Core Operating Limits Report for Unit 1, Cycle 24, Revision 1, and Unit 2, Cycle 22, Revision 1

ML18292A640
Person / Time
Site:	Calvert Cliffs
Issue date:	10/17/2018
From:	Laura Smith Exelon Generation Co
To:	Document Control Desk, Office of Nuclear Reactor Regulation
References
TS 5.6.5
Download: ML18292A640 (46)
v • d • e

Text

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~ Exelon Generation Larry D. Smith Regulatory Assurance Manager Calvert Cliffs Nuclear Power Plant 1650 Calvert Cliffs Parkway Lusby, MD 20657 410 495 5219 Office 410 610 9729 Mobile www.exeloncorp.com larry.smith2@exeloncorp.com TS 5.6.5 October 17, 2018 U.S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, DC 20555 Calvert Cliffs Nuclear Power Plant, Unit Nos. 1 and 2 Renewed Facility Operating License Nos. DPR-53 and DPR-69 NRG Docket Nos. 50-317 and 50-318

Subject:

Core Operating Limits Report for Unit 1, Cycle 24, Revision 1 and Unit 2, Cycle 22, Revision 1 Pursuant to Calvert Cliffs Nuclear Power Plant Technical Specification 5.6.5, the attached Core Operating Limits Reports for Unit 1 (Attachment 1) and Unit 2 (Attachment 2) are provided for your records.

There are no regulatory commitments contained in this correspondence.

Should you have questions regarding this matter, please <;:ontact me at (410) 495-5219.

Respectfully,

~~

for Larry D. Smith Regulatory Assurance Manager LDS/PSF/bjm

Attachment:

(1) Core Operating Limits Report for Unit 1, Cycle 24, Revision 1 (2) Core Operating Limits Report for Unit 2, Cycle 22, Revision 1

Document Control Desk October 17, 2018 Page2 cc: Resident Inspector, NRG (Without Attachment)

NRG Project Manager, Calvert Cliffs NRG Regional Administrator, Region I S. Gray, MD-DNR

ATTACHMENT (1)

CORE OPERATING LIMITS REPORT FOR UNIT 1, CYCLE 24, REVISION 1 Calvert Cliffs Nuclear Power Plant October 17, 2018

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Calvert Cliffs Nuclear Power Plant Core Operating Limits Report COLR Unit 1 Cycle 24 Revision 1 Effective Date: 10/10/2018

-rr~6-+l-., Sc.h4.a.c-e, ~.&4a. ~ 10/2.)2018 Responsible Engineer / Date KT~~ O\oj * ~ 10/3/,-ofk Independent Reviewer / Date Digitally signed by Nicholas Cahtll ON: cn=Nicholas Cahill, o=Exelon Generation, ou=Operations, email=nicholas.cahill@exeloncorp.com, c=US Date:201S.10D314:22:15--04'00' Station Qualified Reviewer / Date e-o~Mf\e &nvtelU"' /J;~ ~ /0/4/Jg Sr. Manager - PWR Core Design / Date Calvert Cliffs 1, Cycle 24 COLR Page 1 of21 Rev.I

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CORE OPERATING LIMITS REPORT CALVERT CLIFFS UNIT 1, CYCLE 24 The following limits are included in this Core Operating Limits Report:

Specification Title Introduction ................................................................................................................. 4 Definitions .................................................................................................................. 5 Licensing Restrictions ................................................................................................. 6 3 .1. 1 Shutdown Margin (SOM) ........................................................................................... 8 3.1.3 Moderator Temperature Coefficient (MTC) ............................................................... 8 3 .1.4 Control Element Assembly (CEA) Alignment .......................................................... 8 3.1.6 Regulating Control Element Assembly (CEA) Insertion Limits ................................ 8 3 .2.1 Linear Heat Rate (LHR) .............................................................................................. 8 3.2.3 Total Integrated Radial Peaking Factor (F/) .............................................................. 9 3 .2.5 Axial Shape Index (ASI) ............................................................................................. 9 3 .3 .1 Reactor Protective System (RPS) Instrumentation - Operating .................................. 9 3.4.1 RCS Pressure, Temperature, and Flow DNB Limits ............................................. :.... 9 3 .9 .1 Boron Concentration ................................................................................................. 10 List of Approved Methodologies .............................................................................. 19 The following figures are included in this Core Operating Limits Report:

Number Figure 3.1.6 CEA Group Insertion Limits vs. Fraction of Rated Thermal Power ......................... 11 Figure 3.2.1-1 Allowable Peak Linear Heat Rate vs. Time in Cycle ............................................... 12 Figure 3.2.1-2 Linear Heat Rate Axial Flux Offset Control Limits ................................................. 13 Figure 3.2.3 Total Integrated Radial Peaking Factor (FrT) vs.

Allowable Fraction of Rated Thermal Power ........................................................... 14 Figure 3.2.5 DNB Axial Flux Offset Control Limits .................................................................... 15 Figure 3.3.1-1 Axial Power Distribution - High Trip Setpoint Peripheral Axial Shape Index vs. Fraction of Rated Thermal Power ............................................................. 16 Figure 3.3.1-2 Thermal Margin/Low Pressure Trip Setpoint- Part 1 .............................................. 17 Figure 3.3.1-3 Thermal Margin/Low Pressure Trip Setpoint - Part 2 .............................................. 18 Calvert Cliffs 1, Cycle 24 COLR Page 2 of21 Rev.I

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UNITl CORE OPERATING LIMITS REPORT LIST OF EFFECTIVE PAGES Page No. Rev.No.

1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 1 9 1 10 1 11 1 12 1 13 1 14 1 15 1 16 1 17 1 18 1 19 1 20 1 21 1 Calvert Cliffs 1, Cycle 24 COLR Page 3 of21 Rev.I

INTRODUCTION This report provides the cycle-specific limits for operation of Calvert Cliffs Unit 1, Cycle 24. It contains the limits for:

Shutdown Margin (SDM)

Moderator Temperature Coefficient (MTC)

Control Element Assembly (CEA) Alignment Regulating Control Element Assembly (CEA) Insertion Limits Linear Heat Rate (LHR)

Total Integrated Radial Peaking Factor (F/)

Axial Shape Index (ASI)

Reactor Protective System (RPS) Instrumentation - Operating RCS Pressure, Temperature, and Flow Departure from Nucleate Boiling (DNB) Limits Boron Concentration In addition, this report contains a number of figures which give limits on the parameters listed above. If any of the limits contained in this report are exceeded, corrective action will be taken as defined in the Technical Specifications.

This report has been prepared in accordance with the requirements of Technical Specifications.

The cycle specific limits have been developed using the NRC-approved methodologies given in the "List of Approved Methodologies" section of this report and in the Technical Specifications.

COLR Revision 0 Initial release of the Unit 1 Cycle 24 (U1C24) COLR. U1C24 may operate in all plant modes.

