Rev 0 to Supplemental Reload Licensing Submittal for Ja Fitzpatrick Nuclear Power Plant,Reload 5

ML20071K736
Person / Time
Site:	FitzPatrick
Issue date:	03/31/1983
From:	Charnley J, Wagner R, Zarbis W GENERAL ELECTRIC CO.
To:
Shared Package
ML20071K581	List: ML20071K576 ML20071K630 ML20071K682 ML20071K736
References
Y1003J01A56, Y1003J01A56-R01, Y1003J1A56, Y1003J1A56-R1, NUDOCS 8305270378
Download: ML20071K736 (25)
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Y1003J01A56 MARCH 1983 SUPPLEMENTAL RELOAD LICENSING SUBMITTAL FOR JAMES A. FITZPATRICK NUCLEAR POWER PLANT RELOAD 5 R8?Sl88?8ag88ll P

GENER AL $ ELECTRIC

I Y1003J01A56 Revision 0 Class I March 1983 SUPPLEMENTAL RELOAD LICENSING SUBMITTAL FOR JAMES A. FITZPATRICK NUCLEAR POWER PLANT RELOAD 5 Prepared: A W. A. Ubis Verified: -

Eh '

R.'L.Wagne(~

Approve J p . Charnley Fuel Licensing Ma er NUCLEAR POWER SYSTEMS DIVISION + GENERAL ELECTRIC COMPANY SAN JOSE, CALIFORNIA 95125 GEN ER AL $ ELECTRIC i

Y1003J01A56 Rev. 0 IMPORTANT NOTICE REGARDING CONTENTS OF THIS REPORT PLEASE READ CAREFULLY f

This report was prepared by General Electric solely for The Power Authority of the State of New York (The Authority) for The Authority's use with the U.S.

Nuclear Regulatory Commission (USNRC) for amending The Authority's operating license of the James A. FitzPatrick Nuclear Power Plant. The information con-tained in this report is believed by General Electric to be an accurate and true representation of the facts known, obtained or provided to General Electric at the time this report was prepared.

The only undertakings of the General Electric Company respecting information in this document are contained in the contract between The Authority and General Electric Company for nuclear fuel and related services for the nuclear system for The James A. FitzPatrick Nuclear Power Plant, dated June 12, 1970, and nothing contained in this document shall be construed as changing said contract. The use of this information except as defined by said contract, or for any purpose other than that for which it is intended, is not authorized; and with respect to any such unauthorized use, neither General Electric Company nor any of the contributors to this document makes any representation or warranty (express or implied) as to the completeness, accuracy or usefulness of the information contained in this document or that such use of such' information may not infringe privately owned rights; nor do they assume any responsibility for liability or damage of any kind which may result from such use of such information.  ;

11

Y1003J01A56 Rev. 0

1. PLANT UNIQUE ITEMS (1.0)*

Appendix A: GETAB Analysis Initial Conditions Appendix B: Verification of Operating Flexibility Options

2. RELOAD FUEL BUNDLES (1.0, 2.0, 3.3.1 and 4.0)

Fuel Type Cycle Loaded Number Number Drilled Irradiated 8DRB283 3 12 12 P8DRB265L 4 24 24 P8DRB283 4, 136 136 P8DRB284H 5 128 128 P8DRB299 5 60 60 New P8DRB299 6 200 200 Total 560 560

3. REFERENCE CORE LOADING PATTERN (3.3.1)

Nominal previous cycle core average exposure at end of cycle: 17232 mwd /st Minimum previous cycle core average exposure at end of cycle from cold shutdown considerations: 17050 mwd /st Assumed reload cycle core average exposure at end of cycle: 17509 mwd /st Core loading pattern: Figure 1 1

1

• ( ) Refers to area of discussion in " General Electric Standard Application for Reactor Fuel," NEDE-240ll-P-A-4, January 1982; a letter "S" preceding the number refers to the United States supplement.

1  ;

Y1003J01A56 Rev. 0

4. CALCULATED CORE EFFECTIVE MULTIPLICATION AND CONTROL SYSTEM WORTH - NO VOIDS, 20*C (3.3.2.1.1 and 3.3.2.1.2)

Beginning of Cycle K-effective Uncontrolled 1.112 Fully Controlled 0.957 Strongast Control Rod Out 0.989 R, Maximum Increase in Cold Core Reactivity with Exposure into Cycle, AK 0.000

5. STANDBY LIQUID CONTROL SYSTEM SHUTDOWN CAPABILITY (3.3.2.1.3)

Shutdown Margin (Ak) ppyg (20*C, Xenon Free) 600 0.026

6. RELOAD UNIQUE TRANSIENT ANALYSIS INPUT (3.3.2.1.5 and S.2.2)

(REDY EVENTS ONLY)

EOC-1000 EOC-2000 EOC mwd /st mwd /st Void Fraction (%) 41.7 41.7 41.7 Average Fuel Temperature (*F) 1271 1271 1271 Void Coefficient N/A* (c/% Rg) -9.19/-11.49 -9.99/-12.49 -10.37/-12.96 Doppler Coefficient N/A (c/"F) -0.234/-0.222 -0.229/-0.218 -0.224/-0.213 f Scram Worth N/A ($)

J

• N = Nuclear Input Data A = Used in Transient Analysis

• • Generic exposure independent values are used as given in " General Electric Standard Application for Reactor Fuel," NEDE-240ll-P-A-4, January 1982.

