Cycle 32 Core Operating Limits Report

ML24125A001
Person / Time
Site:	Arkansas Nuclear
Issue date:	05/04/2024
From:	Keele R Entergy Operations
To:	Office of Nuclear Reactor Regulation, Document Control Desk
References
1CAN052401
Download: ML24125A001 (1)
v • d • e

Text

) entergy 1CAN052401 May 4, 2024 ATTN: Document Control Desk U. S. Nuclear Regulatory Commission Washington, DC 20555-0001

Subject:

ANO-1 Cycle 32 Core Operating Limits Report Arkansas Nuclear One - Unit 1 NRC Docket No. 50-313 Renewed Facility Operating License No. DPR-51 Riley D. Keele, Jr.

Manager, Regulatory Assurance Arkansas Nuclear One Tel 479-858-7826 10 CFR 50.36 TS 5.6.5 Entergy Operations, Inc. (Entergy) Arkansas Nuclear One, Unit 1 (ANO-1) Technical Specification 5.6.5 requires the submittal of the Core Operating Limits Report (COLR) upon issuance for each reload cycle. Enclosed is the ANO-1 Cycle 32 COLR. Please note that the latest approved revision number of the Babcock and Wilcox Topical Report BAW-10179P-A is identified in the COLR as Revision 9, November 2017. In addition, the approved revision number of the Entergy Reactor Physics Methods Report is identified in the COLR as Revision 0, December 1993.

There are no new commitments contained in this submittal.

This completes the reporting requirement of the stated specification. Should you have any questions, please contact Riley Keele, Manager, Regulatory Assurance at 479-858-7826.

Re7f~lly,

• fr~~-

RDK/mar

Enclosure:

ANO-1 Cycle 32 Core Operating Limits Report (COLR)

Entergy Operations, Inc. 1448 SR 333, Russellville, AR 72802

1CAN052401 Page 2 of 2 cc:

NRC Region IV Regional Administrator NRC Senior Resident Inspector - Arkansas Nuclear One NRC Project Manager - Arkansas Nuclear One Designated Arkansas State Official

Enclosure 1CAN052401 ANO-1 Cycle 32 Core Operating Limits Report (COLR)

(31 pages)

CYCLE 32 COLR ANO-1 1

Revision 0 ENTERGY OPERATIONS ARKANSAS NUCLEAR ONE UNIT ONE CYCLE 32 CORE OPERATING LIMITS REPORT

CYCLE 32 COLR ANO-1 2

Revision 0 1.0 CORE OPERATING LIMITS This Core Operating Limits Report (COLR) for ANO-1 Cycle 32 has been prepared in accordance with the requirements of Technical Specification 5.6.5. The core operating limits have been developed using the methodology provided in the references.

The following cycle-specific core operating limits are included in this report:

1) 2.1.1.3 Variable Low RCS Pressure - Temperature Protective Limits

2) 3.1.1 SHUTDOWN MARGIN (SDM)

3) 3.1.8 PHYSICS TESTS Exceptions - MODE 1

4) 3.1.9 PHYSICS TEST Exceptions - MODE 2

5) 3.2.1 Regulating Rod Insertion Limits

6) 3.2.2 AXIAL POWER SHAPING RODS (APSR) Insertion Limits

7) 3.2.3 AXIAL POWER IMBALANCE Operating Limits

8) 3.2.4 QUADRANT POWER TILT (QPT)

9) 3.2.5 Power Peaking

10) 3.3.1 Reactor Protection System (RPS) Instrumentation

11) 3.4.1 RCS Pressure, Temperature, and Flow DNB Limits

12) 3.4.4 RCS Loops - MODES 1 and 2

13) 3.9.1 Boron Concentration

2.0 REFERENCES

1.

"Safety Criteria and Methodology for Acceptable Cycle Reload Analyses," BAW-10179P-A, Rev. 9, Framatome ANP, Inc., Lynchburg, Virginia, November 2017 2

"Qualification of Reactor Physics Methods for the Pressurized Water Reactors of the Entergy System," ENEAD-01-P, Rev. 0, Entergy Operations, Inc., Jackson, Mississippi, December 1993

3.