COLR Revision 1 Mid-Cycle implementation oflatest NRC approved version of Reference 9 (PWR Small Break LOCA Evaluation Model, S-RELAP5 Based) per ECP-18-000354 and ECP-18-000503.

Calvert Cliffs continues to comply with Licensing Restriction #4.

Calvert Cliffs 1, Cycle 24 COLR Page 4 of21 Rev.1

DEFINITIONS Axial Shape Index (ASI)

ASI shall be the power generated in the lower half of the core less the power generated in the upper half of the core, divided by the sum of the power generated in the lower and upper halves of the core.

ASI = lower - upper = y E lower+ upper The Axial Shape Index (Yr) used for the trip and pretrip signals in the Reactor Protection System (RPS) is the above value (YE) modified by an appropriate multiplier (A) and a constant (B) to determine the true core axial power distribution for that channel.

Total Integrated Radial Peaking Factor - FrT The Total Integrated Radial Peaking Factor is the ratio of the peak pin power to the average pin power in an umodded core.

Calvert Cliffs 1, Cycle 24 COLR Page 5 of21 Rev.I

LICENSING RESTRICTIONS

1) For the Asymmetric Steam Generator Transient analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.8, the methodology shall be revised to capture the asymmetric core inlet temperature distribution and application of local peaking augmentation factors. The revised methodology shall be applied to Calvert Cliffs Unit 1 core reload designs starting with Cycle 21.

2) For the Seized Rotor Event analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.8, the methodology shall be revised to capture the asymmetric core inlet flow distribution. The revised methodology shall be applied to Calvert Cliffs Unit 1 core reload designs starting with Cycle 21.

3) For the Control Element Assembly Ejection analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.l 1, the cycle-specific hot zero power peak average radial fuel enthalpy is calculated based on a modified power dependent insertion limit with Control Element Assembly Bank 3 assumed to be fully inserted (only in the analysis, not in actual plant operations). This revised methodology shall be applied to Calvert Cliffs Unit 1 core reload designs starting with Cycle 21.

4) The Small Break Loss of Coolant accident performed in accordance with the methodology of Technical Specification 5.6.5.b.9 shall be analyzed using a break spectrum with augmented detail related to break size. This revised methodology shall be applied to Calvert Cliffs Unit 1 core reload designs starting with Cycle 21.

5) Core Operating Limits Report Figures 3.1.6, 3.2.3, and 3.2.5 shall not be changed without prior NRC review and approval until an NRC-accepted generic, or Calvert Cliffs-specific, basis is developed for analyzing the Control Element Assembly Rod Bank Withdrawal Event, the Control Element Assembly Drop, and the Control Element Assembly Ejection (power level-sensitive transients) at full power conditions only.

6) Approval of the use of S-RELAP5 (Technical Specification 5.6.5.b.8) is restricted only to those safety analyses that confirm acceptable transient performance relative to the specified acceptable fuel design limits. Prior transient specific NRC approval is required to analyze transient performance relative to reactor coolant pressure boundary integrity until NRC-approval is obtained for a generic or Calvert Cliffs-specific basis for the use of the methodology in Technical Specification 5.6.5.b.8 to demonstrate reactor coolant pressure boundary integrity.

NOTE: The NRC has issued a letter that allows S-RELAP5 to be used for the transient-specific application of the methodology to CCNPP only as described in the letter pertaining to PSV setpoints. It is not a generic approval of the methodology.

Ref: Letter from Alexander N. Chereskin (NRC) to Bryan C. Hanson (Exelon) dated December 30, 2015, Calvert Cliffs Nuclear Power Plant, Unit Nos. I and 2 -

Issuance of Amendment Re: Revision to Pressurizer Safety Valve Technical Specifications (CAC Nos. MF3541 and MF3542)

Calvert Cliffs 1, Cycle 24 COLR Page 6 of21 Rev.I

7) For the RODEX2-based fuel thermal-mechanical design analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.3, Calvert Cliffs Unit 1 core reload designs (starting with Cycle 21) shall satisfy the following criteria:

a. Predicted rod internal pressure shall remain below the steady state system pressure.

b. The linear heat generation rate fuel centerline melting safety limit shall remain below 21.0 KW/ft.

8) For the Control Element Assembly Ejection analysis, Calvert Cliffs Unit 1 core reloads (starting with Cycle 21) shall satisfy the following criteria:

a. Predicted peak radial average fuel enthalpy when calculated in accordance with the methodology of Technical Specification 5.6.5.b.l 1 shall remain below 200 cal/g.

b. For the purpose of evaluating radiological consequences, should the S-RELAP5 hot spot model predict fuel temperature above incipient centerline melt conditions when calculated in accordance with the methodology of Technical Specification 5.6.5.b.8, a conservative radiological source term (in accordance with Regulatory Guide 1.183, Revision 0) shall be applied to the portion of fuel beyond incipient melt conditions (and combined with existing gap source term), and cladding failure shall be presumed.

9) The approval of the emergency core cooling system evaluation performed in accordance with the methodology of Technical Specification 5.6.5.b.7 shall be valid only for Calvert Cliffs Unit 1, Cycle 21. To remove this condition, Calvert Cliffs shall obtain NRC approval of the analysis of once- and twice-burned fuel for core designs following Unit 1 Cycle 21.

NOTE: The revised methodology was submitted and received NRC approval in December 2012. This license condition is satisfied; however since NRC approval was obtained via letter and notLAR, this license condition is still listed in Appendix C of the Tech. Specs. and has been retained here for consistency.

Ref: Letter from Douglas V. Pickett (NRC) to George H. Gellrich (CCNPP) dated February 18, 2011, Calvert Cliffs Nuclear Power Plant, Unit Nos. 1 and 2 -

Amendment Re: Transition from Westinghouse Nuclear Fuel to AREY A Nuclear Fuel (TAC Nos. ME283 l and ME2832)

Calvert Cliffs 1, Cycle 24 COLR Page 7 of21 Rev.I

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CYCLE SPECIFIC LIMITS FOR UNIT 1, CYCLE 24 3.1.1 Shutdown Margin (SDM) (SR 3.1.1.1)

Tavg > 200 °P - Modes 3 and 4:

The shutdown margin shall be 2:': 3 .5% ~p.

Tavg ~ 200 °P - Mode 5:

The shutdown margin shall be 2:': 3 .0% ~p.

3.1.3 Moderator Temperature Coefficient (MTC) (SR 3.1.3.2)

The Moderator Temperature Coefficient (MTC) shall be less negative than -3 .1 x 10-4 ~p/°F at rated thermal power.

3.1.4 Control Element Assembly (CEA) Alignment (Action 3.1.4.B.1)

The allowable time to realign a CEA is 120 minutes when the pre-misaligned F/ is :S 1.65 and zero (0) minutes when the pre-misaligned F/ is> 1.65.

The pre-misaligned F/ value used to determine the allowable time to realign the CEA shall be the latest measurement taken within 5 days prior to the CEA misalignment. If no measurements have been taken within 5 days prior to the misalignment and the full core power distribution monitoring system is unavailable then the time to realign is zero (0) minutes.