2

Y1003J01A56 Rev. 0

7. RELOAD UNIQUE GETAB TRANSIENT ANALYSIS INITIAL CONDITION PARAMETERS (S.2.2)

Fuel Peaking Factors R- Bundle Bundle Flow Initial Design Local Radial Axial Factor Power (MWt) (1000 lb/hr) MCPR Exposure: EOC 8x8R 1.20 1.45 1.40 1.051 6.193 116.8 1.31 P8x8R 1.20 1.42 1.40 1.051 6.059 117.7 1.34 Exposure: E0C-1000 mwd /st 8x8R 1.20 1.49 1.40 1.051 6.338 116.0 1.28 P8x8R 1.20 1.45 1.40 1.051 6.194 116.9 1.31 Exposure: EOC-2000 mwd /st 8x8R 1.20. 1.54 1.40 1.051 6.550 114.8 1.24 P8x8R 1.20 1.51 1.40 1.051 6.424 115.6 1.26

8. SELECTED MARGIN IMPROVEMENT OPTIONS (S.2.2.2)

Transient Recategorization: No Recirculation Pump Trip  : No Rod Withdrawal Limiter  : No Thermal Power Monitor  : Yes ODYN Option B Improved Scram Time  : Yes Exposure Dependent Limits : Yes Exposure Points Analyzed : EOC, E0C-1000 mwd /st, EOC-2000 mwd /st

9. CORE-WIDE TRANSIENT ANALYSIS RESULTS (S.2.2.1)

I Exposure Flux Q/A ACPR Transient (mwd /st) (% NBR) (% NBR) 8x8R P8x8R Figure l Load Rejection Without EOC 615 128 0.24 0.27 2a Bypass EOC-1000 550 125 0.21 0.24 2b EOC-2000 484 121 0.17 0.19 2c Loss of 80*F E0C 122 121 0.13 0.13 3 Feedwater Heating Feedwater Controller EOC 442 126 0.21 0.23 4a Failure EOC-1000 309 122 0.17 0.19 4b EOC-2000 248 118 0.13 0.14 4c 3

J1003J01A56 Rev. 0

10. LOCAL ROD WITHDRAWAL ERROR (WITH LIMITING INSTRUMENT FAILURE) TRANSIENT

SUMMARY

(S.2.2.1)

Limiting Rod Pattern: Figure 5 Includes 2.2% Power Spiking Penalty: Yes .

Rod Position Rod Block (ft ACPR MLHCR (kW/ft)

Reading withdrawn) 8x8R/P8x8R 8x8R/P8x8R 104 3.5 0.12 14.17 105 4.0 0.14 14.72 106 4.5 0.15 14.84 107 5.0 0.17 14.84 108 5.5 0.18 14.84 109 6.0 0.20 14.84 110 9.0 0.26 16.23 Set Point Selected: 108

11. CYCLE MCPR VALUES (S.2.2)

Non-Pressurization Events Exposure Range: BOC to EOC P8x8R 8x8R Loss of 80*F Feedwater Heating 1.20 1.20 Fuel Loading Error 1.20 --

l Rod Withdrawal Error 1.25 1.25 l

4

Y1003J01A56 Rev. O Pressurization Events Option A Option B P8x8R 8x8R P8x8R 8x8R Exposure Range:

BOC to E0C-2000 mwd /st Load Rejection Without Bypass 1.32 1.29 1.11 1.10 Feedwater Controller Failure 1.26 1.25 1.20 1.19 Exposure Range:

E0C-2000 mwd /st to EOC-1000 mwd /st Load Rejection Without Bypass 1.37 1.34 1.15 1.13 Feedwater Controller Failure 1.32 1.29 1.25 1.23 Exposure Range:

EOC-1000 mwd /st to EOC Load Rejection Without Bypass 1.40 1.37 1.'28 1.25 Feedwater Controller Failure 1.36 1.34 1.29 1.27

12. OVERPRESSURIZATION ANALYSIS

SUMMARY

(S.2.3) e si v Plant Transient (psig) (psig) Respcnse MSIV Closure (Flux Scram) 1218 1256 Figure 6

