Core Operating Limits Report, Cycle 20 (Revision 2)

ML073200099
Person / Time
Site:	Quad Cities
Issue date:	11/05/2007
From:	Tulon T Exelon Generation Co, Exelon Nuclear
To:	Document Control Desk, Office of Nuclear Reactor Regulation
References
SVP-07-069
Download: ML073200099 (42)
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ExeIkn.

Exelon Generation Company, LLC Ouad Cities Nuclear Power Station www~exeloncorp.com Nuclear 22710 206"h Avenue North Cordova, IL61242-9740 SVP-07-069 November 5, 2007 U. S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, D.C. 20555 Quad Cities Nuclear Power Station, Unit 1 Renewed Facility Operating License No. DPR-29 NRC Docket Number 50-254

Subject:

Core Operating Limits Report for Quad Cities Unit 1 Cycle 20 (Revision 2)

Reference:

Letter from Timothy J. Tulon (Exelon Generation Company, LLC) to U. S. NRC, "Core Operating Limits Report for Quad Cities Unit 1 Cycle 20 (Revision 1)," dated June 1, 2007 In accordance with Technical Specifications Section 5.6.5.d, enclosed is Revision 2 of the Core Operating Limits Report (COLR) for Quad Cities Unit 1 Cycle 20.

Revision 2 includes the incorporation of updated Operating Limit Minimum Critical Power Ratio (OLMCPR) values resulting from recently performed licensing analyses. This revision to the COLR is applicable until the end of Cycle 20.

Should you have any questions concerning this letter, please contact Mr. W. J. Beck at (309) 227-2800.

Respectfully, T*eothy J. Tulon e Vice President Quad Cities Nuclear Power Station

Attachment:

Core Operating Limits Report for Quad Cities Unit 1 Cycle 20 (Revision 2) cc: Regional Administrator - NRC Region III NRC Senior Resident Inspector - Quad Cities Nuclear Power Station

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Attachment Core Operating Limits Report for Quad Cities Unit I Cycle 20 (Revision 2)

COLR Quad Cities 1 Revision 2 Pagel 1 Quad Cities Unit 1 Cycle 20 Core Operating Limits Report Revision 2 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 2 Table of Contents

1. R efe re nce s ..................................................................................... .......... . . 5

2. Term s and D efinitions ................................................................................. 6

3. G eneral Inform ation ................................................ ....................................... 7

4. Average Planar Linear Heat Generation Rate ............................................. 8

5. Operating Limit Minimum Critical Power Ratio ........................................... 13 5.1. Manual Flow Control MCPR Limits ........................... 13 5.1.1. Power-Dependent MCPR ............................................................ 13 5.1.2. Flow-Dependent MCPR .................................................................. 13 5.2. Automatic Flow Control MCPR Limits .................................................. 13 5.3. Scram Time ........ ............................ ....... 13 5.4. Recirculation Pump Motor Generator Settings .................................... 14

6. Linear Heat G eneration Rate ...................................................................... 24 7: Rod Block Monitor .................................. ....... 37

8. Stability Protection Setpoints ...................................................................... 38

9. Modes of O peration ......................................... ....................................... . 39

10. Methodology ........................................................................................... 40 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 3 1 List of Tables Table 4-1 MAPLHGR for bundle(s):

GE14-PlODNAB409-17GZ-1 00T-145-T6-2825 GE14-Pl ODNAB408-15GZ-1 OOT-145-T6-2826 G E 14- P 10 DNAB 194-4G 7.0-1 OOT- 145-T6-2647 GE1 4-P1 ODNAB411-14GZ-1 OOT-1 45-T6-2564 GE 14-P1 ODNAB409-15GZ- 1OT-1 45-T6-2565 ........................... 8 Table 4-2 MAPLHGR for bundle/lattice:

. OPT2-3.99-15GZ8.00-3G6.00/Lattices 101,102,103, and 108 .......................... 8 Table 4-3 MAPLHGR for bundle/lattice: OPT2-3.99-15GZ8.00-3G6.00/Lattice 104 ......... 9 Table 4-4 MAPLHGR for bundle/lattice:

OPT2-3.99-15GZ8.00-3G6.00/Lattice 105 OPT2-4.00-13GZ8.00-3G6.00/Lattice 105 ................................................... 9 Table 4-5 MAPLHGR for bundle/lattice:

OPT2-3.99-15GZ8.00-3G6.00 OPT2-4.00-13GZ8.00-3G6.00 Lattices 106 and 107 .............. .............................. 10 Table 4-6 MAPLHGR for bundle/lattice:

OPT2-4.00-13GZ8.00-3G6.00/Lattices 101, 108, 109, and 110 ........................ 10 Table 4-7 MAPLHGR for bundle/lattice:OPT2-4.00-13GZ8.00-3G6.00/Lattice 111 .......... 11 Table 4-8 MAPLHGR for bundle/lattice:

OPT2-4.05-12GZ7.00-2G6.00/Lattices 101, 108, 112, and 113 ......................... 11 Table 4-9 MAPLHGR for bundle/lattice:

OPT2-4.05-12GZ7.00-2G6.00/Lattices 114 and 115 ..................................... 12 Table 4-10 MAPLHGR for bundle/lattice:OPT2-4.05-12GZ7.00-2G6.00/Lattice 116 ...... 12 Table 4-11 MAPLHGR SLO multiplier for GE Fuel ...................... ......................... 12 Table 5-1 Scram Tim es ........................................................................................ 13 Table 5-2 MCPR TSSS Based Operating Limits - Nominal FWT .................................... 15 Table 5-3 MCPR TSSS Based Operating Limits - FWTR ........................................... 16 Table 5-4 MCPR ISS Based Operating Limits- Nominal FWT .................................... 17 Table 5-5 MCPR ISS Based Operating Limits - FWTR ............................................... 18 Table 5-6 MCPR NSS Based Operating Limits - Nominal FWT ..................................... 19 Table 5-7 MCPR NSS Based Operating Limits - FWTR ................................................ 20 Table 5-8 MCPR(P) for GE and Westinghouse Fuel - Nominal FWT ........................... 21 Table 5-9 MCPR(P) for GE and Westinghouse Fuel - FWTR ...................................... 22 Table 5-10 MCPR(F) Limits for GE Fuel, DLO Operation ................................... ;........... 23 Table 5-11 MCPR(F) Limits for GE Fuel, SLO Operation ........................................... 23 Table 5-12 MCPR(F) Limits for Westinghouse Fuel, DLO Operation ............................... 23 Table 5-13 MCPR(F) Limits for Westinghouse Fuel, SLO Operation .............................. 23 Table 6-1: LHGR Limit for GE14-P1ODNAB411-14GZ-100T-145-T6-2564 ..................... 24 Table 6-2: LHGR Limit for GE14-P1ODNAB409-15GZ-10OT-145-T6-2565 ..................... 25 Table 6-3: LHGR Limit for GE14-P1ODNAB194-4G7.0-10OT-145-T6-2647 ..................... 25 Table 6-4: LHGR Limit for GE14-PIODNAB409-17GZ-100T-145-T6-2825 ...................... 26 Table 6-5: LHGR Limit for GE14-P1ODNAB408-15GZ-100T-145-T6-2826 ..................... 26 Table 6-6: LHGR Limit for GE14-P1ODNAB194-4G7.0-100T-145-T6-2647, Lattice 5977 ...... 27 Table 6-7: LHGR Limit for GE14-P1ODNAB409-17GZ-100T-145-T6-2825, Lattice 6828... 28 Table 6-8: LHGR Limit for GE14-P1ODNAB408-15GZ-10OT-145-T6-2826, Lattice 6834 ...... 29 Table 6-9: LHGR Limit for GE14-P1ODNAB411-14GZ-100T-145-T6-2564, Lattice 5571 ...... 30 Table 6-10: LHGR Limit for GE14-P1ODNAB409-15GZ-100T-145-T6-2565, Lattice 5577 .... 31 Table 6-11: LHGR Limit for GE14-P1ODNAB409-15GZ-10OT-145-T6-2565, Lattice 5576... 32 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 4 1.