3.1.6 Regulating Control Element Assembly (CEA) Insertion Limits (SR 3.1.6.1 and SR 3.1.6.2)

The regulating CEA groups insertion limits are shown on COLR Figure 3 .1.6.

Figure 3 .1.6 will not be changed unless the requirements in Licensing Restriction 5 are met.

3.2.1 Linear Heat Rate (LHR) (SR 3.2.1.2 and SR 3.2.1.4)

The linear heat rate shall not exceed the limits shown on COLR Figure 3 .2.1-1.

The axial shape index power dependent control limits are given in COLR Figure 3 .2.1-2.

When using the excore detector monitoring system (SR 3 .2.1.2):

The alarm setpoints are equal to or less than the ASI limits; therefore when the alarms are adjusted, they provide indication to the operator that ASI is not within the limits.

The axial shape index alarm setpoints are shown as a function of fraction of thermal power on COLR Figure 3 .2.1-2.

Calvert Cliffs 1, Cycle 24 COLR Page 8 of21 Rev.I

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When using the incore detector monitoring system (SR 3.2.1.4):

The alarm setpoints are adjusted to protect the Linear Heat Rate limits shown on COLR Figure 3 .2.1-1 and uncertainty factors are appropriately included in the setting of these alarms.

The uncertainty factors for the incore detector monitoring system are:

1. A measurement-calculational uncertainty factor of 1.07

2. An engineering uncertainty factor of 1.03, 3.a For measured thermal power less than or equal to 50 percent but greater than 20 percent of rated full core power a thermal power measurement uncertainty factor of 1.035.

3.b For measured thermal power greater than 50 percent of rated full core power a thermal power measurement uncertainty factor of 1.020.

3.2.3 Total Integrated Radial Peaking Factor (F ?) (SR 3.2.3.1)

The calculated value of F/ shall be limited to :S 1.65.

If the calculated F/ exceeds the above limit, the allowable combinations of thermal power, CEA position, and F/ are shown on COLR Figure 3.2.3.

Figure 3 .2.3 will not be changed unless the requirements in Licensing Restriction 5 are met.

3.2.5 Axial Shape Index (ASI) (SR 3.2.5.1)

The axial shape index and thermal power shall be maintained equal to or less than the limits of COLR Figure 3 .2.5 for CEA insertions specified by COLR Figure 3 .1.6.

Figure 3.2.5 will not be changed unless the requirements in Licensing Restriction 5 are met.

3.3.1 Reactor Protective System (RPS) Instrumentation - Operating (Reactor Trip Setpoints) (TS Table 3.3.1-1)

The Axial Power Distribution - High trip setpoint and allowable values are given in COLR Figure 3.3.1-1.

The Thermal Margin/Low Pressure (TM/LP) trip setpoint is given in COLR Figures 3.3.1-2 and 3 .3 .1-3. The allowable values are to be not less than the larger of (1) 1875 psia or (2) the.

value calculated from COLR Figures 3.3.1-2 and 3.3.1-3.

3.4.1 RCS Pressure, Temperature, and Flow Departure from Nucleate Boiling (DNB) Limits The RCS DNB parameters for pressurizer pressure, cold leg temperature, and RCS total flow rate shall be within the limits specified below:

a. Pressurizer pressure ~ 2200 psia;

b. RCS cold leg temperature (Tc) :S 548°F; and

c. RCS total flow rate ~ 370,000 gpm.

Calvert Cliffs 1, Cycle 24 COLR Page 9 of21 Rev.I

3.9.1 Boron Concentration (SR 3.9.1.1)

The refueling boron concentration will maintain the keff at 0.95 or less (including a 1% ~k/k conservative allowance for uncertainties). The refueling boron concentration shall be maintained uniform. For Mode 6 operation the RCS temperature must be maintained

_::: 140°F.

U1C24 Refueling Boron Concentration Limits

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U 1C24 Cycle Average Exposure 0 GWD/MTU O GWD/MTU 2: 16 GWD/MTU 24 Number of Credited CEAs 0 0 (Note 1)

Post-Refueling UGS or RV Head Lift Height No Restriction S 12 inches No Restriction Restrictions.

Minimum Required Refueling Boron Concentration:

This number includes:

• Chemistry Sampling Uncertainty

~ 2560 ppm ~ 2412 ppm ~ 2560 ppm

• Boron-IO Depletion Allowance

• Margin for dilution of refueling pool between low and high level alarms (Note,2)

• Unlimited number of temporary rotations of fuel assemblies

• Extra Conservatism for empty locations during refueling operations.

Note: (1) The Core Loading Plan (latest revision ofNFl 73129) details the specific required credited CEAs.

(2) This value applies to the core offload at the end ofUlC24. It contains significant margin to ensure that the RCS will not need to be borated (when no RCPs are running) prior to loading new fuel for Ul C25.

Calvert Cliffs 1, Cycle 24 COLR Page 10 of 21 Rev.I

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Per Tech Spec Bases 3.1.5 and 3.1.6, CEAs are considered to be fully withdrawn at 129 inches.

Figure 3.1.6 CEA Group Insertion Limits vs. Fraction of Rated Thermal Power This figure cannot be changed without prior NRC approval.

Calvert Cliffs 1, Cycle 24 COLR Page 11 of 21 Rev.I

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(LCO Limits are not needed below 20% thermal'power per SE00433)

(See NEOP-13 for Operational Limits)

Calvert Cliffs 1, Cycle 24 COLR Page 13 of21 Rev.I

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Allowable Fraction of Rated Thermal Power While operating with F? greater than 1.65, withdraw CEAs to or above the Long Term Steady State Insertion Limits (Figure 3.1.6)

This figure cannot be changed without prior NRC approval.

Calvert Cliffs 1, Cycle 24 COLR Page 14 of 21 Rev.1

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Calvert Cliffs 1, Cycle 24 COLR Page 15 of21 Rev.1

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Calvert Cliffs 1, Cycle 24 COLR Page 17 of21 Rev.I

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Calvert Cliffs l, Cycle 24 COLR Page 18 of21 Rev.I

LIST OF APPROVED METHODOLOGIES

1. ANF-88-133 (P)(A) and Supplement 1, "Qualification of Advanced Nuclear Fuels' PWR Design Methodology for Rod Bumups of 62 GWd/MTU" Advanced Nuclear Fuels Corporation, December 1991

2. BAW- 10240(P)(A), Revision 0, "Incorporation ofM5 Properties in Framatome ANP Approved Methods" Framatome ANP, May 2004

3. EMF-92-116(P)(A), Revision 0, Supplement l(P)(A), Revision 0, "Generic Mechanical Design Criteria for PWR Fuel Designs" AREVA Inc., February 2015 [Licensing Restriction 7]

4. EMF-92-153(P)(A), Revision 1, "HTP: Departure from Nucleate Boiling Correlation for High Thermal Performance Fuel," Siemens Power Corporation, January 2005

