in each OTSG to be plugged.

Florida Power Corporation did not specifically state the level of asymmetric tube plugging or the maximum percentage of plugged tubes in anyone OTSG that is to be allowed. Although asymmetric tube plugging analyses and results were discussed, it is not clear which analysis determines the limiting acceptable tube plugging asymmetry.

Please provide a discussion regarding any restrictions being placed on the maximum number of plugged tubes in any one OTSG and the maximum plugging asymmetry between OTSGs. Provide justification for these restrictions.

FPC Response:

Relative to OTSG tube plugging, the license amendment request will allow up to an equivalent of 20 percent of the tubes in either or both steam generators to be plugged, including 0 percent/20 percent asymmetric tube plugging. Framatome ANP performed the analysis in such a manner as to eliminate the need for an asymmetric plugging limit. There is no single analysis that defines the maximum allowed asymmetry. Steam generator tube plugging reduces the tube heat transfer area and decreases the flow area through the tubes.

These changes alter the fluid temperatures, reactor coolant system (RCS) flow rates, and secondary side mass inventories during steady-state operation and transients. Asymmetric tube plugging effects create both overall and loop specific changes that are scenario specific.

The overall RCS steady-state changes are best represented by an equivalent overall plugging limit (i.e., change in total core flow), but these may have asymmetric effects reflected by loop and core inlet temperature differences that may create slight core power tilts. The transient analyses in which the loops remain roughly symmetrical (e.g.,

four-pump coastdown, turbine trip, and loss of all main feedwater) are also best characterized with symmetrical plugging.

Transients for which asymmetric effects are important (e.g., cold leg loss-of-coolant accidents (LOCAs), locked pump rotor, single pump coastdown) are best characterized with asymmetric plugging.

For these events, specific analyses were performed to address the asymmetric effects. For the LOCAs, the peak clad temperature calculations considered up to 25 percent plugged tubes in one steam generator with up to 15 percent in the opposite loop steam generator (this distribution was most limiting for the LOCA analysis). For the departure from nucleate boiling (DNB) and core peaking aspects, the core flow distribution created by a 0 percent and 30 percent tube plugging asymmetry was evaluated. It was determined that this asymmetry could reduce the localized core inlet flow velocity by 0.4 percent. This asymmetric effect on flow was included in the global flow reduction associated with 20 percent tube plugging in both OTSGs.

(A further discussion of the asymmetrical effects on the DNB analysis is

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 2 of 29 presented in the response to Question 2.e. below.) Based on these analyses, no asymmetric plugging limits are required. The OTSG plugging limit is a maximum equivalent of 20 percent of the tubes that can be plugged in either or both steam generators.

2. NRC Request:

Three vendor-proprietary OTSG Thermal-Hydraulic performance-related computer codes were referenced and used by the licensee in the 20 percent tube plugging analyses:

FSPLIT VAGEN PORTHOS

a. Discuss the interaction of these three codes with the design-basis accident/transient analysis codes.

FPC Response:

There is no direct interaction between these three codes and the design basis accident/transient analysis codes.

Indirect interaction has included comparing the results from these three design codes with the results from the design basis accident/transient analysis codes.

b. These three codes have not been reviewed and approved for use by the U.S.

Nuclear Regulatory Commission. Are these codes appropriately controlled in accordance with Title 10 of the Code of Federal Regulations, Appendix B?

FPC Response:

Yes, these codes are used in accordance with Framatome ANP procedures governing the use of internally developed design codes. There is no requirement for NRC review and approval of these types of codes.

c. Confirm that the input data, model, and options selected accurately represent CR-3 plant-specific design features and justify the use of these codes for CR-3.

Please note that the use of the PORTHOS code was not discussed in the submittal.

FPC Response:

The FSPLIT model (B&W 32-1203121-01, "FSPLIT Certification Analysis") is a Crystal River Unit 3 (CR-3) specific hydraulics model that has been benchmarked to measurements derived from RCS flows and incorporates CR-3 specific reactor coolant pump (RCP) performance curves and CR-3 hydraulics inputs.

The VAGEN model (FTI Report TRG 78-2, Revision K, "VAGEN Generator Performance Prediction,"

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 3 of 29 May 1995) is generic to B&W design 177 fuel assembly (FA) plants.

It has been benchmarked to model boiler and plant data.