Table 6-12: LHGR Limit for Westinghouse Optima2 Fuel OPT2-3.99-15GZ8.00-3G6.00 OPT2-4.00-13GZ8.00-3G6.00 OPT2-4.05-12GZ7.00-2G6.00 .................................................... 32 Table 6-13 LHGRFAC(P) for GE Fuel, DLO.... ................. .... ......... 33 Table 6-14 LHGRFAC(P) for GE Fuel, SLO ............................................................... . 33 Table 6-15 LHGRFAC(P) for W estinghouse Fuel ..................... ........ ......... ......... 34 Table 6-16 LHGRFAC(F) Multipliers, GE Fuel, DLO, All Cases except TCV Stuck Closed .... 35 Table 6-17 LHGRFAC(F) Multipliers, GE Fuel, DLO, TCV Stuck Closed ............... 35 Table 6-18 LHGRFAC(F) Multipliers, GE Fuel, SLO, All Cases except TCV Stuck Closed ... 36 Table 6-19 LHGRFAC(F) Multipliers, GE Fuel, SLO, TCV Stuck Closed ........................... 36 Table 6-20 LHGRFAC(F) Multipliers, Westinghouse Fuel .......................... 36 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 5 1

1. References

1. Exelon Generation Company, LLC, Docket No. 50-254, Quad Cities Nuclear Power Station, Unit 1 Facility Operating License, License No. DPR-29.

2. Letter from D. M. Crutchfield to All Power Reactor Licensees and Applicants, Generic Letter 88-16; Concerning the Removal of Cycle-Specific Parameter Limits from Tech Specs, October 3, 1988.

3. Westinghouse Document, WCAP-1 6728-P, Rev. 1, "Quad Cities Nuclear Power Station Unit 1 Cycle 20 Reload Licensing Report," July 2007 (TODI NF0700086, Revision 1).

4. GE Document, GE-NE-J1 1-03912-00-01-R3, "Dresden 2 and 3 Quad Cities 1 and 2 Equipment Out-Of-Service and Legacy Fuel Transient Analysis," September 2005 (TODI NFM0100091 Sequence 03).

5. GNF Letter, FRL02EX-013, "Quad Cities Unit 1.Cycle 18 and Dresden Unit 3 Cycle 18 Pellet Based LHGR Limits", September 30, 2002.

6. GE DRF C51-00217-01, "Instrument Setpoint Calculation Nuclear Instrumentation, Rod Block Monitor, Commonwealth Edison Company, Quad Cities 1 & 2," December 14,1999.

7. GE Design Basis Document, DB-0012.03, Revision 0, "Fuel-Rod Thermal-Mechanical Performance Limits for GE14C," May 2000.

8. GE Document, NEDE-2401 1-P-A-14, "General Electric Standard Application for Reactor Fuel," June 2000..

9. Westinghouse Document, NF-BEX-06-229, Revision 1, "Final Task Report for Quad Cities Unit 1 Cycle 20 Reload Licensing Analysis Plan, Revision 1", April 3, 2007.

10. Deleted.

11. Nuclear Fuels Letter, NF-MW:02-0081, "Approval of GE Evaluation of Dresden and Quad Cities Extended Final Feedwater Temperature Reduction," August 27, 2002.

12. GNF Letter, MJM-EXN-EE1-04-036, "QC1 C18A Pellet Based LHGR Limits for the FreshFuel Bundle Type 2647," November 17, 2004.

13. Deleted.

14. GNF Letter, MJM-EXN-EE1-04-047, "TSD B207: Quad Cities 1 C19 LHGR Limits", December 17, 2004.

15. GNF Document 0000-0014-8357-SRLR, Rev. 0, "Supplemental Reload Licensing Report for Quad Cities 1 Q1M16 Cycle 18A", May 2003 (TODI NF0300045, Revision 0).

16. FANP Letter, NJC:04:031/FAB04-496, "Startup with TIP Equipment Out of Service," April 20, 2004 (EC 348897-00)

17. Nuclear Fuels TODI NF0500090, Revision 0, "Quad Cities Unit 1 OPRM Trip Setpoints", April 19, 2005.

18. Technical Specifications for Quad Cities 1 and 2, Table 3.1.4-1, "Control Rod Scram Times".

19. GNF Document, 0000-0028-1626-SRLR, Rev. 1, "Supplemental Reload Licensing Report for Quad Cities 1 Reload 18 Cycle 19," May 2005 (TODI NF0500036, Revision 1).

20. Westinghouse Document, NF-BEX-06-254, Revision 1, "Exelon Nuclear - Final Report Quad Cities 1 Cycle 20 Bundle Designs Revision 1", December 22, 2006.