5. EMF-96-029(P)(A) Volumes 1 and 2, "Reactor Analysis System for PWRs Volume 1 -

Methodology Description, Volume 2 - Benchmarking Results," Siemens Power Corporation,

, January 1997

6. EMF-1961 (P)(A), Revision 0, "Statistical Setpoint/Transient Methodology for Combustion Engineering Type Reactors," Siemens Power Corporation, July 2000

7. EMF-2103 (P)(A), Revision 0, "Realistic Large Break LOCA Methodology for Pressurized Water Reactors" Framatome ANP, April 2003 [Licensing Restriction 9]

8. EMF-231 O(P)(A), Revision 1, "SRP Chapter 15 Non-LOCA Methodology for Pressurized Water Reactors" Framatome ANP, May 2004 [Licensing Restrictions 1, 2, 6, and 8b]

9. EMF-2328(P)(A), Revision 0, Supplement 1 (P)(A), Revision 0, "PWR Small Break LOCA Evaluation Model, S-RELAP5 Based" AREVA, September 2015 [Licensing Restriction 4]

10. XN-NF-75-32(P)(A), Supplements 1, 2, 3 & 4; "Computational Procedure for Evaluating Fuel Rod Bowing" Exxon Nuclear Company Inc., February 1983

11. XN-NF-78-44(NP)(A), "A Generic Analysis of the Control Rod Ejection Transient for Pressurized Water Reactors" Exxon Nuclear Company Inc., October 1983 [Licensing Restrictions 3 and 8a]

12. XN-NF-79-56(P)(A), Revision 1 and Supplement 1, "Gadolinia Fuel Properties for L WR Fuel Safety Evaluation" Siemens Power Corporation, October 1981

13. XN-NF-82-06(P)(A), Revision 1 & Supplements 2, 4, and 5, "Qualification of Exxon Nuclear Fuel for Extended Bumup" Exxon Nuclear Company Inc., October 1986

14. XN-NF-82-2l(P)(A), Revision 1, "Application of Exxon Nuclear Company PWR Thermal Margin Methodology to Mixed Core Configurations" Exxon Nuclear Company Inc., August 1983 Calvert Cliffs 1, Cycle 24 COLR Page 19 of21 Rev.I

15. XN-NF-85-92(P)(A), Revision 0, "Exxon Nuclear Uranium Dioxide/Gadolinia Irradiation Examination and Thermal Conductivity Results" Exxon Nuclear Company Inc., September 1986

16. CEN-124(B)-P, "Statistical Combination of Uncertainties Methodology Part 2: Combination of System Parameter Uncertainties in Thermal Margin Analyses for Calvert Cliffs Units 1 and 2," January 1980 [Not used/or this fuel cycle]

17. CEN-191(B)-P, "CETOP-D Code Structure and Modeling Methods for Calvert Cliffs Units 1 and 2," December 1981 [Not used/or this fuel cycle]

18. Letter from Mr. D. H. Jaffe (NRC) to Mr. A. E. Lundvall, Jr. (BG&E), dated June 24, 1982, Unit 1 Cycle 6 License Approval (Amendment No. 71 to DPR-53 and SER) [Approval to CEN-124(B)-P (three parts) and CEN-191(B)-P)] [Not used for this fuel cycle]

19. CENPD-161-P-A, "TORC Code, A Computer Code for Determining the Thermal Margin of a Reactor Core," April 1986 [Not used for this fuel cycle]

20. CENPD-206-P-A, "TORC Code, Verification and Simplified Modeling Methods," June 1981

[Not used/or this fuel cycle]

21. CENPD-225-P-A, "Fuel and Poison Rod Bowing," June 1983 [Not used/or thisfuel cycle]

22. CENPD-382-P-A, "Methodology for Core Designs Containing Erbium Burnable Absorbers,"

August 1993 [Not used/or this fuel cycle]

23. CENPD-139-P-A, "C-E Fuel Evaluation Model Topical Report," July 1974 [Not used/or this fuel cycle]

24. CEN-161-(B)-P-A, "Improvements to Fuel Evaluation Model," August 1989 [Not used/or this fuel cycle]

25. CEN-161-(B)-P, Supplement 1-P, "Improvements to Fuel Evaluation Model," April 1986 [Not used/or this fuel cycle]

26. Letter from Mr. S. A. McNeil, Jr. (NRC) to Mr. J. A. Tieman (BG&E), dated February 4, 1987, Docket Nos. 50-317 and 50-318, "Safety Evaluation of Topical Report CEN-161-(B)-P, Supplement 1-P, Improvements to Fuel Evaluation Model" (Approval of CEN-161(B),

Supplement 1-P) [Not used for this fuel cycle]

27. CEN-372-P-A, "Fuel Rod Maximum Allowable Gas Pressure," May 1990 [Not used for this fuel cycle]

28. CENPD-135, Supplement 5-P, "STRIKIN-11, A Cylindrical Geometry Fuel Rod Heat Transfer Program," April 1977 [Not used/or this fuel cycle]

29. CENPD-387-P-A, Latest Approved Revision, "ABB Critical Heat Flux Correlations for PWR Fuel" [Not usedfor this fuel cycle]

30. CENPD-404-P-A, Latest Approved Revision, "Implementation of ZIRLO' Cladding Material in CE Nuclear Power Fuel Assembly Designs". [Not used for this fuel cycle]

Calvert Cliffs 1, Cycle 24 COLR Page 20 of21 Rev.I

~

~I,7- Exelon Generation,:,1

31. WCAP-11596-P-A, "Qualification of the PHOENIX-P, ANC Nuclear Design System for Pressurized Water Reactor Cores," June 1988. [Not used/or this fuel cycle]

32. WCAP-10965-P-A, "ANC: A Westinghouse Advanced Nodal Computer Code," September 1986. [Not used/or this fuel cycle]

33. WCAP-10965-P-A Addendum 1, "ANC: A Westinghouse Advanced Nodal Computer Code; Enhancements to ANC Rod Power Recovery," April 1989. [Not used/or this fuel cycle]

34. WCAP-16072-P-A, "Implementation of Zirconium Diboride Burnable Absorber Coatings in CE Nuclear Power Fuel Assembly Designs," August 2004. [Not used for this Juel cycle]

35. WCAP-16045-P-A, "Qualification of the Two-Dimensional Transport Code PARAGON," August 2004. [Not used/or this fuel cycle]

Calvert Cliffs 1, Cycle 24 COLR Page 21 of21 Rev.I

ATTACHMENT (2)

CORE OPERATING LIMITS REPORT FOR UNIT 2, CYCLE 22, REVISION 1 Calvert Cliffs Nuclear Power Plant October 17, 2018

rr1i f ft -* Exelon Generation(li Calvert Cliffs Nuclear Power Plant Core Operating Limits Report COLR Unit 2 Cycle 22 Revision 1 Effective Date: 10/10/2018 Tim61-h'l Sch4.~rtr ~~6.~ 10/2.)2ti18 Responsible Engineer / Date KT~!'S choj ~ tohf?-o/3