The PORTHOS model (FTI 32-1239294-00, "PORTHOS for OTSG Applications") is generic to non-internal auxiliary feedwater (AFW) header, B&W 177 FA design plants, and thus applies to CR-3. PORTHOS has been benchmarked to model boiler and plant data.

d. Provide a discussion of the key assumptions and methodology used to determine the impact of symmetric and asynmnetric OTSG tube plugging on RCS flow and hot-to-cold leg temperature difference (delta-T) for both three and four reactor coolant pump (RCP) operation and confirm that the results are bounding.

FPC Response:

The methodology used in calculating the RCS flow changes due to tube plugging was to reduce the steam generator flow area and adjust the tube sheet inlet and outlet form loss factors commensurate with the degree of tube plugging. Both symmetric and asymmetric plugging were modeled within the RCS hydraulics model to define the reactor vessel inlet nozzle flow rates. Experimental data from vessel model flow tests were used to correlate inlet nozzle flow asymmetry (due to OTSG tube plugging asymmetry) with core inlet velocity asymmetry.

The results of the analyses showed that asymmetric plugging resulted in applying an additional 0.5% decrease in core inlet flow to compensate for its effects.

There is no limit on the hot-to-cold leg temperature difference. The integrated control system (ICS) will re-ratio feedwater flows to the OTSGs to ensure equal cold leg temperatures.

e. Provide a discussion regarding the methodology used to calculate, combine, and apply the symmetric and asymmetric core design and Departure from Nucleate Boiling (DNB) flow penalties.

FPC Response:

The impact of OTSG tube plugging on the RCS flow rate was quantified for the CR-3 plant as well as other B&W-designed 177 FA plants as part of a B&W Owners Group project to provide supporting justification for 20% tube plugging.

The analyses indicated that CR-3 would have a global RCS flow rate reduction of 4.0% of design flow by going from a 0% tube plugging condition to a 20% tube plugging condition (as seen in Table 1, Section C.1 of Reference 2, Attachment F). The maximum global RCS flow rate reduction for all 177 FA plants examined was 4.5%.

Additional analyses found that a bounding asymmetric OTSG plugging condition (30% in one OTSG and 0% in the other OTSG, or 30%/0%) could reduce a localized core inlet flow velocity by 0.4%.

However, the same bounding asymmetric plugging condition only has a 3.5% impact on the global RCS flow reduction. Since the maximum global RCS

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 4 of 29 flow rate reduction (associated with 20%/20%) can not occur at the same time as the most severe localized core inlet flow velocity reduction (associated with a bounding asymmetric tube plugging condition) it was concluded that a 4.5% global RCS flow rate reduction impact for DNB analyses conservatively bounds the RCS global and localized core inlet flow effects for all the 177 FA plants examined.

In the CR-3 DNB analyses supporting 20% tube plugging, the 4.5% global RCS flow rate reduction has been completely incorporated. This resulted in the reduction of the nominal RCS flow rate basis, for DNB analyses, from 109% of design flow rate to 104.5% of design flow rate.

3. NRC Request:

Regarding the impact of tube plugging on increased RCS flow resistance, please provide a reference and discuss the method used to quantify that 6.7 sleeves have the same hydraulic resistance as one plug. Include in the discussion any test data and analyses this is based on, the effects of OTSG tube plugging asymmetry on this value, and whether this equivalent bounds all steady-state and transient operating conditions.

FPC Response:

The 6.7 sleeve-to-plug ratio is based on the most prevalent sleeve design. This value was provided as an example only and was not intended to imply that this value would be used for all sleeves at CR-3.

Other sleeve designs would have different sleeve-to-plug ratios.

The sleeve-to-plug ratio is based on adjusting the steam generator hydraulic resistance (within the CR-3 specific FSPLIT model) based on actual sleeve designs used at CR-3.

This includes a reduction in tube flow area and decrease in frictional diameter over the sleeve length and accounting for the additional contraction into the sleeve and expansion out of the sleeve. The RCS flow changes due to sleeving was equated with the RCS flow changes due to plugging. This methodology is currently being used for CR-3 and will not change as a result of the proposed amendment.

4. Regarding the impact of reduced RCS flow rate and potential asymmetry in system flow on fuel component integrity:

a. Clad oxidation has been determined to be the limiting constraint while CR-3 utilizes Zircaloy-4 cladding. Discuss the administrative controls, processes, or procedures in place to ensure the necessary limitations on burnup and peaking for cycle-specific reload designs are such that acceptance criteria for clad oxidation will be maintained.