Framatome Document, "Transmittal of ANO-1 Cycle 32 Limits and Setpoints,"

FS1 0071311-1.0

4.

Framatome Document, "Transmittal of ANO-1 Cycle 32 Reload Report,"

FS1-0071734-2.0, CALC-ANO1-NE-23-00003

5.

Framatome Document, "Transmittal of ANO-1 Cycle 32 Core Loading Plan,"

FS1-0070205 1.0, CALC-ANO1-NE-23-00004

6.

"IC (Initial Condition) DNB RCS Protection Criteria," CALC-96-E-0023-02, Rev. 7

7.

Framatome Document, "Transmittal of ANO-1 Cycle 32 Reload Technical Document,"

FS1-0071775-1.0, CALC-ANO1-NE-23-00002

8.

Framatome Document, "Transmittal of ANO-1 Generic Reload Technical Document,"

FS1-0071774-1.0, CALC-ANO1-NE-23-00005

CYCLE 32 COLR ANO-1 3

Revision 0 Table Of Contents Page REACTOR CORE SAFETY LIMITS Fig. 1 Variable Low RCS Pressure-Temperature Protective Limits................................. 5 Fig. 2 AXIAL POWER IMBALANCE Protective Limits..................................................... 6 SHUTDOWN MARGIN (SDM)...................................................................................................... 7 REGULATING ROD INSERTION LIMITS Fig. 3-A Regulating Rod Insertion Limits for Four-Pump Operation From 0 to 200 +/- 10 EFPD...................................................................................... 8 Fig. 3-B Regulating Rod Insertion Limits for Four-Pump Operation From 200 +/- 10 EFPD to EOC............................................................................... 9 Fig. 4-A Regulating Rod Insertion Limits for Three-Pump Operation From 0 to 200 +/- 10 EFPD................................................................................... 10 Fig. 4-B Regulating Rod Insertion Limits for Three-Pump Operation From 200 +/- 10 EFPD to EOC............................................................................. 11 AXIAL POWER SHAPING RODS (APSR) INSERTION LIMITS............................................... 12 AXIAL POWER IMBALANCE OPERATING LIMITS Fig. 5-A1 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Four-Pump Operation from 0 EFPD to 200 +/- 10 EFPD...................................... 13 Fig. 5-A2 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Four-Pump Operation from 200 +/- 10 EFPD to EOC........................................... 14 Fig. 5-B1 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions for Four-Pump Operation from 0 EFPD to 200 +/- 10 EFPD................................. 15 Fig. 5-B2 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions for Four-Pump Operation from 200 +/- 10 EFPD to EOC...................................... 16 Fig. 5-C1 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Four-Pump Operation from 0 EFPD to 200 +/- 10 EFPD...................................... 17 Fig. 5-C2 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Four-Pump Operation from 200 +/- 10 EFPD to EOC........................................... 18 Fig. 6-A1 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Three-Pump Operation from 0 EFPD to 200 +/- 10 EFPD.................................... 19 Fig. 6-A2 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Three-Pump Operation from 200 +/- 10 EFPD to EOC......................................... 20 Fig. 6-B1 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions for Three-Pump Operation from 0 EFPD to 200 +/- 10 EFPD............................... 21 Fig. 6-B2 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions for Three-Pump Operation from 200 +/- 10 EFPD to EOC.................................... 22 Fig. 6-C1 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Three-Pump Operation from 0 EFPD to 200 +/- 10 EFPD.................................... 23

CYCLE 32 COLR ANO-1 4

Revision 0 Fig. 6-C2 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Three-Pump Operation from 200 +/- 10 EFPD to EOC......................................... 24 QUADRANT POWER TILT LIMITS AND SETPOINTS............................................................. 25 POWER PEAKING FACTORS Fig. 7A LOCA Linear Heat Rate Limits for Mark-B-HTP Fuel.......................................... 26 Fig. 7B DNB Power Peaking Factors............................................................................... 27 REACTOR PROTECTION SYSTEM (RPS) INSTRUMENTATION Fig. 8 RPS Maximum Allowable Setpoints for Axial Power Imbalance......................... 28 Fig. 9 RPS Variable Low Pressure Temperature Envelope Setpoints.......................... 29 RCS PRESSURE, TEMPERATURE, AND FLOW DNB SURVEILLANCE LIMITS.................. 30 RCS LOOPS MODE 1 AND 2.................................................................................................... 31 REFUELING BORON CONCENTRATION................................................................................ 31