• Independent Reviewer / Date Digitally signed by Nicholas Cahill DN: cn=Nicholas Cahill, o=Exelon Generation, oua:Operatlons, emall=nlcholas.cahilf@exeioncorp.com, c=US Date: 2018.10.03 14:22:15 -04'00' Station Qualified Reviewer / Date R,os.o..rv1.e. C..O..rlY\-U-1'- ee~

Sr. Manager - PWR Core Design

~ lo(11 / ,g

/ Date Calvert Cliffs 2, Cycle 22 COLR Page 1 of21 Rev.l

CORE OPERATING LIMITS REPORT CALVERT CLIFFS UNIT 2, CYCLE 22 The following limits are included in this Core Operating Limits Report:

Specification Title Introducti.on ................................................................................................................. 4 Definitions .................................................................................................................. 5 Licensing Restrictions ................................................................................................. 6 3 .1.1 Shutdown Margin (SOM) ........................................................................................... 8 3.1.3 Moderator Temperature Coefficient (MTC) ............................................................... 8 3.1.4 Control Element Assembly (CEA) Alignment .......................................................... 8 3.1.6 Regulating Control Element Assembly (CEA) Insertion Limits ................................ 8 3.2.1 Linear Heat Rate (LHR) .............................................................................................. 8 3.2.3 Total Integrated Radial Peaking Factor (F/) .............................................................. 9 3 .2.5 Axial Shape Index (ASI) ............................................................................................. 9 3.3.1 Reactor Protective System (RPS) Instrumentation - Operating .................................. 9 3.4.1 RCS Pressure, Temperature, and Flow DNB Limits .................................................. 9 3 .9 .1 Boron Concentration ................................................................................................. 10 List of Approved Methodologies .............................................................................. 19 The following figures are included in this Core Operating Limits Report:

Number Figure 3.1.6 CEA Group Insertion Limits vs. Fraction of Rated Thermal Power ......................... 11 Figure 3.2.1-1 Allowable Peak Linear Heat Rate vs. Time in Cycle ............................................... 12 Figure 3.2.1-2 Linear Heat Rate Axial Flux Offset Control Limits ................................................. 13 1

Figure 3.2.3 Total Integrated Radial Peaking Factor (Fr ) vs.

Allowable Fraction of Rated Thermal Power ........................................................... 14 Figure 3.2.5 DNB Axial Flux Offset Control Limits .................................................................... 15 Figure 3 .3 .1-1 Axial Power Distribution - High Trip Setpoint Peripheral Axial Shape Index vs. Fraction of Rated Thermal Power ............................................................. 16 Figure 3.3.1-2 Thermal Margin/Low Pressure Trip Setpoint - Part 1 .............................................. 17 Figure 3.3.1-3 Thermal Margin/Low Pressure Trip Setpoint- Part 2 .............................................. 18 Calvert Cliffs 2, Cycle 22 COLR Page 2 of21 Rev.I

UNIT2 CORE OPERATING LIMITS REPORT LIST OF EFFECTIVE PAGES Page No. Rev.No.

1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 1 9 1 10 1 11 1 12 1 13 1 14 1 15 1 16 1 17 1 18 1 19 1 20 1 21 1 Calvert Cliffs 2, Cycle 22 COLR Page 3 of21 Rev.I

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INTRODUCTION This report p_rovides the cycle-specific limits for operation of Calvert Cliffs Unit 2, Cycle 22. It contains the limits for:

Shutdown Margin (SDM)

Moderator Temperature Coefficient (MTC)

Control Element Assembly (CEA) Alignment Regulating Control Element Assembly (CEA) Insertion Limits Linear Heat Rate (LHR)

Total Integrated Radial Peaking Factor (F/)

Axial Shape Index (ASI)

Reactor Protective System (RPS) Instrumentation - Operating RCS Pressure, Temperature, and Flow Departure from Nucleate Boiling (DNB) Limits Boron Concentration In addition, this report contains a number of figures which give limits on the parameters listed above. If any of the limits contained in this report are exceeded, corrective action will be taken as defined in the Technical Specifications.

This report has been prepared in accordance with the requirements of Technical Specifications.

The cycle specific limits have been developed using the NRC-approved methodologies given in the "List of Approved Methodologies" section of this report and in the Technical Specifications.

COLR Revision 0 Initial release of the Unit 2 Cycle 22 (U2C22) COLR. U2C22 may operate in all plant modes.

COLR Revision 1 Mid-Cycle implementation oflatest NRC approved version of Reference 9 (PWR Small Break LOCA Evaluation Model, S-RELAP5 Based) per ECP-18-000354 and ECP-18-000503.

Calvert Cliffs continues to comply with Licensing Restriction #4.

Fixed spelling of Pickett under Licensing Restriction #9 per Issue Report 04106824.

Calvert Cliffs 2, Cycle 22 COLR Page 4 of21 Rev.I

DEFINITIONS Axial Shape Index (ASI)

ASI shall be the power generated in the lower half of the core less the power generated in the upper half of the core, divided by the sum of the power generated in the lower and upper halves of the core.

ASI = lower - upper = y E lower+ upper The Axial Shape Index (Yr) used for the trip and pretrip signals in the Reactor Protection System (RPS) is the above value (YE) modified by an appropriate multiplier (A) and a constant (B) to determine the true core axial power distribution for that channel.

Total Integrated Radial Peaking Factor - FrT The Total Integrated Radial Peaking Factor is the ratio of the peak pin power to the average pin power in an unrodded core.

Calvert Cliffs 2, Cycle 22 COLR Page 5 of21 Rev.I

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LICENSING RESTRICTIONS

1) For the Asymmetric Steam Generator Transient analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.8, the methodology shall be revised to capture the asymmetric core inlet temperature distribution and application of local peaking augmentation factors. The revised methodology shall be applied to Calvert Cliffs Unit 2 core reload designs starting with Cycle 19.

2) For the Seized Rotor Event analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.8, the methodology shall be revised to capture the asymmetric core inlet flow distribution. The revised methodology shall be applied to Calvert Cliffs Unit 2 core reload designs starting with Cycle 19.

3) For the Control Element Assembly Ejection analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.l l, the cycle-specific hot zero power peak average radial fuel enthalpy is calculated based on a modified power dependent insertion limit with Control Element Assembly Bank 3 assumed to be fully inserted (only in the analysis, not in actual plant operations). This revised methodology shall be applied to Calvert Cliffs Unit 2 core reload designs starting with Cycle 19.

4) The Small Break Loss of Coolant accident performed in accordance with the methodology of Technical Specification 5.6.5.b.9 shall be analyzed using a break spectrum with augmented detail related to break size. This revised methodology shall be applied to Calvert Cliffs Unit 2 core reload designs starting with Cycle 19.

5) Core Operating Limits Report Figures 3.1.6, 3.2.3, and 3.2.5 shall not be changed without prior NRC review and approval until an NRC-accepted generic, or Calvert Cliffs-specific, basis is developed for analyzing the Control Element Assembly Rod Bank Withdrawal Event, the Control Element Assembly Drop, and the Control Element Assembly Ejection (power level-sensitive transients) at full power conditions only.