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 5 of 29 FPC Response:

Cycle specific checks of clad oxidation levels are performed as part of Framatome's standard reload licensing analysis activities following methods outlined in the NRC approved topical report BAW-10186P-A Rev. 1, "Extended Burnup Evaluation."

These cycle specific checks are an integral part of the cycle design process in which the highest burnup fuel pins in each fuel batch are analyzed using Framatome's KOROS/COROS2 evaluation model. The cycle specific check incorporates bounding core parameters, while typically employing a pin specific power history.

By performing these checks early in the reload licensing process, the validity of the proposed cycle design is confirmed.

b. Please discuss the expected increase in clad oxidation levels for the current CR-3 Zircaloy-4 fuel type and demonstrate acceptance criteria are met.

FPC Response:

CR-3 Cycle 13 is the first reload cycle to consider the effects of 20% OTSG tube plugging. Results from the Cycle 13 clad oxidation check have shown that, although the highest burnup pins are approaching the clad oxide limit, acceptable results have been demonstrated by the use of pin specific power histories as described in BAW-10186P-A Rev. 1. Cycle design strategies for future cycles are expected to be similar to those of Cycle 13 resulting in similar peak burnups and similar pin power histories. It is, therefore, expected that future detailed cycle specific checks using pin specific power history data will continue to yield acceptable clad oxidation results.

c. Discuss the administrative controls, processes, or procedures in place to ensure the necessary limitations on clad lift-off for cycle-specific reload designs are such that acceptance criteria will be maintained.

FPC Response:

Cycle specific checks of fuel thermal performance, including inception of pellet/clad lift-off, are performed as part of Framatome's standard reload licensing analysis activities following methods outlined in the NRC approved topical reports BAW-10162P-A, "TACO3 Fuel Pin Thermal Analysis Computer Code,"

BAW-10184P-A, "GDTACO - Urania Gadolinia Fuel Pin Thermal Analysis Code,"

and BAW-10183P-A, "Fuel Rod Gas Pressure Criterion." These cycle specific checks confirm that the peak burnup pin in each fuel batch is bounded by a generic fuel performance analysis.

In those instances where bounding generic analyses are too restrictive, additional margin is obtained by evaluating fuel performance using pin specific power history data. Cycle 13 was the first reload cycle to consider the effects of 20% OTSG tube plugging at CR-3. For Cycle 13, the reduced flow rate associated with the higher tube plugging was incorporated into all fuel performance analyses and all acceptance criteria were met.

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 6 of 29

d. Discuss the methodology applied for the guide tube boiling analysis to determine that no saturation will occur in the guide tube Assembly Hold-down Springs, Guide Tubes, and Spacer Grids.

FPC Response:

The guide tube boiling analysis is performed using a thermal-hydraulic methodology which conservatively models a limiting control component within the guide tube and determines the margin to saturation. This analysis is a deterministic type analysis where key parameters such as total core power, flow rate within the guide tube, and heat generation within the guide tube are treated at a conservative level.

The generic analysis, which used design assumptions that were bounding for all B&W 177 FA type plants, conservatively bounded the CR-3 specific design condition.

By demonstrating positive margin to saturation for this conservative set of design conditions, assurance is given that CR-3 operation with up to 20% tube plugging will be acceptable.

Additional fuel mechanical evaluations were supported by LYNXT based calculations which determined that the impact of tube plugging was a less than 2°F increase in coolant temperatures at the spacer grid locations and at the assembly exit (e.g. at the assembly hold down springs). These LYNXT calculations were also based on design assumptions which were bounding for all B&W 177 FA type plants (BAW-10156-A, Rev.1, "LYNXT - Core Transient Thermal Hydraulic Program," March 1993). The fuel mechanical effects of this increase in temperature at the spacer grids and hold down springs were evaluated and shown to be bounded by the effects that would be seen within the guide tubes.

5. NRC Request:

Regarding the Core Physics impacts:

a. Discuss the rationale for choosing a +/-1.10F inlet temperature asymmetry penalty.

Is this meant to be consistent with the requested TS change of 1.2 OF?