21. Exelon TODI QDC-06-0053, Revision 0, "OPL-W Parameters for Quad Cities Unit 1 Cycle 20 Transient Analysis," September 1, 2006.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 6 1

2. Terms and Definitions APLHGR Average planar linear heat generation rate APRM Average power range monitor BOC Beginning of cycle DLO Dual loop operation EFPH Effective full power hour ELLLA Extended load line limit analysis EOC End of cycle EOOS Equipment out of service EOFPL End of full power life FWTR Feedwater temperature reduction FWHOOS Feedwater heater out of service FWT Feedwater temperature GE14 GE14C fuel GNF Global Nuclear Fuel ICF Increased core flow ISS Intermediate scram speed LHGR Linear heat generation rate LHGRFAC(F) Flow dependent LHGR multiplier LHGRFAC(P) Power dependent LHGR multiplier LPRM Local power range monitor MAPLHGR Maximum average planar linear heat generation rate MAPRAT Maximum average planar ratio MCPR Minimum critical power ratio MCPR(F) Flow dependent MCPR MCPR(P) Power dependent MCPR MELLLA Maximum extended load line limit analysis MSIV Main steam isolation valve OLMCPR Operating limit minimum critical power ratio OPRM Oscillation power range monitor PBDA Period based detection algorithm PLUOOS Power load unbalance out of service PROOS Pressure regulator out of service RBM Rod block monitor RPTOOS Recirculation pump trip out of service RWE Rod withdrawal error SLMCPR Safety limit minimum critical power ratio SLO Single loop operation SRVOOS Safety-relief valve out of service TBPOOS Turbine bypass system out of service TCV Turbine control valve TCVOOS Turbine control valve out of service TIP Traversing incore probe TSSS Technical Specification scram speed TSV Turbine stop valve TSVOOS Turbine stop valve out of service Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 71

3. General Information Power and flow dependent limits are listed for various power and flow levels. Linear interpolation is to be used to find intermediate values.

Rated core flow is 98 Mlb/hr. Operation up to 108% rated flow is licensed for this cycle. Licensed rated thermal power is 2957 MWth.

MCPR(P) and MCPR(F) values are independent of scram time.

LHGRFAC(P) and LHGRFAC(F) values are independent of scram speed.

For thermal limit monitoring above 100% rated power or 100% rated core flow, the 100% rated power and the 100% core flow values, respectively, can be used unless otherwise indicated in the applicable table.

The OPRM PBDA trip settings are based, in part, on the cycle specific OLMCPR and the power dependent MCPR limits. Any change to the OLMCPR values and/or the power dependent MCPR limits should be evaluated for potential impact on the OPRM PBDA trip settings.

For both Base and EOOS DLO/SLO conditions, for operation at Nominal FWT, the OLMCPR limit is applicable to a variation of +10°F/- 30°F in feedwater temperature, and an operating steam dome pressure region bounded by the maximum value of 1020 psia and the minimum pressure curve in the Reload Licensing Report (Reference 3). For operation outside of Nominal FWT, a feedwater temperature reduction of up to 120°F is supported for Base and EOOS DLO/SLO conditions for cycle operation through EOC. Nominal FWT is defined and described in detail in Section 9 of the Reference 3 Reload Licensing Report.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 8 1

4. Average Planar Linear Heat Generation Rate The MAPLHGR values for the most limiting lattice (excluding natural uranium) of the GE14 bundle types as a function of average planar exposure is given in Table 4-1. During single loop operation, these limits are multiplied by the SLO multiplier listed in Table 4-11.

For Optima2 fuel, lattice-specific MAPLHGR values for DLO and SLO are provided in Tables 4-2 through 4-10. Table 4-4 provides only the most limiting set of MAPLHGR limit from Reference 3 for Lattice 105, which is part of two types of Optima2 fuel bundles. The MAPLHGR limits for the top and bottom natural uranium lattices (lattices 101 and 108) will be set equal to the most restrictive MAPLHGR limits for the other lattice types.

Table 4-1 MAPLHGR for bundle(s):

GE14-Pl ODNAB409-17GZ-10OT-145-T6-2825 GE14-P1ODNAB408-15GZ-10OT-145-T6-2826 GE14-PIODNABi94-4G7.0-10OT-145-T6-2647 GE14-PlODNAB411-14GZ-100T-145-T6-2564 GE1 4-P1 ODNAB409-15GZ-1 OOT-1 45-T6-2565 (References 15 and 19)

Avg. Planar Exposure MAPLHGR (GWd/MT) (kW/ft) 0.00 11.68 16.00 11.68 44.09 9.16 55.12 8.09 63.50 6.97 70.00 4.36 Table 4-2 MAPLHGR for bundle/lattice:

OPT2-3.99-15GZ8.00-3G6.00/Lattices 101, 102,103, and 108 (References 3 and 20)

Lattices 101: Opt2-BO.71 102: Opt2-B4.38-15G8.00-3G6.00 103: Opt2-BE4.47-15G8.00-3G6.00 108: Opt2-TO.71 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 9.26 7.96 7.5 9.11 7.83 17.5 9.11 7.83 24.0 9.45 8.13 58.0 9.45 8.13 70.0 8.08 6.95 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 9 1 Table 4-3 MAPLHGR for bundle/lattice:

OPT2-3.99-15GZ8.00-3G6.00/Lattice 104 (Reference 3 and 20)

Lattice 104: Opt2-M4.47-15G8.00-3G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 9.37 8.06 7.5 9.17 7.89 17.5 9.17 7.89 24.0 9.57 8.23 58.0 9.57 8.23 70.0 8.20 7.05 Table 4-4 MAPLHGR for bundle/lattice:

OPT2-3.99-15GZ8.00-3G6.00/Lattice 105 OPT2-4.00-13GZ8.00-3G6.00/Lattice 105 (Reference 3 and 20)

Lattice 105: Opt2-ME4.46-11G8.00-3G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 9.37 8.06 7.5 9.17 7.89 17.5 9.17 7.89 24.0 9.57 8.23 58.0 9.57 8.23 70.0 8.20 7.05 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 10 1 Table 4-5 MAPLHGR for bundle/lattice:

OPT2-3.99-15GZ8.00-3G6.00 OPT2-4.00-13GZ8.00-3G6.00 Lattices 106 and 107 (Reference 3 and 20)

Lattices 106: Opt2-T4.46-11G8.00-3G6.00 107: Opt2-T4.46-14G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 10.15 8.73 10.0 9.68 8.32 20.0 9.68 8.32 24.0 9.85 8.47 58.0 9.85 8.47 70.0 8.48 7.29 Table 4-6 MAPLHGR for bundle/lattice:

OPT2-4.00-13GZ8.00-3G6.00 Lattices 101, 108, 109, and 110 (References 3 and 20)

Lattices 101: Opt2-B0.71 108: Opt2-TO.71 109: Opt2-B4.40-13G8.00-3G6.00 110: Opt2-BE4.48-13G8.00-3G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 9.50 8.17 10.0 9.25 7.96 20.0 9.25 7.96 24.0 9.45 8.13 58.0 9.45 8.13 70.0 8.08 6.95 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 11 1 Table 4-7 MAPLHGR for bundle/lattice:

OPT2-4.00-13GZB.00-3G6.00/Lattice 111 (Reference 3 and 20)

Lattice 111: Opt2-M4.48-13G8.00-3G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 9.59 8.25 10.0 9.32 8.02 20.0 9.32 8.02 24.0 9.57 8.23 58.0 9.57 8.23 70.0 8.20 7.05 Table 4-8 MAPLHGR for bundle/lattice:

OPT2-4.05-12GZ7.00-2G6.00 Lattices 101, 108, 112, and 113 (Reference 3 and 20)

Lattices 101: Opt2-B0.71 108: Opt2-TO.71 112: Opt2-B4.44-12G7.00-2G6.00 113: Opt2-BE4.55-10G7.00-2G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 9.90 8.51 10.0 9.52 8.19 58.0 9.52 8.19 70.0 8.15 7.01 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 121 Table 4-9 MAPLHGR for bundle/lattice:

OPT2-4.05-12GZ7.00-2G6.00 Lattices 114 and 115 (Reference 3 and 20)

Lattices 114: Opt2-M4.55-10G7.00-2G6.00 115: Opt2-M E4.51-10G7.00-2G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 10.33 8.88 12.5 9.69 8.33 58.0 9.69 8.33 70.0 8.32 7.16 Table 4-10 MAPLHGR for bundle/lattice:

OPT2-4.05-12GZ7.00-2G6.00/Lattice 116 (Reference 3 and 20)

Lattice 116: Opt2-T4.51-10G7.00-2G6.00 Avg. Planar DLO SLO Exposure MAPLHGR MAPLHGR (GWd/MT) (kW/ft) (kW/ft) 0.0 10.66 9.17 10.0 9.91 8.52 58.0 9.91 8.52 70.0 8.54 7.34 Table 4-11 MAPLHGR SLO multiplier for GE Fuel (Reference 15 and 19)

Fuel~ype SLO Fuel Type Multiplier GE14 0.77 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 131

5. Operating Limit Minimum Critical Power Ratio 5.1. Manual Flow Control MCPR Limits The OLMCPR is determined for a given power and flow condition by evaluating the power-dependent MCPR and the flow-dependent MCPR and selecting the greater of the two.

5.1.1. Power-Dependent MCPR For operation at less than 38.5% of rated core thermal power, the OLMCPR as a function of core thermal power (MCPR(P)) is shown in Tables 5-8 and 5-9. For operation at greater than 38.5% of rated core thermal power, the OLMCPR as a function of core thermal power is determined by multiplying the applicable rated condition OLMCPR limit shown in Table 5-2 through 5-7 by the applicable MCPR multiplier K(P) given in Table 5-8 and 5-9. For operation at exactly 38.5% of rated core thermal power, the OLMCPR as a function of core thermal power is the maximum of either of the two aforementioned methods evaluated at 38.5% of rated core thermal power.

5.1.2. Flow-Dependent MCPR Tables 5-10 through 5-13 give the MCPR(F) limit as a function of the flow based on the applicable plant condition. The MCPR(F) limit determined from these tables is the flow dependent OLMCPR.

5.2. Automatic Flow Control MCPR Limits Automatic Flow Control MCPR Limits are not provided.

5.3. Scram Time TSSS, ISS, and NSS refer to scram speeds. TSSS is the Technical Specification Scram Speed, ISS is the Intermediate Scram Speed, and NSS is the Nominal Scram Speed.

The scram time values are shown in Table 5-1. Reference 3 indicates that TSSS control rod insertion time values used in the analysis are conservative in comparison to the values shown in Table 5-1.

The NSS scram times are based on a conservative interpretation of scram time surveillance measurements. In the event that plant surveillance shows these scram insertion times to be exceeded, the MCPR limits are to default to the values which correspond to the ISS scram time. The ISS times have been chosen to provide an intermediate value between the NSS and the TSSS, but the interpolation between these values is not supported by Westinghouse methodology. In the event that the ISS times are exceeded, MCPR limits for the TSSS apply.

Table 5-1 Scram Times (References 3 and 18)

Control Rod Insertion Fraction TSSS (seconds) ISS (seconds) NSS (seconds)

(%)

5 0.48 0.360 0.324 20 0.89 0.720 0.694 50 1.98 1.530 1.459 90 3.44 2.740 2.635 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 14 1 5.4. Recirculation Pump Motor Generator Settings Cycle 20 was analyzed with a maximum core flow runout of 110%; therefore the recirculation pump motor generator scoop tube mechanical and electrical stops must be set to maintain core flow less than 110% (107.8 Mlb/hr) for all runout events (Reference 9). This value is consistent with the analyses of Reference 3.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 15 1 Table 5-2 MCPR TSSS Based Operating Limits - Nominal FWT (Reference 3)

Cycle Exposure

< 10600 MWd/MT > 10600 MWd/MT EOOS Combination Fuel Type Optim a2 1.72 1.90 BASE GE14 1.82 1.85 Optim a2 1.76 1.94 BASE SLO GE14 1.86 1.89 Optima2 1.80 2.00 PLUOOS GE14 1.87 1.91 Optima2 1.84 2.04 PLUOOS SLO GE14 1.91 1.95 Optima2 1.89 2.05 TBPOOS GE14 1.98 1.99 Optima2 1.93 2.09 TBPOOS SLO GE14 2.02 2.03 Optirna2 1.83 2.05 TCV SLOW CLOSURE GE14 1.90 1.93 Optima2 1.87 2.09 TCV SLOW CLOSURE SLO GE14 1.94 1.97 Optima2 1.72 1.90 TCV STUCK CLOSED GE14 1.82 1.85 Optima2 1.76 1.94 TCV STUCK CLOSED SLO GE14 1.86 1.89 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 16 1 Table 5-3 MCPR TSSS Based Operating Limits - FWTR (Reference 3)

Cycle Exposure

< 10600 MWd/MT > 10600 MWd/MT EOOS Combination Fuel Type Optima2 1.72 1.90 BASE GE14 1.82 1.85 Optima2 1.76 1.94 BASE SLO GE14 1.86 1.89 Optima2 1.80 2.00 PLUOOS GE14 1.87 1.91 Optima2 1.84 2.04 PLUOOS SLO GE14 1.91 1.95 Optima2 1.89 2.05 TBPOOS GE14 1.98 1.99 Optima2 1.93 2.09 TBPOOS SLO GE14 2.02 2.03 Optima2 1.83 2.05 TCV SLOW CLOSURE GE14 1.90 1.93 Optima2 1.87 2.09 TCV SLOW CLOSURE SLO GE14 1.94 1.97 Optima2 1.72 1.90 TCV STUCK CLOSED GE14 1:82 1.85 Optima2 1.76 1.94 TCV STUCK CLOSED SLO GE14 1.86 1.89 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 17 Table 5-4 MCPR ISS Based Operating Limits - Nominal FWT (Reference 3)