CYCLE 32 COLR ANO-1 5

Revision 0 FIGURE 1 Variable Low RCS Pressure - Temperature Protective Limits (Figure is referred to by Technical Specification 2.1.1.3)

PUMPS OPERATING (TYPE OF LIMIT)

GPM*

POWER**

FOUR PUMPS (DNBR LIMIT) 383,680 (100%)

110%

THREE PUMPS (DNBR LIMIT) 284,307 (74.1%)

89%

109% OF DESIGN FLOW (2.5% UNCERTAINTY INCLUDED IN STATISTICAL DESIGN LIMIT)

• • AN ADDITIONAL 2% POWER UNCERTAINTY IS INCLUDED IN STATISTICAL DESIGN LIMIT

CYCLE 32 COLR ANO-1 6

Revision 0 Figure 2 AXIAL POWER IMBALANCE Protective Limits (measurement system independent)

(Figure is referred to by Technical Specification 2.1.1 Bases)

CYCLE 32 COLR ANO-1 7

Revision 0 SHUTDOWN MARGIN (SDM)

(Limits are referred to by Technical Specifications 3.1.1, 3.1.4, 3.1.5, 3.1.8, 3.1.9, and 3.3.9)

Verify SHUTDOWN MARGIN per the table below.

APPLICABILITY REQUIRED SHUTDOWN MARGIN TECHNICAL SPECIFICATION REFERENCE MODE 1*

1 %k/k 3.1.4, 3.1.5 MODE 2*

1 %k/k 3.1.4, 3.1.5, 3.3.9 MODE 3 1 %k/k 3.1.1, 3.3.9 MODE 4 1 %k/k 3.1.1, 3.3.9 MODE 5 1 %k/k 3.1.1, 3.3.9 MODE 1 PHYSICS TESTS Exceptions**

1 %k/k 3.1.8 MODE 2 PHYSICS TESTS Exceptions 1 %k/k 3.1.9

• The required Shutdown Margin capability of 1 %k/k in MODE 1 and MODE 2 is preserved by the Regulating Rod Insertion Limits specified in Figures 3-A&B, and 4-A&B, as required by Technical Specification 3.2.1.

• • Entry into Mode 1 Physics Tests Exceptions is not supported by existing analyses and as such requires actual shutdown margin to be 1 %k/k.

CYCLE 32 COLR ANO-1 8

Revision 0 Figure 3-A Regulating Rod Insertion Limits for Four-Pump Operation From 0 to 200 +/- 10 EFPD (Figure is referred to by Technical Specification 3.2.1)

Operating rod group overlap in the above figure is 20% +/- 5% between two sequential groups, except for physics tests.

CYCLE 32 COLR ANO-1 9

Revision 0 Figure 3-B Regulating Rod Insertion Limits for Four-Pump Operation From 200 +/- 10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.1)

Operating rod group overlap of Groups 5, 6, 7 in the above figure is 20% +/- 5% between two sequential groups, except for physics tests.

CYCLE 32 COLR ANO-1 10 Revision 0 Figure 4-A Regulating Rod Insertion Limits for Three-Pump Operation From 0 to 200 +/- 10 EFPD (Figure is referred to by Technical Specification 3.2.1)

Operating rod group overlap of Groups 5, 6, 7 in the above figure is 20% +/- 5% between two sequential groups, except for physics tests.

CYCLE 32 COLR ANO-1 11 Revision 0 Figure 4-B Regulating Rod Insertion Limits for Three-Pump Operation From 200 +/- 10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.1)

Operating rod group overlap of Groups 5, 6, 7 in the above figure is 20% +/- 5% between two sequential groups, except for physics tests.