FPC Response:

The licensing amendment submittal requested a change of 1.2°F to the RCS hot leg temperature DNB surveillance parameter of SR 3.4.1.2. There is no direct connection between that parameter and the +/- 1. I°F inlet temperature asymmetry value. The +/- 1. I°F inlet temperature asymmetry was associated with evaluation of potential core power distributions that could be produced by asymmetric steam generator tube plugging. The full-core NEMO power distribution analysis actually used a value of 2.2°F and split it so that the core inlet temperature from one side was higher than nominal by 1. 1°F and the other side was lower than nominal by 1. 10F. Since a +/- 1. 1IF delta Tin (for at total

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 7 of 29 of 2.20F loop delta-T) due to asymmetric plugging was modeled, the calculations remain bounding for the worst case (maximum) of 1.7°F loop delta-T. The latter figure actually represented a case that was more severe than 20%/0% tube plugging.

Furthermore, the power distribution evaluation did not take credit for any ICS action to mitigate the loop delta-T. The ICS would normally drive the loop delta-T to zero (or the desired setpoint) even with asymmetric plugging.

Therefore, in reality, it was concluded that there would be no delta-T penalty for asymmetric plugging, thus using the +/- 1. IVF value is conservative.

b. Provide more detail regarding the "conservative equation" to determine an adjusted burnup which was developed for use in core designs.

FPC Response:

Some of the power peaking limits are burnup-dependent (examples: LOCA limits and linear heat rate limits based on transient cladding strain criteria).

Therefore, an investigation was performed to determine if the differences in fuel rod burnups that could accumulate with asymmetric steam generator tube plugging could be significant.

It was found that the maximum cumulative burnup increases and decreases were on the order of 50 megawatt days per metric ton of uranium (MWd/mtU) (approximately 1.5 Effective Full Power Days) and are not large enough to cause concern with regard to application of burnup-dependent peaking limits in licensing analyses. Consequently, it was concluded that simulation of the core power distribution using quarter-core symmetry could be continued in reload cycle licensing evaluations.

c. Please provide a listing of the approved methods used to evaluate the effects of OTSG tube plugging on each aspect of core physics discussed in the submittal.

FPC Response:

The core physics analyses were performed in accordance with Section 5 of BAW 10179P-A, which is Framatome ANP's approved safety criteria and methodology topical report for reload safety evaluations.

The power distribution simulations were performed with Framatome ANP's standard nuclear design code (NEMO) used for cycle-specific reload safety evaluations.

The NEMO code is fully described in an approved topical report, and has been subjected to an extensive verification program that quantified the uncertainties associated with its application (BAW-10180-A, Rev. 1).

The code was used within its range of applicability to simulate core power distributions used in support of the evaluation of OTSG tube plugging.

e. Provide a quantitative discussion regarding the impact on transient xenon power distribution.

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 8 of 29 FPC Response:

Transient xenon power distributions are simulated in order to evaluate skewed axial power distributions in reload safety evaluations.

Section 5 of BAW-10179P-A describes how the transients are simulated and used to generate limiting core power distributions.

The evaluations performed for steam generator tube plugging simulated the same types of transients that are used in cycle-specific reload safety evaluations for B&W units, however full-core simulations were generated in order to account for power distributions with asymmetric tube plugging. The correlations of power peaking to axial offset were found to remain similar to those generated for symmetric cores with only small changes noted in axial power offset and peaking factors.

e. Do the four configurations evaluated for each core physics aspect bound the maximum allowed plugging asymmetry (this ties in with question 1)?

FPC Response:

The four configurations were designed to provide a bounding evaluation of core power distributions and margins to power peaking limits for both symmetric and asymmetric power distributions with 20% steam generator tube plugging. The base case (no tube plugging) was included in order to generate data for comparative analysis.

6. NRC Request:

Please provide the following information for the four RCP and one RCP Coastdown, Locked Rotor, Startup Event, Loss of All AC Power/Station Blackout (SBO),

Anticipated Transient Without Scram (ATWS), Large and Small Break Loss of Coolant Accidents and Main Steam Line Break events, which were either re-analyzed or re-evaluated for OTSG tube plugging:

a. Initial conditions and justification including instrument uncertainty discussions.

b. Sequence of events.

c. Trip setpoints including instrument uncertainty discussions.

d. Safety system actuation setpoints including instrument uncertainty discussions.

e. Single failure criterion.