Cycle Exposure

< 10600 MWd/MT > 10600 MWd/MT EOOS Combination Fuel Type BASE Optima2 1.51 1.60 GE14 1.64 1.64 BASE SLO Optima2 1.54 1.63 GE14 1.67 1.67 Optima2 1.57 1.67 PLUOOS GE14 1.67 1.68 Optima2 1.60 1.71 PLUOOS SLO GE14 1.71 1.72 Optima2 1.62 1.74 TBPOOS GE14 1.74 1.71 Optima2 1.65 1.78 TBPOOS SLO GE14 1.78 1.75 Optima2 1.57 1.73 TCV SLOW CLOSURE GE14 1.67 1.73 Optima2 1.60 1.77 TCV SLOW CLOSURE SLO GE14 1.71 1.77 Optima2 1.51 1.60 TCV STUCK CLOSED GE14 1.64 1.64 Optima2 1.54 1.63 TCV STUCK CLOSED SLO GE14 1.67 1.67 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 18 Table 5-5 MCPR ISS Based Operating Limits - FWTR (Reference 3)

Cycle Exposure

< 10600 MWd/MT > 10600 MWd/MT EOOS Combination Fuel Type BASE Optima2 1.58 1.63 GE14 1.64 1.64 BASE SLO Optima2 1.61 1.66 GE14 1.67 1.67 Optima2 1.58 1.67 PLUOOS GE14 1.67 1.68 Optima2 1.61 1.71 PLUOOS SLO GE14 1.71 1.72 Optima2 1.67 1.76 TBPOOS GE14 1.77 1.73 Optima2 1.71 1.80 TBPOOS SLO GE14 1.81 1.77 Optima2 1.58 1.73 TCV SLOW CLOSURE GE14 1.67 1.73 Optima2 1.61 1.77 TCV SLOW CLOSURE SLO GE14 1.71 1.77 Optima2 1.58 1.63 TCV STUCK CLOSED GE14 1.64 1.64 Optima2 1.61 1.66 TCV STUCK CLOSED SLO GE14 1.67 1.67 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1. Revision 2 Page 19 Table 5-6 MCPR NSS Based Operating Limits - Nominal FWT (Reference 3)

.Cycle Exposure

< 10600 MWd/MT > 10600 MWd/MT EOOS Combination Fuel Type BASE Optima2 1.50 1.55 GE14 1.64 1.64 BASE SLO Optima2 1.53 1.58 GE14 1.67 1.67 Optima2 1.56 1.64 PLUOOS GE14 1.65 1.66 Optima2 1.59 1.67 PLUOOS SLO GE14 1.68 1.69 Optima2 1.60 1.72 TBPOOS GE14 1.72 1.70 Optima2 1.63 1.76 TBPOOS SLO GE14 1.76 1.74 Optima2 1.56 1.70 TCV SLOW CLOSURE GE14 1.66 1.69 Optima2 1.59 1.74 TCV SLOW CLOSURE SLO GE14 1.69 1.73 Optima2 1.50 1.55 TCV STUCK CLOSED GE14 1.64 1.64 Optima2 1.53 1.58 TCV STUCK CLOSED SLO GE14 1.67 1.67 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 20 Table 5-7 MCPR NSS Based Operating Limits - FWTR (Reference 3)

Cycle Exposure

< 10600 MWdIMT > 10600 MWd/MT EOOS Combination Fuel Type_________

BASE Optirma2 1.57 1.59 GE14 1.64 1.64 BASE SLO Optima2 1.60 1.62 GE14 1.67 1.67 Optima2 1.57 1.64 PLUOOS GE14 1.65 1.66 Optima2 1.60 1.67 PLUOOS SLO GE14 1.68 1.69 Optima2 1.66 1.73 TBPOOS GE14 1.75 1.70 Optima2 1.69 1.77 TBPOOS SLO GE14 1.79 1.74 Optimna2 1.57 1.70 TCV SLOW CLOSURE GE14 1.66 1.69 Optima2 1.60 1.74 TCV SLOW CLOSURE SLO GE14 1.69 1.73 Optima2 1.57 1.59 TCV STUCK CLOSED GE14 1.64 1.64 Optima2 1.60 1.62 TCV STUCK CLOSED SLO GE14 1.67 1.67 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 21 Table 5-8 MCPR(P) for GE and Westinghouse Fuel - Nominal FWT (Reference 3)

EOOS Combination o Core

(

ICore 0 25 Thermal Power (% of rated) 8.5 41 50 60 80 100 of Rated) Operating Limit MCPR Operating Limit MCPR Multiplier, Kp Base <60 2.68 2.39 2.24 1.32 1.29 1.22 1.16 1.07 1.00

>60 2.91 2.64 2.50

<60 2.73 2.44 2.29 Base SLO 1.32 1.29 1.22 1.16 1.07 1.00

>60 2.97 2.69 2.55

<60 2.68 2.39 2.24 PLUOOS 1.58 1.56 1.50 1.35 1.07 1.00

>60 2.91 2.64 2.50

<60 2.73 2.44 2.29 PLUOOS SLO 1.58 1.56 1.50 1.35 1.07 1.00

>60 2.97 2.69 2.55

<60 3.88 3.04 2.59 TBPOOS 1.32 1.29 1.22 1.16 1.07 1.00

>60 3.93 3.27 2.92

_<60 3.95 3.10 2.64 TBPOOS SLO 1.32 1.29 1.22 1.16 1.07 1.00

>60 4.01 3.33 2.98 TCV SLOW <60 2.68 2.39 2.24 1.58 1.56 1.50 1.35 1.07 1.00 CLOSURE

>60 2.91 2.64 2.50 TCV SLOW <60 2.73 2.44 2.29 1.58 1.56 1.50 1.35 1.07 1.00 CLOSURE SLO

>60 2.97 2.69 2.55

<60 2.68 2.39 2.24 TCV STUCK 1.32 1.29 1.22 1.16 1.07 1.00 CLOSED >60 2.91 2.64 2.50

<60 2.73 2.44 2.29 TCV STUCK 1.32 1.29 1.22 1.16 1.07 1.00

>60 2.97 2.69 2.55 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 22 Table 5-9 MCPR(P) for GE and Westinghouse Fuel - FWTR (Reference 3)

Core Core Thermal Power (% of rated)

EOOS Com o Flow (% 0 1 25 1 38.5 38.5 41 1 50 60 80 100 of Operating Limit MCPR Operating Limit MCPR Multiplier, Kp