6) Approval of the use of S-RELAP5 (Technical Specification 5.6.5.b.8) is restricted only to those safety analyses that confirm acceptable transient performance relative to the specified acceptable fuel design limits. Prior transient specific NRC approval is required to analyze transient performance relative to reactor coolant pressure boundary integrity until NRC-approval is obtained for a generic or Calvert Cliffs-specific basis for the use of the methodology in Technical Specification 5.6.5.b.8 to demonstrate reactor coolant pressure boundary integrity.

NOTE: The NRC has issued a letter that allows S-RELAP5 to be used for the transient-specific application of the methodology to CCNPP only as described in the letter pertaining to PSV setpoints. It is not a generic approval of the methodology.

Ref: Letter from Alexander N. Chereskin (NRC) to Bryan C. Hanson (Exelon) dated December 30, 2015, Calvert Cliffs Nuclear Power Plant, Unit Nos. land 2 -

Issuance of Amendment Re: Revision to Pressurizer Safety Valve Technical Specifications (CAC Nos. MF3541 and MF3542)

Calvert Cliffs 2, Cycle 22 COLR Page 6 of21 Rev.1

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7) For the RODEX2-based fuel thermal-mechanical design analysis performed in accordance with the methodology of Technical Specification 5.6.5.b.3, Calvert Cliffs Unit 2 core reload designs (starting with Cycle 19) shall satisfy the following criteria:

a. Predicted rod internal pressure shall remain below the steady state system pressure.

b. The linear heat generation rate fuel centerline melting safety limit shall remain below 21.0 KW/ft.

8) For the Control Element Assembly Ejection analysis, Calvert Cliffs Unit 2 core reloads (starting with Cycle 19) shall satisfy the following criteria:

a. Predicted peak radial average fuel enthalpy when calculated in accordance with the methodology of Technical Specification 5.6.5.b.l 1 shall remain below 200 cal/g.

b. For the purpose of evaluating radiological consequences, should the S-RELAP5 hot spot model predict fuel temperature above incipient centerline melt conditions when calculated in accordance with the methodology of Technical Specification 5.6.5.b.8, a conservative radiological source term (in accordance with Regulatory Guide 1.183, Revision 0) shall be applied to the portion of fuel beyond incipient melt conditions (and combined with existing gap source term), and cladding failure shall be presumed.

9) The approval of the emergency core cooling system evaluation performed in accordance with the methodology of Technical Specification 5.6.5.b.7 shall be valid only for Calvert Cliffs Unit 2, Cycle 19. To remove this condition, Calvert Cliffs shall obtain NRC approval of the analysis of once- and twice-burned fuel for core designs following Unit 2 Cycle 19.

NOTE: The revised methodology was submitted and received NRC approval in December 2012. This license condition is satisfied; however since NRC approval was obtained via letter and not LAR, this license condition is still listed in Appendix C of the Tech. Specs. and has been retained here for consistency.

Ref: Letter from Douglas V. Pickett (NRC) to George H. Gellrich (CCNPP) dated February 18, 2011, Calvert Cliffs Nuclear Power Plant, Unit Nos. 1 and 2 -

Amendment Re: Transition from Westinghouse Nuclear Fuel to AREVA Nuclear Fuel (TAC Nos. ME283 l and ME2832)

Calvert Cliffs 2, Cycle 22 COLR Page 7 of 21 Rev.I

Exelon Generation.]

CYCLE SPECIFIC LIMITS FOR UNIT 2, CYCLE 22 3.1.1 Shutdown Margin (SDM) (SR 3.1.1.1)

Tavg > 200 °P - Modes 3 and 4:

The shutdown margin shall be ~ 3 .5% ~p.

Tavg s 200 °P - Mode 5:

The shutdown margin shall be ~ 3 .0% ~p.

3.1.3 Moderator Temperature Coefficient (MTC) (SR 3.1.3.2)

The Moderator Temperature Coefficient (MTC) shall be less negative than -3 .1 x 10 4 ~p/°F at rated thermal power.

3.1.4 Control Element Assembly (CEA) Alignment (Action 3.1.4.B.1)

The allowable time to realign a CEA is 120 minutes when the pre-misaligned F/ is :S 1.65 and zero (0) minutes when the pre-misaligned F/ is> 1.65.

The pre-misaligned F/ value used to determine the allowable time to realign the CEA shall be the latest measurement taken within 5 days prior to the CEA misalignment. If no measurements have been taken within 5 days prior to the misalignment and the full core power distribution monitoring system is unavailable then the time to realign is zero (0) minutes.

3.1.6 Regulating Control Element Assembly (CEA) Insertion Limits (SR 3.1.6.1 and SR 3.1.6.2)

The regulating CEA groups insertion limits are shown on COLR Figure 3 .1.6.

Figure 3. l .6 will not be changed unless the requirements in Licensing Restriction 5 are met.

3.2.1 Linear Heat Rate (LHR) (SR 3.2.1.2 and SR 3.2.1.4)

The linear heat rate shall not exceed the limits shown on COLR Figure 3 .2.1-1.

The axial shape index power dependent control limits are given in COLR Figure 3 .2.1-2.

When using the excore detector monitoring system (SR 3 .2.1.2):

The alarm setpoints are equal to or less than the ASI limits; therefore when the alarms are adjusted, they provide indication to the operator that ASI is not within the limits.

The axial shape index alarm setpoints are shown as a function of fraction of thermal power on COLR Figure 3.2.1-2.

Calvert Cliffs 2, Cycle 22 COLR Page 8 of 21 Rev.I

When using the incore detector monitoring system (SR 3 .2.1.4 ):

The alarm setpoints are adjusted to protect the Linear Heat Rate limits shown on COLR Figure 3 .2.1-1 and uncertainty factors are appropriately included in the setting of these alarms.

The uncertainty factors for the incore detector monitoring system are:

1. A measurement-calculational uncertainty factor of 1.07

2. An engineering uncertainty factor of 1.03, 3.a For measured thermal power less than or equal to 50 percent but greater than 20 percent of rated full core power a thermal power measurement uncertainty factor of 1.035.

3.b For measured thermal power greater than 50 percent ofrated full core power a thermal power measurement uncertainty factor of 1.020.

3.2.3 Total Integrated Radial Peaking Factor (F rT) (SR 3.2.3.1)

The calculated value of F/ shall be limited to :S 1.65.

If the calculated F/ exceeds the above limit, the allowable combinations of thermal power, CEA position, and F/ are shown on COLR Figure 3.2.3.

Figure 3 .2.3 will not be changed unless the requirements in Licensing Restriction 5 are met.

3.2.5 Axial Shape Index (ASI) (SR 3.2.5.1)

The axial shape index and thermal power shall be maintained equal to or less than the limits of COLR Figure 3 .2.5 for CEA insertions specified by COLR Figure 3 .1.6.