FPC Response for A through E:

Each of the events are addressed separately below:

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 9 of 29 Four Reactor Coolant Pump (RCP) Coastdown No new system analysis was required for the four-pump coastdown accident to justify increased levels of OTSG tube plugging.

Only the DNB portion of the event was reanalyzed.

The analysis method is outlined in BAW-10179P-A, "Safety Criteria and Methodology for Acceptable Cycle Reload Analyses," Revision 2.

The original system response provides input to the DNB analysis that includes the transient core exit pressure, core inlet temperature, core inlet flow rate, and the total core power values. The system analysis was performed at the minimum design flow rate versus the minimum DNB flow rate to ensure a conservative pressure and temperature prediction. The core inlet flow is normalized and, therefore, will not be affected by the increased levels of OTSG tube plugging. The core power response is also normalized since the initial core power level in the calculation accounts for the heat balance uncertainty.

Based on the results of the system response calculation, the core pressure and the core inlet temperature are held constant throughout the DNB calculation at the initial nominal values. The uncertainty in these parameters is included in DNB calculation through application of the statistical core design methodology (BAW-10187P-A, "Statistical Core Design for B&W-Designed Plants").

The minimum DNB flow rate is reduced to account for 20 percent OTSG tube plugging and is applied to the normalized flow data from the system analysis. The loss of flow is the initiating event and the reactor is tripped based on the loss of all pumps reactor protection system (RPS) trip with a 2.6-second time delay.

Consistent with the plant design basis, there are no single failures imposed on this analysis.

No safety system actuation or operator actions are required to mitigate this event.

The transient normalized flow and power response is provided in Figure 1. The DNB response is provided in Figure 2 and was generated using the LYNXT computer code (BAW-10156A, Rev. 1, "LYNXT - Core Thermal-Hydraulic Program, Revision 1"). For this event, the calculated DNB Ratio (DNBR) remains above the thermal design limit for all times. The current statistically based thermal design limit for CR-3 is 1.40 BWC. All of the restrictions and limitations of the approved computer codes and methods were met for the four-pump coastdown analysis.

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 10 of 29 Figure I Figure 2 CR-3 Four Pump Coastdown -20% OTSG Tube Plugging CR-3 Four Pump Coaddown -20% OTSG Tube Plugging 1.2-220 1 0?_0 0.8-*

ZOO

• ~0.6 1.9 0

z 1.90 0.2 I.

Care 1.75e I

RCS Flaw 1.70________________

0 0-5 1

1.5 2

2.5 3

3.5 4

0.0 0.5 1.0 1.5 2.0 25 3.0 3.5 4.0 "Time (sec)

Time (sec)

One Reactnr Cnnolnt rnmp (RCP) COaqtdown No new system analysis was required for the single-pump coastdown accident to justify increased levels of OTSG tube plugging.

Only the DNB portion of the event was reanalyzed.

The analysis method is outlined in BAW-10179P-A, "Safety Criteria and Methodology for Acceptable Cycle Reload Analyses," Revision 2.

The original system response provides input to the DNB analysis that includes the transient core exit pressure, core inlet temperature, core inlet flow rate, and the total core power values. The system analysis was performed at the minimum design flow rate versus the minimum DNB flow rate to ensure a conservative pressure and temperature prediction.

The core inlet flow is normalized and therefore will not be affected by the increased levels of OTSG tube plugging. The core power response is also normalized since the initial core power level in the calculation accounts for the heat balance uncertainty.

Based on the results of the system response calculation, the core pressure and the core inlet temperature are held constant throughout the DNB calculation at the initial nominal values.

The uncertainty in these parameters is included in DNB calculation through application of the statistical core design methodology (BAW-10187P-A, "Statistical Core Design for B&W Designed Plants").

The minimum DNB flow rate is reduced to account for 20 percent OTSG tube plugging and is applied to the normalized flow data from the system analysis.

The loss of flow is the initiating event and the reactor is tripped based on the flux-to-flow reactor protection system (RPS) trip setpoint of 1.12985 with a 2.18-second time delay.

Consistent with the plant design basis, there are no single failures imposed on this analysis.

No safety system actuation or operator actions are required to mitigate this event.

The transient normalized flow and power response is provided in Figure 3.

The DNB response is provided in Figure 4 and was generated using the LYNXT computer code (BAW-10156A, Rev. 1, "LYNXT - Core Thermal-Hydraulic Program, Revision 1"). For this event, the calculated DNBR remains above the thermal design limit for all times. The

U.S. Nuclear Regulatory Commission 3F0602-06 Attachment A Page 11 of 29 current statistically based thermal design limit for CR-3 is 1.40 BWC.