<60 2.68 2.39 2.24 2.68 1.36 1.34 1.24 1.16 1.08 1.00 Base _60

>60 2.91 2.64 2.50

_<60 2.73 2.44 2.29 Base SLO 1.36 1.34 1.24 1.16 1.08 1.00

>60 2.97 2.69 2.55

_<60 2.68 2.39 2.24 PLUOOS 1.58 1.56 1.50 1.35 1.08 1.00

>60 2.91 2.64 2.50

<60 2.73 2.44 2.29 PLUOOS SLO _60 1.58 1.56 1.50 1.35 1.08 1.00

>60 2.97 2.69 2.55

<60 4.23 3.21 2.65 TBPOOS _60 1.36 1.34 1.24 1.16 1.08 1.00

>60 3.93 3.27 2.96

_<60 4.31 3.27 2.70 TBPOOS SLO 1.36 1.34 1.24 1.16 1.08 1.00

>60 4.01 3.33 3.02

<60 2.68 2.39 2.24 TCV SLOW - 1.58 1.56 1.50 1.35 1.08 1.00 CLOSURE >60 2.91 2.64 2.50 TCV SLOW <60 2.73 2.44 2.29 1.58 1.56 1.50 1.35 1.08 1.00 CLOSURE SLO >60 2.97 2.69 2.55

<60 2.68 2.39 2.24 TCV STUCK 6 1.36 1.34 1.24 1.16 1.08 1.00 CLOSED

>60 2.91 2.64 2.50

<60 2.73 2.44 2.29 CVOSTUCKS 1.36 1.34 1.24 1.16 1.08 1.00

>60 2.97 2.69 2.55 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 23 Table 5-10 MCPR(F) Limits for GE Fuel, DLO Operation (Reference 3)

F Flow MCPR(F)

Limit

(% rated) 110.0 1.25 100.0 1.25 80.0 1.44 60.0 1.63 40.0 1.79 20.0 2.00 0.0 2.21 Table 5-11 MCPR(F) Limits for GE Fuel, SLO Operation (Reference 3)

Flow MCPR(F)

(% rated) Limit 110.0 1.27 100.0 1.27 80.0 1.46 60.0 1.66 40.0 1.82 20.0 2.03 0.0 2.24 Table 5-12 MCPR(F) Limits for Westinghouse Fuel, DLO Operation (Reterence 3)

Flow MCPR(F)

(% rated) Limit 110.0 1.17 100.0 1.17 80.0 1.34 60.0 1.49 40.0 1.55 20.0 1.59 0.0 1.63 Table 5-13 MCPR(F) Limits for Westinghouse Fuel, SLO Operation (Reference 3)

Flow MCPR(F)

(% rated) Limit 110.0 1.19 100.0 1.19 80.0 1.36 60.0 1.52 40.0 1.57 20.0 1.62 0.0 1.67 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 24

6. Linear Heat Generation Rate The maximum LHGR shall not exceed the zero exposure limit of 13.4 KW/ft for the following fuel bundles (Reference 7).

GE14-P1ODNAB409-i7GZ-10OT-145-T6-2825 GE14-P1ODNAB408-15GZ-10OT-145-T6-2826 GE14-P1ODNAB194-4G7.0-10OT-145-T6-2647 GE14-P1ODNAB411-14GZ-10OT-145-T6-2564 GE14-P1ODNAB409-15GZ-10OT-145-T6-2565 The thermal mechanical operating limit at rated conditions for the Optima2 fuel is established in terms of the maximum LHGR given in Table 6-12 as a function of rod nodal exposure. The limit applies to all Optima2 bundle designs.

The linear heat generation rate (LHGR) limit is the product of the exposure dependent LHGR limit from Tables 6-1 through 6-12 and the minimum of: the power dependent LHGR Factor, LHGRFAC(P), the flow dependent LHGR Factor, LHGRFAC(F), or the single loop operation (SLO) multiplication factor where applicable. The LHGRFAC(P) is determined from Tables 6-13, 6-14, and 6-15. The LHGRFAC(F) is determined from Table 6-16 through 6-20.

Table 6-1: LHGR Limit for GEl4- PlODNAB411-14GZ-10OT-145-T6-2564 (Reference 5)

Lattices 5567, 5568, 5569, 5570, 5572 and 5573 LHGR Limit kW/ft 5567: P1ODNAL071-NOG-10OT-T6-5567 5568: P1ODNAL458-6G7.0/8G6.0-10OT-T6-5568 5569: P1 ODNAL458-6G7.0/7G6.0-1 OOT-T6-5569 5570: P1ODNAL451-6G7.0/7G6.0-10OT-E-T6-5570 5572: PlODNAL071-NOG-10OT-V-T6-5572 5573: P1ODNAL071-14G E-10OT-V-T6-5573 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/)t) 0.0000 13.4000 16.0000 13.4000 63.5000 8.0000 70.0000 5.0000 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 25 Table 6-2: LHGR Limit for GE14-P1ODNAB409-15GZ-100T-145-T6-2565 (Reference 5)

Lattice 5567, 5574, 5575, 5572, and 5578 LHGR Limit kW/ft 5567: P1ODNAL071-NOG-100T-T6-5567 5574: P1ODNAL456-13G7.0/2G6.0-10OT-T6-5574 5575: P1ODNAL456-12G7.0/2G6.0-10OT-T6-5575 5572: P1ODNAL071-NOG-10OT-V-T6-5572 5578: P1ODNAL071-15GE-10OT-V-T6-5578 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0000 13.4000 16.0000 13.4000 63.5000 8.0000 70.0000 5.0000 Table 6-3: LHGR Limit for GE14-P1ODNAB194-4G7.0-10OT-145-T6-2647 (Reference 12)

Lattices 5976, 5978, 5979, 5980, 5981 and 5982 LHGR Limit kW/ft 5976: P1ODNAL071-NOG-10OT-T6-5976 5978: P1ODNAL212-4G7.0-1OOT-T6-5978 5979: P1ODNAL216-4G7.0-10OT-E-T6-5979 5980: P1ODNAL256-4G7.0-10OT-V-T6-5980 5981: P1ODNAL071-NOG-10OT-V-T6-5981 5982: PiODNAL071-4GE-10OT-V-T6-5982 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0000 13.4000 16.0000 13.4000 63.5000 8.0000 70.0000 5.0000 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 26 Table 6-4: LHGR Limit for GE14-P1ODNAB409-17GZ-100T-145-T6-2825 (Reference 14)

Lattice 6824, 6825, 6826, 6827, 6829, and 6830 LHGR Limit kW/ft 6824: P1ODNAL071-NOG-10OT-T6-6824 6825: P1ODNAL456-4G7.0/11G6.0/2G3.0-10OT-T6-6825 6826: P1ODNAL456-4G7.0/10G6.0/2G3.0-1OOT-T6-6826 6827: P1ODNAL448-14G6.0/2G3.0-10OT-E-T6-6827 6829: P1ODNAL071-NOG-10OT-V-T6-6829 6830: P1ODNAL071-17GE-10OT-V-T6-6830 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0000 13.4000 16.0000 13.4000 63.5000 8.0000 70.0000 5.0000 Table 6-5: LHGR Limit for GE14-P1ODNAB408-15GZ-100T-145-T6-2826 (Reference 14)