CYCLE 32 COLR ANO-1 12 Revision 0 AXIAL POWER SHAPING RODS (APSR) INSERTION LIMITS (Limits are referred to by Technical Specification 3.2.2)

Up to 458 +/- 10 EFPD, the APSRs may be positioned as necessary for transient imbalance control; however, the APSRs shall be fully withdrawn by 468 EFPD. After the APSRs withdrawal at 458 +/- 10 EFPD, the APSRs shall not be reinserted, except during the end-of-cycle shutdown when the reactor power is equal to, or less than, 30 % FP.

CYCLE 32 COLR ANO-1 13 Revision 0 Figure 5-A1 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Four-Pump Operation from 0 EFPD to 200 +10/-10 EFPD (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 14 Revision 0 Figure 5-A2 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Four-Pump Operation from 200 +10/-10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 15 Revision 0 Figure 5-B1 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions* for Four-Pump Operation from 0 EFPD to 200 +10/-10 EFPD (Figure is referred to by Technical Specification 3.2.3)

• Assumes that no individual long emitter detector affecting the minimum incore imbalance calculation exceeds 73% sensitivity depletion. The imbalance setpoints for the minimum incore system must be reduced to 2.8% FP at the earliest time-in-life this assumption is no longer valid.

CYCLE 32 COLR ANO-1 16 Revision 0 Figure 5-B2 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions* for Four-Pump Operation from 200 +10/-10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.3)

• Assumes that no individual long emitter detector affecting the minimum incore imbalance calculation exceeds 73% sensitivity depletion. The imbalance setpoints for the minimum incore system must be reduced to 2.8% FP at the earliest time-in-life this assumption is no longer valid.

CYCLE 32 COLR ANO-1 17 Revision 0 Figure 5-C1 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Four-Pump Operation from 0 EFPD to 200 +10/-10 EFPD (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 18 Revision 0 Figure 5-C2 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Four-Pump Operation from 200 +10/-10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 19 Revision 0 Figure 6-A1 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Three-Pump Operation from 0 EFPD to 200 +10/-10 EFPD (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 20 Revision 0 Figure 6-A2 AXIAL POWER IMBALANCE Setpoints for Full In-Core Conditions for Three-Pump Operation from 200 +10/-10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 21 Revision 0 Figure 6-B1 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions* for Three-Pump Operation from 0 EFPD to 200 +10/-10 EFPD (Figure is referred to by Technical Specification 3.2.3)

• Assumes that no individual long emitter detector affecting the minimum incore imbalance calculation exceeds 73% sensitivity depletion. The imbalance setpoints for the minimum incore system must be reduced to 2.8% FP at the earliest time-in-life this assumption is no longer valid.

CYCLE 32 COLR ANO-1 22 Revision 0 Figure 6-B2 AXIAL POWER IMBALANCE Setpoints for Minimum In-Core Conditions* for Three-Pump Operation from 200 +10/-10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.3)

• Assumes that no individual long emitter detector affecting the minimum incore imbalance calculation exceeds 73% sensitivity depletion. The imbalance setpoints for the minimum incore system must be reduced to 2.8% FP at the earliest time-in-life this assumption is no longer valid.

CYCLE 32 COLR ANO-1 23 Revision 0 Figure 6-C1 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Three-Pump Operation from 0 EFPD to 200 +10/-10 EFPD (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 24 Revision 0 Figure 6-C2 AXIAL POWER IMBALANCE Setpoints for Ex-Core Conditions for Three-Pump Operation from 200 +10/-10 EFPD to EOC (Figure is referred to by Technical Specification 3.2.3)

CYCLE 32 COLR ANO-1 25 Revision 0 Quadrant Power Tilt Limits And Setpoints (Limits are referred to by Technical Specification 3.2.4)

From 0 EFPD to EOC Measurement System Steady State Value (%)

Maximum Value (%)

60 % FP

> 60 % FP Full In-core Detector System Setpoint 6.83 4.44 25.00 Minimum In-core Detector System Setpoint 2.78*

1.90*

25.00 Ex-core Power Range NI Channel Setpoint 4.05 1.96 25.00 Measurement System Independent Limit 7.50 4.92 25.00

• Assumes that no individual long emitter detector affecting the minimum in-core tilt calculation exceeds 73% sensitivity depletion. The setpoint must be reduced to 1.50% (power levels

> 60% FP) and to 2.19% (power levels 60% FP) at the earliest time-in-life that this assumption is no longer valid.