All of the restrictions and limitations of the approved computer codes and methods were met for the single-pump coastdown analysis.

I _oclced Thimp Rotor A locked rotor event is the reduction in forced flow through the reactor coolant system when the rotor of one of the reactor coolant pumps seizes. When the rotor seizes, forced flow is no longer provided by the affected pump, which results in a more rapid initial reduction in flow than the four-pump coastdown event. The reactor is tripped based on the flux-to-flow trip function of the reactor protection system.

Once the control rods begin to insert, the core power is reduced and the minimum DNBR begins to increase. Consistent with the CR-3 design basis, there are no single failures assumed in the analysis. There is no safety system actuation or operator actions required to mitigate this event. A list of the key parameters that is used in the analysis is provided in the following table.

Parameter Core Power Primary Side Ave Fluid Temp.

RCS Pressure @ HL Tap Moderator Coefficient at Full Power Doppler Coefficient at Full Power Reactor Trip on Flux-to-Flow Ratio Reactor Tip Time Delay Value 1.02 x 1.001 of 2568 MWt 579 OF 2170 psia

+0.0 E-4 (Ak/k)/° F

-1.17 E-5 (Ak/k)/°F 1.12985 %FP/ %Flow 2.18 sec Figure 3 CR-3 Single Pump Coasbdown - 20%OTSG Tube Plugging Z

0 1

2 3

4 5

6 7

8 Time (sac)

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 12 of 29 In order to support increased levels of OTSG tube plugging, the system response to the locked pump rotor event was reanalyzed using the RELAP5/MOD2-B&W computer code (BAW-10164P-A, "RELAP5/MOD2-B&W, An Advanced Computer Program for Light Water Reactor LOCA and Non-LOCA Transient Analysis,"

Revision 3).

RELAP5/MOD2-B&W has been approved by the NRC for non-LOCA applications (BAW-10193P-A, "RELAP5/MOD2-B&W for Safety Analysis of B&W-Designed Pressurized Water Reactors").

All of the restrictions and limitations of the approved topical reports were met.

Once the system calculation was completed, the DNB portion of the event was reanalyzed.

The DNB analysis method is outlined in BAW-10179P-A, "Safety Criteria and Methodology for Acceptable Cycle Reload Analyses," Revision 2.

The system response calculation provides input to the DNB analysis that includes the transient core exit pressure, core inlet temperature, core inlet flow rate, and the total core power values. The system analysis was performed at the minimum design flow rate versus the minimum DNB flow rate to ensure a conservative pressure and temperature prediction.

The core inlet flow is normalized and is provided in Figure 5. The core power response is also normalized since the initial core power level in the calculation accounts for the heat balance uncertainty and is shown in Figure 5.

Based on the results of the system response calculation, the core pressure and the core inlet temperature are held constant throughout the DNB calculation at the initial nominal values. The uncertainty in these parameters is included in the DNB calculation through application of the statistical core design methodology (BAW-10187P-A, "Statistical Core Design for B&W-Designed Plants").

The minimum DNB flow rate is reduced to account for 20 percent OTSG tube plugging and is applied to the normalized flow data from the system analysis. The DNB response is provided in Figure 6 and was generated using the LYNXT computer code (BAW-10156A, Rev. 1, "LYNXT - Core Thermal-Hydraulic Program, Revision 1"). For this event, the calculated DNBR remains above the thermal design limit for all times.

The current statistically based thermal design limit for CR-3 is 1.40 BWC. All of the restrictions and limitations of the approved computer codes and methods were met for the locked rotor analysis.

U.S. Nuclear Regulatory Commission 3F0602-06 Attachment A Page 13 of 29 Stamrtu vent The startup event is a rod withdrawal accident from subcritical or low power conditions.

The rapid reactivity addition causes the RCS pressure, temperature, and core power to increase.

The control rods are inserted on a reactor trip based on either high system pressure or high flux. Once the control rods begin to insert, the event is quickly terminated.

A list of key parameters used in the analyses is provided in the following table.