Lattice 6824, 6832, 6833, 6835, and 6836 LHGR Limit kW/ft 6824: P1ODNAL071-NOG-10OT-T6-6824 6832: P1ODNAL455-14G6.0/1G3.0-10OT-T6-6832 6833: P1ODNAL448-13G6.0/1G3.0-100T-E-T6-6833 6835: P1ODNAL071-NOG-10OT-V-T6-6835 6836: P1ODNAL071-15GE-1OOT-V-T6-6836 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0000 13.4000 16.0000 13.4000 63.5000 8.0000 70.0000 5.0000 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 27 Table 6-6: LHGR Limit for GE14-P1ODNAB194-4G7.0-100T-145-T6-2647, Lattice 5977 (Reference 12)

Lattice 5977 LHGR Limit kW/ft 5977: P1ODNAL179-4G7.0-10OT-T6-5977 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0 13.4000 13.2416 13.4000 14.4581 13.1829 15.6627 12.9384 16.8610 12.9122 18.0548 12.9207 19.2449 12.9377 21,6161 12.7615 22.2852 12.6855 28.3952 11.9909 34.7442 11.2691 41,2946 10.5244 47.9999 9.7621 54.8153 8.9873 61.7044 8.2041 68.6395 5.6279 70.0000 5.0000 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 28 Table 6-7: LHGR Limit for GE14-P1ODNAB409-17GZ-100T-145-T6-2825, Lattice 6828 (Reference 14)

Lattice 6828 LHGR Limit kW/ft 6828: P1ODNAL448-14G6.0/2G3.0-10OT-V-T6-6828 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0 13.40 15.0498 13.40 16.3328 13.3622 17.6026 13.2178 18.8592 13.0750 20.1044 12.9334 22.5708 12.6530 26.2373 12.2362 32.2831 11.5489 38.2384 10.8718 44.0904 10.2066 49.8351 9.5415 55.4794 8.8812 61.0422 8.2765 66.5524 6.5912 70.0 5.00 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 29 Table 6-8: LHGR Limit for GE14-P1ODNAB408-15GZ-100T-145-T6-2826, Lattice 6834 (Reference 14)

Lattice 6834 LHGR Limit kW/ft 6834: P1ODNAL448-13G6.O/1 G3.0-10OT-V-T6-6834 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0 13.40 14.7557 13.40 16.0380 13.3957 17.3111 13.2510 18.5741 13.1074 19.8276 12.9649 22.3110 12.6825 25.9974 12.2635 32.0720 11.5729 38.0552 10.8927 43.9337 10.2244 49.7028 9.5685 55.3685 8.9194 60.9492 8.2886 66.4736 6.6276 70.0 5.00 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 30 Table 6-9: LHGR Limit for GE14-P1ODNAB411-14GZ-100T-145-T6-2564, Lattice 5571 (Reference 5)

Lattice 5571 LHGR Limit kW/ft 5571: P1ODNAL451-6G7.0/7G6.0-10OT-V-T6-5571 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0 13.4000 15.9983 13.4000 17.2727 13.2553 18.5367 13.1116 19.7907 12.9691 22.2716 12.6870 25.9479 12.2691 32.0006 11.5810 37.9622 10.9032 43.8209 10.2372 49.5719 9.5726 55.2216 8.8106 60.7884 8.1396 66.3010 6.7072 70.0000 5.0000 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 31 Table 6-10: LHGR Limit for GE14-P1ODNAB409-15GZ-100T-145-T6-2565, Lattice 5577 (Reference 5)

Lattice 5577 LHGR Limit kW/ft 5577: P1ODNAL448-12G7.0/2G6.0-10OT-V-T6-5577 U02 Pellet Burnup LHGR Limit (GWd/MTU) (kW/ft) 0.0 13.4000 14.8933 13.4000 16.1803 13.3795 17.4565 13.2344 18.7218 13.0906 19.9762 12.9480 22.4568 12.6660 26.1333 12.2480 32.1885 11.5596 38.1530 10.8816 44.0146 10.2152 49.7684 9.3907 55.4205 8.7352 60.9892 8.1212 66.5031 6.6140 70.0000 5.0000 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 32 Table 6-11: LHGR Limit for GE14-P1ODNAB409-15GZ-100T-145-T6-2565, Lattice 5576 (Reference 5)

Lattice 5576 LHGR Limit kW/ft 5576: P1ODNAL448-12G7.012G6.0-10OT-E-T6-5576 U02 Pellet Burnup LHGR Limit (GWd/MTU) J (kW/ft) 0.0 13.4000 14.9599 13.4000 16.2535 13.3712 17.5365 13.2253 18.8087 13.0807 20.0704 12.9373 22.5658 12.6536 26.2623 12.2333 32.3461 11.5417 38.3361 10.8607 44.2214 10.1917 49.9984 9.4847 55.6748 8.8349 61.2700 8.2535 66.8131 6.4709 70.0000 5.0000 Table 6-12: LHGR Limit for Westinghouse Optima2 Fuel OPT2-3.99-15GZ8.00-3G6.00 OPT2-4.00-13GZ8.00-3G6.00 OPT2-4.05-12GZ7.00-2G6.00 (Reference 3)

Rod Nodal Exposure LHGR Limit (GWd/MTU) (kW/ft) 0.00 13.11 14.00 13.11 72.00 6.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 33 Table 6-13 LHGRFAC(P) for GE Fuel, DLO (Reference 3)

Core Core Thermal Power (% of rated)

EOOS Combination Flow (% 0 25 38.5 38.5 170 170 180 1100 of rated) LHGRFAC(P) Multiplier

< 60 Base - 0.50 0.56 0.59 0.68 0.86

> 60 PLUOOS_~< 60 ,,4 PLUOOS 0.54 0.54 0.54 0.54 0.73 0.78 1 00

>60

<60 0.22 0.48 TBPOOS - 0.39 0.54 1.00

> 60 0.33 0.42

<60 TCV Slow Closure 0.54 0.54 0.54 0.54 0.73 0.78 1.00

> 60 TCV Stuck Closed 0.50 0.56 0.59 0.68 0.86 1.00

> 60 Table 6-14 LHGRFAC(P) for GE Fuel, SLO (Reference 3)

Core Core Thermal Power (% of rated)

EOOS Combination Flow(% 0 25 38.5 38.5 1 70 CP* 100 of rated) LHGRFAC(P) Multiplier Base SLO < 60 0.50 0.56 0.59 0,68 0.77 0.77

> 60

<60 PLUOOS SLO 0.54 0.54 0.54 0.54 0.73 0.77 0.77

> 60 TB POOS SLO -< 60 0 0.39 0.54 . 0.77 0.77

> 60 0.33 0.42

< 60 TCV Slow Closure SLO 0.54. 0.54 0.54 0.54 0.73 0.77 0.77

> 60 Cloed TCV tuc LO < 60 ...