CYCLE 32 COLR ANO-1 26 Revision 0 Figure 7A LOCA Linear Heat Rate Limits for Mark-B-HTP Fuel (Figure is referred to by Technical Specification 3.1.8 and 3.2.5)

Allowable LOCA LHR Limits Core Elevation, ft LHR Limit for 0 MWd/mtU, kW/ft LHR Limit for 28,000 MWd/mtU, kW/ft LHR Limit for 62,000 MWd/mtU, kW/ft 0.000 16.60 16.60 12.30 2.506 17.50 17.50 13.00 4.264 17.50 17.50 13.00 6.021 17.30 17.30 13.00 7.779 17.50 17.50 13.00 9.536 17.30 17.30 13.00 11.000 15.30 15.30 12.50 12.000 14.50 14.50 12.30 Note:

The LOCA LHR limits may be linearly interpolated as a function of burnup between 0 MWd/mtU and 28,000 MWd/mtU, between 28,000 MWd/mtU and 62,000 MWd/mtU, and as a function of core elevation.

CYCLE 32 COLR ANO-1 27 Revision 0 Figure 7B DNB Power Peaking Factors (Limits are referred to by Technical Specification 3.1.8 and 3.2.5)

The following total power peaking factors define the Maximum Allowable Peaking (MAP) limits to protect the initial conditions assumed in the DNB Loss of Flow transient analysis. The total power peaking factors for IC-DNB 4-pump and 3-pump are identical; hence one set of IC-DNB values are provided for both 4-pump and 3-pump operation.

IC-DNB Total Power Peaking Factors Mark-B-HTP Axial Peak x/L IC MAP Limits Axial Peak x/L IC MAP Limits Axial Peak x/L IC MAP Limits 1.1 0.01 2.04426 1.4 0.01 2.94000 1.7 0.01 3.20469 0.14 2.04515 0.14 2.94000 0.14 3.20469 0.20 2.04535 0.20 2.93545 0.20 3.15423 0.30 2.04551 0.30 2.84715 0.30 3.08083 0.40 2.04470 0.40 2.76077 0.40 2.98064 0.50 2.04437 0.50 2.66671 0.50 2.89369 0.60 2.04415 0.60 2.55808 0.60 2.78037 0.70 2.04400 0.70 2.46508 0.70 2.68552 0.80 2.04329 0.80 2.34973 0.80 2.56207 0.89 2.00109 0.89 2.27714 0.89 2.49021 0.99 1.90427 0.99 2.18525 0.99 2.39515 1.2 0.01 2.33088 1.5 0.01 3.08066 1.8 0.01 3.24949 0.14 2.33287 0.14 3.08066 0.14 3.24949 0.20 2.33339 0.20 3.03513 0.20 3.20303 0.30 2.33352 0.30 2.93856 0.30 3.13047 0.40 2.33338 0.40 2.84115 0.40 3.04037 0.50 2.33285 0.50 2.75216 0.50 2.95027 0.60 2.33232 0.60 2.63946 0.60 2.84225 0.70 2.26721 0.70 2.54429 0.70 2.74696 0.80 2.16931 0.80 2.42655 0.80 2.62489 0.89 2.10460 0.89 2.35382 0.89 2.55373 0.99 2.00767 0.99 2.26040 0.99 2.45882 1.3 0.01 2.64464 1.6 0.01 3.14861 1.9 0.01 3.28611 0.14 2.64863 0.14 3.14861 0.14 3.28611 0.20 2.64909 0.20 3.09918 0.20 3.24461 0.30 2.64997 0.30 3.01573 0.30 3.17163 0.40 2.64949 0.40 2.91490 0.40 3.08589 0.50 2.56272 0.50 2.82718 0.50 3.00025 0.60 2.46600 0.60 2.71210 0.60 2.89826 0.70 2.37484 0.70 2.61653 0.70 2.80288 0.80 2.26452 0.80 2.49634 0.80 2.68386 0.89 2.19471 0.89 2.42370 0.89 2.61261 0.99 2.09988 0.99 2.32955 0.99 2.51792 Notes