Figure 3.2.5 will not be changed unless the requirements in Licensing Restriction 5 are met.

3.3.1 Reactor Protective System (RPS) Instrumentation - Operating (Reactor Trip Setpoints) (TS Table 3.3.1-1)

The Axial Power Distribution - High trip setpoint and allowable values are given in COLR Figure 3 .3 .1-1.

The Thermal Margin/Low Pressure (TM/LP) trip setpoint is given in COLR Figures 3 .3 .1-2 and 3.3.1-3. The allowable values are to be not less than the larger of (1) 1875 psia or (2) the value calculated from COLR Figures 3.3.1-2 and 3.3.1-3.

3.4.1 RCS Pressure, Temperature, and Flow Departure from Nucleate Boiling (DNB) Limits The RCS DNB parameters for pressurizer pressure, cold leg temperature, and RCS total flow rate shall be within the limits specified below:

a. Pressurizer pressure 2: 2200 psia;

b. RCS cold leg temperature (Tc) :S 548°F; and

c. RCS total flow rate 2: 370,000 gpm.

Calvert Cliffs 2, Cycle 22 COLR Page 9 of21 Rev.I

3.9.1 Boron Concentration (SR 3.9.1.1)

The refueling boron concentration will maintain the keff at 0.95 or less (including a 1% Lik/k conservative allowance for uncertainties). The refueling boron concentration shall be maintained uniform. For Mode 6 operation the RCS temperature must be maintained

_:s 140°F.

U2C22 Refueling Boron Concentration Limits U2C22 Cycle Average Exposure OGWD/MTU OGWD/MTU 2: 16 GWD/MTU 24 Number of Credited CEAs 0 0 (Note 1)

Post-Refueling UGS or RV Head Lift Height No Restriction ~ 12 inches No Restriction Restrictions.

Minimum Required Refueling Boron Concentration:

This number includes:

• Chemistry Sampling Uncertainty

~ 2619 ppm ~ 2450 ppm ~ 2560 ppm

• Boron- IO Depletion Allowance

• Margin for dilution of refueling pool between low and high level alarms (Note 2) (Note 2) (Note 2)

• Unlimited number of temporary rotations of fuel assemblies

• Extra Conservatism for empty locations during refueling operations.

Note: (1) The Core Loading Plan (NF162412) details the specific required credited CEAs.

(2) Based upon a U2C21 EOC bumup of2: 20.510 GWD/MTU.

Calvert Cliffs 2, Cycle 22 COLR Page 10 of21 Rev.I

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%CEA INSERTION INCHES CEA WITHDRAWN (ARO is defined in NEOP-23)

Note:

Per Tech Spec Bases 3.1.5 and 3.1.6, CEAs are considered to be fully withdrawn at 129 inches.

Figure 3.1.6 CEA Group Insertion Limits vs. Fraction of Rated Thermal Power This figure cannot be changed without prior NRC approval.

Calvert Cliffs 2, Cycle 22 COLR Page 11 of21 Rev.I

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Figure 3.2.1-2 Linear Heat Rate Axial Flux Offset Control Limits (AXIAL SHAPE INDEX limits for Linear Heat Rate when using Excore Detector Monitoring System)

(LCO Limits are not needed below 20% thermal power per SE00433)

(See NEOP-23 for Operational Limits)

Calvert Cliffs 2, Cycle 22 COLR Page 13 of2I Rev.I

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Allowable Fraction of Rated Thermal Power While operating with F / greater than 1.65, withdraw CEAs to or above the Long Term Steady State Insertion Limits (Figure 3.1.6)

This figure cannot be changed without prior NRC approval.

Calvert Cliffs 2, Cycle 22 COLR Page 14 of21 Rev.I

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This figure cannot be changed without prior NRC approval.

Calvert Cliffs 2, Cycle 22 COLR Page 15 of21 Rev.I

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1.300 ~ - - - - - - - - - - - - - - - - - - - - - - - - - - ~

1.250 (0.0, 1.17) 1.200 UNACCEPTABLE UNACCEPTABLE 1.150 OPERATION OPERATION REGION REGION 1.100 1.050 1.000 (-0.2, 1.00) a:: 0.950 w

~

D.

0.900

...J c(

5 0.850 a::

w

c 0.800 I-C w

0.750

~

II.

0 0.700 z

0 j:: 0.650 u

~ 0.600 II. ACCEPTABLE OPERATION 0.550 REGION 0.500 0.450 --

0.400 (-0.6, 0.40) (0.6, 0.40) 0.350 0.300 0.250 0.200 0.150

-0.80 -0.60 -0.40 -0.20 0.00 0.20 0.40 0.60 0.80 PERIPHERAL AXIAL SHAPE INDEX, Y1 Figure 3.3.1-1 Axial Power Distribution - High Trip Setpoint Peripheral Axial Shape Index vs. Fraction of Rated Thermal Power Calvert Cliffs 2, Cycle 22 COLR Page 16 of21 Rev.l

1.60 I p

var

=2869.5 X (A1) x (QR1) + 17.98 X Tin - 10820 1.50 °oNs A1 x QR1 1.40

(-0.6, 1.3) 1.30 I"

1.20

"/

~ A1 = +0.16 37xM ,I+ 1.0 1.10 1.00 A1 r

= 0.5 X /. SI+ 1.0

~

(0.0, 1 0)

~

(+0.6, 1.1) 0.90

-0.60 -0.50 -0.40 -0.30 -0.20 -0.10 0.00 0.10 0.20 0.30 0.40 0.50 0.60 ASI Figure 3.3.1-2 Thermal Margin/Low Pressure Trip Setpoint - Part 1 (ASI vs. A1)

Calvert Cliffs 2, Cycle 22 COLR Page 17 of21 Rev.I

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P~i = 2869.5 X (A1) X (QR1) + 17.98 X Tin - 10820 OoNB = A1 x QR1 1.2 1.1 l QR1 =(RTP) + 0.0 I I

- V (1.2, 1.2) 1.0

~

V (1.( 1.0

~

~ I 0.9 ...