Startup Event Key Parameters Initial Conditions Core Power 2.568 W Hot Leg Pressure 2170 psia RCS Average Temperature 532 0F Reactor Protection System High Flux Reactor Trip Setpoint 112% of 2,568 MWt?()

High RCS Pressure Reactor Trip Setpoint 2400 psia (Hot Leg) ')

Delay Time for High Flux Reactor Trip 0.4 sec ()

Delay Time for High RCS Pressure Trip 0.6 sec ()

Figure 5 CR4 Locked RCP Rotor - 20% OTSG Tube Plugging 1.2000 1.0000 0.8000 0

0.6000 0.4000 0.2000 0.0000 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 Time (sec)

U.S. Nuclear Regulatory Commission 3F0602-06 Attachment A Page 14 of 29 Startup Event Key Parameters Control Rod Drive Assembly (CRA)

Maximum Control Rod Speed 30 in/min Maximum Number of CRAs 60(a)

Maximum Rod Worth, all rods 12.9% Ak/k(a)

Maximum Reactivity Addition rate, 9.27 E-4 (Ak/k)/sec all rods at maximum speed Nominal Rod Worth of single group, 3.0% Ak/k when reactor is critical Nominal Reactivity Addition Rate, single rod group 2.15 E-4 (Ak/k)/sec Doppler Coefficient at Rated Power

-1.3 E-5 (Ak/k)/OF (b)

Moderator Coefficient at Zero Power

+0.9 E-4 (Ak/k)/!Fc(b)

Control Rod Travel Time, to 2/3 Insertion 1.4 sec Minimum Tripped Rod Worth Used 2.43 % Ak/k(c)

NOTES (a) The number of CRAs is/was not explicitly modeled in the analysis. The input to the analysis is a reactivity insertion rate that is independent of the number or worth of the control rods.

For each new core reload, the reactivity insertion rate is converted to a control rod worth and is compared to the cycle specific value to verify that the safety analysis remains bounding.

(b) In order to support increased OTSG tube plugging limits, a new analysis was performed with 30 percent of the OTSG tubes plugged (bounds 20 percent) using RELAP5/MOD2-B&W.

(c) Sufficient control rod worth was added to provide 1 % (Ak/k) shutdown margin at hot zero power conditions.

In order to support increased levels of OTSG tube plugging, a spectrum of reactivity insertion rates were reanalyzed using the RELAP5/MOD2-B&W computer code (BAW 10164P-A, "RELAP5/MOD2-B&W, An Advanced Computer Program for Light Water Reactor LOCA and Non-LOCA Transient Analysis," Revision 3). RELAP5/MOD2-B&W has been approved by the NRC for non-LOCA applications (BAW-10193P-A, "RELAP5/MOD2-B&W for Safety Analysis of B&W-Designed Pressurized Water

U.S. Nuclear Regulatory Commission Attachment A 3F0602-06 Page 15 of 29 Reactors").

All of the restrictions and limitations of the approved topical reports were met. The reanalysis supports up to 30 percent (equivalent) steam generator tube plugging and a pressurizer safety valve lift tolerance of +/-3 percent. The reanalysis was performed using the most positive moderator temperature reactivity coefficient at hot zero power conditions and a least negative Doppler reactivity coefficient as shown in the table above.

Consistent with the methods described in Section 14.1.2.2. of the CR-3 Final Safety Analysis Report (FSAR), the reactivity insertion rate was varied to find the limiting value with respect to peak system pressure and peak power.

Also consistent with the CR-3 design basis, no single failures are modeled in the analysis.

For the limiting reactivity insertion rate, the peak reactor coolant pressure was shown to be less than 110 percent of the design pressure (or < 2750 psig) using a pressurizer safety valve lift setpoint of 2500 psig with a +3 percent lift tolerance. The peak power was less than 112 percent of 2568 MegaWatts thermal (MWt).

Therefore, all the acceptance criteria were met. Based on these results, it is concluded that the reactor is completely protected against any startup accident involving the withdrawal of any or all control rods and with 3 or 4 reactor coolant pumps in operation.

In no case does the thermal power exceed the design overpower condition, and the peak pressure never exceeds code allowable limits.

The pressure response for the startup event was provided on Page 20 of Attachment F to the License Amendment Request No. 263. The peak power response for the spectrum of reactivity insertion rates analyzed is provided in Figure 7.

Figure 7 CR-3 Startup Event-20%SG Tube Plugging 80 -(Peak Thermal Power) 70 -1 60 S50 sO S40 S30 20

a.