1. The values above are not error corrected.

2. The values above were generated using SCD methods which incorporate a 3.8% radial peak uncertainty in the DNBR design limit. Therefore, the above IC MAP limits can be compared to predicted peaks without the addition of up to 3.8% in radial peak calculation uncertainty. These limits, however, do not incorporate any grid bias uncertainty.

3. The present T-H methodology allows for an increase in the design radial-local peak for power levels below 100% full power.

The equations defining the multipliers are as follows:

P/Pm = 1.00 P/Pm < 1.00 MAP Multiplier 1.0 1 + 0.3(1 - P/Pm)

Where P

=

core power fraction, and Pm =

1.00 for 4-pump operation, or

=

0.75 for 3-pump operation

CYCLE 32 COLR ANO-1 28 Revision 0 Figure 8 Reactor Protection System Maximum Allowable Setpoints for Axial Power Imbalance (Figure is referred to by Technical Specification 3.3.1 and Technical Specification Bases 2.1.1)

Flux / Flow Setpoint

(% Power / % Flow)

Four Pump Operation 1.07 Three Pump Operation 1.07

CYCLE 32 COLR ANO-1 29 Revision 0 Figure 9 Reactor Protection System Variable Low Pressure Temperature Envelope Setpoints (Figure is referred to by Technical Specification 3.3.1)

CYCLE 32 COLR ANO-1 30 Revision 0 RCS Pressure, Temperature, and Flow DNB Surveillance Limits (Limit is referred to by Technical Specification 3.4.1)

Four-Pump Operation Three-Pump Operation Minimum RCS Hot Leg Pressure (psig) Note 1 2082.2 2081.2 Note 4 2120.4 Note 5 Maximum RCS Hot Leg Temperature (°F) Note 2 602.6 602.9 Minimum RCS Total Flow (Mlbm/hr) Note 3 143.36 Note 6 138.01 Note 8 106.46 Note 7 102.45 Note 8 Note 1 -- Using individual indications P1021, P1023, P1038 and P1039 (or equivalent) from the plant computer.

Note 2 -- Using individual indications T1011NR, T1014NR, T1039NR, T1042NR, T1012, T1013, T1040 and T1041 or averages TOUTA, XTOUTA, TOUTB, XTOUTB, TOUT, XTOUT from the plant computer.

Note 3 -- Using indication WRCFT (or equivalent) from the plant computer, and can be linearly interpolated between these values provided the Tave versus Power level curve is followed.

Note 4 -- Applies to the RCS loop with two RCPs operating.

Note 5 -- Applies to the RCS loop with one RCP operating.

Note 6 -- For Tcold = 556.57 °F.

Note 7 -- For Tcold = 556.3 °F.

Note 8 -- For Tcold = 580 °F.

CYCLE 32 COLR ANO-1 31 Revision 0 RCS Loops - Mode 1 and Mode 2 (Limit is referred to by Technical Specification 3.4.4)

Nominal Operating Power Level

(% Power)

Four Pump Operation 100 Three Pump Operation 75 Refueling Boron Concentration (Limit is referred to by Technical Specification 3.9.1)

The minimum required boron concentration (which includes uncertainties) for use during refueling as a function of the End of Cycle 31 (EOC-31) EFPD is:

EOC-31 EFPD Refueling Boron (ppm)1 441 2329 444 2323 447 2317 450 2311 453 2305 456 2299 459 2293 462 2287 465 2281 468 2275 471 2269 474 2266 477 2263 480 2260 481 2259 1The Refueling Boron may be linearly interpolated as a function of EOC-31 EFPD between 441 and 481 EFPD.