0.8

/ ~ I 0.8 ))\

~

I 0.7 / OR1 =0.375 x (RTP) + 0.625

/

a:: 0.6 ,/

a p

0.5

/~

0.4 QR1 =0.9167 x (RTP) + 0.3 0.3 V (0.( 0.3 I

0.2 0.1 0.0 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 FRACTION OF RATED THERMAL POWER (RTP)

Figure 3.3.1-3 Thermal Margin/Low Pressure Trip Setpoint - Part 2 (Fraction of Rated Thermal Power vs. QR 1)

Calvert Cliffs 2, Cycle 22 COLR Page 18 of21 Rev.I

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LIST OF APPROVED METHODOLOGIES

1. ANF-88-133 (P)(A) and Supplement 1, "Qualification of Advanced Nuclear Fuels' PWR Design Methodology for Rod Burnups of 62 GWd/MTU" Advanced Nuclear Fuels Corporation, December 1991

2. BAW- 10240(P)(A), Revision 0, "Incorporation ofM5 Properties in Framatome ANP Approved Methods" Framatome ANP, May 2004

3. EMF-92-116(P)(A), Revision 0, Supplement l(P)(A), Revision 0, "Generic Mechanical Design Criteria for PWR Fuel Designs" AREVA Inc., February 2015 [Licensing Restriction 7]

4. EMF-92-153(P)(A), Revision 1, "HTP: Departure from Nucleate Boiling Correlation for High Thermal Performance Fuel," Siemens Power Corporation , January 2005

5. EMF-96-029(P)(A) Volumes 1 and 2, "Reactor Analysis System for PWRs Volume 1 -

Methodology Description, Volume 2 - Benchmarking Results," Siemens Power Corporation, January 1997

6. EMF-1961 (P)(A), Revision 0, "Statistical Setpoint/Transient Methodology for Combustion Engineering Type Reactors," Siemens Power Corporation, July 2000

7. EMF-2103 (P)(A), Revision 0, "Realistic Large Break LOCA Methodology for Pressurized Water Reactors" Framatome ANP, April 2003 [Licensing Restriction 9]

8. EMF-23 lO(P)(A), Revision 1, "SRP Chapter 15 Non-LOCA Methodology for Pressurized Water Reactors" Framatome ANP, May 2004 [Licensing Restrictions 1, 2, 6, and 8b]

9. EMF-2328(P)(A), Revision 0, Supplement 1 (P)(A), Revision 0, "PWR Small Break LOCA Evaluation Model, S-RELAP5 Based" AREVA, September 2015 [Licensing Restriction 4]

10. XN-NF-75-32(P)(A), Supplements 1, 2, 3 & 4, "Computational Procedure for Evaluating Fuel Rod Bowing" Exxon Nuclear Company Inc., February 1983

11. XN-NF-78-44(NP)(A), "A Generic Analysis of the Control Rod Ejection Transient for Pressurized Water Reactors" Exxon Nuclear Company Inc., October 1983 [Licensing Restrictions 3 and 8a]

12. XN-NF-79-56(P)(A), Revision 1 and Supplement 1, "Gadolinia Fuel Properties for LWR Fuel Safety Evaluation" Siemens Power Corporation, October 1981

13. XN-NF-82-06(P)(A), Revision 1 & Supplements 2, 4, and 5, "Qualification of Exxon Nuclear Fuel for Extended Burnup" Exxon Nuclear Company Inc., October 1986

14. XN-NF-82-21(P)(A), Revision 1, "Application of Exxon Nuclear Company PWR Thermal Margin Methodology to Mixed Core Configurations" Exxon Nuclear Company Inc., August 1983 Calvert Cliffs 2, Cycle 22 COLR Page 19 of21 Rev.I

15. XN-NF-85-92(P)(A), Revision 0, "Exxon Nuclear Uranium Dioxide/Gadolinia Irradiation Examination and Thermal Conductivity Results" Exxon Nuclear Company Inc., September 1986

16. CEN-l24(B)-P, "Statistical Combination of Uncertainties Methodology Part 2: Combination of System Parameter Uncertainties in Thermal Margin Analyses for Calvert Cliffs Units 1 and 2," January 1980 [Not used/or this fuel cycle]

17. CEN-191(B)-P, "CETOP-D Code Structure and Modeling Methods for Calvert Cliffs Units 1 and 2," December 1981 [Not used/or this.fu<d cycle]

18. Letter from Mr. D. H. Jaffe (NRC) to Mr. A. E. Lundvall, Jr. (BG&E), dated June 24, 1982, Unit 1 Cycle 6 License Approval (Amendment No. 71 to DPR-53 and SER) [Approval to CEN-l24(B)-P (three parts) and CEN-191(B)-P)] [Not used for this.fuel cycle]

19. CENPD-16 l -P-A, "TORC Code, A Computer Code for Determining the Thermal Margin of a Reactor Core," April 1986 [Not used/or this fuel cycle]

20. CENPD-206-P-A, "TORC Code, Verification and Simplified Modeling Methods," June 1981

[Not usedfor this fuel cycle]

21. CENPD-225-P-A, "Fuel and Poison Rod Bowing," June 1983 [Not used for this fuel cycle]

22. CENPD-382-P-A, "Methodology for Core Designs Containing Erbium Burnable Absorbers,"

August 1993 [Not used/or this fuel cycle]

23. CENPD-139-P-A, "C-E Fuel Evaluation Model Topical Report," July 1974 [Not used for this fuel cycle]

24. CEN-161-(B)-P-A, "Improvements to Fuel Evaluation Model," August 1989 [Notusedfor

. this fuel cycle]

25. CEN-161-(B)-P, Supplement 1-P, "Improvements to Fuel Evaluation Model," April 1986 [Not used/or this fuel cycle]

26. Letter from Mr. S. A. McNeil, Jr. (NRC) to Mr. J. A. Tieman (BG&E), dated February 4, 1987, Docket Nos. 50-317 and 50-318, "Safety Evaluation of Topical Report CEN-161-(B)-P, Supplement 1-P, Improvements to Fuel Evaluation Model" (Approval of CEN-161(B),

Supplement 1-P) [Not usedfor this fuel cycle]

27. CEN-372-P-A, "Fuel Rod Maximum Allowable Gas Pressure," May 1990 [Not used/or this fuel cycle]

28. CENPD-135, Supplement 5-P, "STRIKIN-II, A Cylindrical Geometry Fuel Rod Heat Transfer Program," April 1977 [Not used for this fuel cycle]

29. CENPD-387-P-A, Latest Approved Revision, "ABB Critical Heat Flux Correlations for PWR Fuel" [Not usedfor this.fuel cycle]

30. CENPD-404-P-A, Latest Approved Revision, "Implementation of ZIRLO' Cladding Material in CE Nuciear Power Fuel Assembly Designs". [Not used/or this.fuel cycle]

Calvert Cliffs 2, Cycle 22 COLR Page 20 of21 Rev.I

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31. WCAP-11596-P-A, "Qualification of the PHOENIX-P, ANC Nuclear Design System for Pressurized Water Reactor Cores," June 1988. [Not usedfor this fuel cycle]

32. WCAP-10965-P-A, "ANC: A Westinghouse Advanced Nodal Computer Code," September 1986. [Not usedfor this fuel cycle]

33. WCAP-10965-P-A Addendum 1, "ANC: A Westinghouse Advanced Nodal Computer Code; Enhancements to ANC Rod Power Recovery," April 1989. [Not usedfor this fuel cycle]

34. WCAP-16072-P-A, "Implementation of Zirconium Diboride Burnable Absorber Coatings in CE Nuclear Power Fuel Assembly Designs," August 2004. [Not used for this fuel cycle]

35. WCAP-16045-P-A, "Qualification of the Two-Dimensional Transport Code PARAGON," August 2004. [Not usedfor this fuel cycle]

Calvert Cliffs 2, Cycle 22 COLR Page 21 of21 Rev.I