13. STABILITY ANALYSIS RESULT (S.2.4)

Rod Line Analyzed: Extrapolated Rod Block Decay Ratio: Figure 7 Reactor Core Stability Decay Ratio, x2/ *0 0.93 Channel Hydrodynamic Performance Decay Ratio, x2 /*0 Channel Type 8x8R/P8x8R 0.30 5

Y1003J01A56 Rev. 0

14. LOADING ERROR RESULTS (S.2.5.4)

Variable Water Cap Misoriented Bundle Analysis: Yes i

Event Initial CPR Resulting CPR Misoriented 1.18 1.07

15. CONTROL ROD DROP ANALYSIS LESULTS (S.2.5.1)

Bounding Analysis Results:

Doppler Reactivity Coefficient: Figure 8 Accident Reactivity Shape Functions: Figures 9 and 10 Scram Reactivity Functions: Figures 11 and 12 Plant Specific Analysis Results:

Parameter (s) not Bounded, Cold: Accident Reactivity Resultant Peak Enthalpy, Cold: 225.5 cal /gm Parameter (s) not Bounded, HSB : Accident Reactivity Resultant Peak Enthalpy, HSB : 272.2 cal /gm

16. LOSS-OF-COOLANT ACCIDENT RESULT (S.2.5.2)

See " Loss-of-Coolant Accident Analysis Report for James A. FitzPatrick Nuclear ,

Power Plant (Lead Plant)," July 1977, NEDO-21662 (as amended).

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! NOTES: 1. NUMBER INDICATES NUMBER OF NOTCHES WITHDRAWN OUT OF 48. BLANK IS A WITHDRAWN ROD

2. ERROR ROD IS (22,31).

Figure 5. Limiting RWE Rod Pattern 15

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Figure 7. Reactor Core Decay Ratio versus Power 17

Y1003J01A56 Rev. 0 0

-5

-10 g -1s

/

u

t 8

o

$ -20 )

-2s

-30 3

-3s

• CALCUL '.TED "'LUE COLO B CALCUL %TED VALUE-HSB C BOUND /AL 280 cal /G COLD D BOUND /AL 280 cal /G HSB (

-40 O 500 1000 1500 2000 2500 3000 FUEL TEMPERATURE (*Cl Figure 8. Doppler Reactivity Coefficient in 1/A 'C 18 1

Y1003J01A56 Rev. 0 l

20.0 17.5 ,

15.0

[ 12.5 00 0 2

2 10.0 0

5 m

7.5 5.0 v

)

2.5 ,

j A ACCIDENT FUNCTION B BOUNDING VALUE 280 CAL /G 0 ,,

0 5 10 15 20 ROD POSITION (feet out)

Figure 9. Accident Reactivity Shape Function, Cold Startup 19

Y1003J01A56 Rev. 0 20.0 17.5 15.0 o 12.5 n n n n

( u o o E

10.0 E

7.5 5.0 u 2.5 A ACCIDENT FlJNCTION B BOUNOING VdLUE 280 CAL /G j 0a 15 20 0 5 10 ROD POSITION (feet out)

Figure 10. Accident Reactivity Shape Function, Hot Standby 20

Y1003J01A56 Rev. 0 4o A SCRAM F JNCTION C BOUNDIN3 VALUE 281) CAL /G ,

35 I

f 25 e

n i ao s

b 2

U

!'5 10 b 5 -

0 l, l, --

3 0 1 2 3 4 5 6 ELAPSED TIME (seconds)

Figure 11. Scram Reactivity Function, Cold Startup 21

Y1003J01A56 Rev. 0 50 A SCRAM F JNCTION _

B BOUNDIN 3 VALUE 280 CAL /G 40 7 30 2

4 b

5 W

EN "

10 i

0 0" 1 2 3 4 5 6 ELAPSED TIME (seconds)

Figure 12. Scram Reactivity Function,llot Standby 22

Y1003J01A56 Rev. O e

APPENDIX A GETAB ANALYSIS INITIAL CONDITIONS

• I*

The values listed below were used in the GETAB analysis for this reload rather than the values given in Reference A-1, to more nearly reflect actual plant data.

Reactor Pressure (psia) 1035 Inlet Enthalpy (Btu /lb) 527.0 REFERENCE A-1. " General Electric Standard Application for Reactor Fuel,"

NEDE-24011-P-A-4, January 1982.

?

A-1/A-2

Y1003J01A56 Rev. 0 -

APPENDIX B VERIFICATION OF OPERATING FLEXIBILITY OPTIONS The following operating flexibility options have been developed for BWRs.

A "Yes" indicates that the option has been verified as being applicable to Cycle 6.

1. Single Loop Operation: Yes

2. Load Line Limit: Yes

3. Extended Load Line Limit: No

4. Increased Core Flow: No

5. Feedwater Temperature Reduction: No

)

/

B-1/B-2

GENER AL $ ELECTRIC f

/

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