TCV Stuck Closed SLO < 0.50 0.56 0.59 0.68 0.77 0.77

> 60

• CP is the cutoff power level and is equal to 59.25% for Base Case SLO and TCV Stuck Closed SLO, 70%

for PLUOOS SLO, 69.25% for TBPOOS SLO, and 70% for TCV Slow Closure SLO.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 34 Table 6-15 LHGRFAC(P) for Westinghouse Fuel (Reference 3)

Core Thermal Power (% of rated)

EOOS Combination 0 25 38.5 38.5 41 50 60 80 100 102 LHGRFAC(P) Multiplier Base 0.49 0.61 0.67 0.62 0.83 0.85 0.89 0.96 1.00 1.00 Base SLO 0.49 0.61 0.67 0.82 0.83 0.85 0.89 0.96 1.00 1.00 PLUOOS 0.48 0.59 0.65 0.65 0.66 0.67 0.74 0.96 1.00 1.00 PLUOOS SLO 0.48 0.59 0.65 0.65 0.66 0.67 0.74 0.96 1.00 1.00 TBPOOS 0.24 0.46 0.58 0.82 0.83 0.85 0.89 0.95 1.00 1.00 TBPOOS SLO 0.24 0.46 0.58 0.82 0.83 0.85 0.89 0.95 1.00 1.00 TCV Slow Closure 0.48 0.59 0.65 0.65 0.66 0.67 0.74 0.96 1.00 1.00 TCV Slow Closure SLO 0.48 0.59 0.65 0.65 0.66 0.67 0.74 0.96 1.00 1.00 TCV Stuck Closed 0.49 0.61 0.67 0.82 0.83 0.85 0.89 0.96 1.00 1.00 TCV Stuck Closed SLO 0.49 0.61 0.67 0.82 0.83 0.85 0.89 0.96 1.00 1.00 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 35 Table 6-16 LHGRFAC(F) Multipliers, GE Fuel, DLO, All Cases except TCV Stuck Closed (Reference 3)

Flow LHGRFAC(F)

(% rated) Multiplier 100.0 1.00 80.0 1.00 50.0 0.77 40.0 0.64 30.0 0.55 0.0 0.28 Table 6-17 LHGRFAC(F) Multipliers, GE Fuel, DLO, TCV Stuck Closed (Reference 3)

Flow 1LHGRFAC(F)

(% rated) Multiplier 100.0 1.00 98.3 1.00 80.0 0.86 50.0 0.63 40.0 0.50 30.0 0.41 0.0 0.14 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 36 Table 6-18 LHGRFAC(F) Multipliers, GE Fuel, SLO, All Cases except TCV Stuck Closed (Reference 3)

[

(%Flow rated) 100.0 Multiplier LHGRFAC(F) 0.77 50.0 0.77 40.0 0.64 30.0 0.55 0.0 0.28 Table 6-19 LHGRFAC(F) Multipliers, GE Fuel, SLO, TCV Stuck Closed

. (Reference 3)

Flow LHGRFAC(F)

(% rated) Multiplier 100.0 0.77 68.3 0.77 50.0 0.63 40.0 0.50 30.0 0.41 0.0 0.14 Table 6-20 LHGRFAC(F) Multipliers, Westinghouse Fuel (Reference 3)

Flow LHGRFAC(F)

(% rated) Multiplier 110.00 1.00 100.00 1.00 80.00 1.00 60.00 0.80 40.00 0.59 20.00 0.43 0.00 0.27 Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 37

7. Rod Block Monitor The Rod Block Monitor Upscale Instrumentation Setpoints are determined from the relationships shown below (Reference 6):

ROD BLOCK MONITOR UPSCALE TRIP FUNCTION ALLOWABLE VALUE Two Recirculation Loop 0.65 Wd + 56.1%

Operation 0.65_W__+_56.1%

Single Recirculation Loop 0.65 Wd + 51.4%

Operation The setpoint may be lower/higher and will still comply with the rod withdrawal error (RWE) analysis because RWE is analyzed unblocked.

The allowable value is clamped with a maximum value not to exceed the allowable value for a recirculation loop drive flow (Wd) of 100%

Wd - percent of recirculation loop drive flow required to produce a rated core flow of 98.0 Mlb/hr.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 38

8. Stability Protection Setpoints The OPRM PBDA Trip Settings (Reference 3):

Corresponding Maximum PBDA Trip Amplitude Setpoint (Sp) Confirmation Count Setpoint (Np) 1.19 18 The PBDA is the only OPRM setting credited in the safety analysis as documented in the licensing basis for the OPRM system.

The OPRM PBDA trip settings are based, in part, on the cycle specific OLMCPR and the power dependent MCPR limits. Any change to the OLMCPR values and/or the power dependent MCPR limits should be evaluated for potential impact on the OPRM PBDA trip settings.

The OPRM PBDA trip settings are applicable when the OPRM system is declared operable, and the associated Technical Specifications are implemented.

Quad Cities Unit 1 Cycle 20

COLR Quad Cities 1 Revision 2 Page 39

9. Modes of Operation The allowed Modes of Operation with the combinations of EOOS are as described below:

EOS Options',Z6,8 Operating Region' Standard MELLLA CF]' Coastdown3 Base, TSSS, ISS, or NSS Yes Yes Yes Yes Base SLO, TSSS, ISS, or NSS Yes Yes No Yes TBPOOS, TSSS, ISS, or NSS Yes Yes Yes Yes TBPOOS SLO, TSSS, ISS, or NSS Yes Yes No Yes PLUOOS"'lu, TSSS, ISS, or NSS Yes Yes Yes Yes PLUQOS SLObl, TSSS, ISS, or NSS Yes Yes No* Yes TCV Slow Closure`u, TSSS, ISS, or NSS Yes Yes Yes Yes TCV Slow Closure SLO' , TSSS, ISS, or NSS Yes Yes No Yes TCV Stuck Closed"'u, TSSS, ISS, or NSS Yes Yes Yes Yes TCV Stuck Closed SLO'9 l, TSSS, ISS, or NSS Yes Yes No Yes 1 Each OOS Option may be combined with up to 18 TIP channels OOS provided the requirements (as clarified in Reference 16) for utilizing SUBTIP methodology aremet and up to 50% of the LPRMs OOS with an LPRM calibration frequency of 2500 Effective Full Power Hours (EFPH) (2000 EFPH +25%). For operation under all limit sets, a 120'F reduction in feedwater temperature throughout the cycle was analyzed and is subject to the restrictions in Reference 11 (Feedwater Temperature Reduction or Feedwater Heaters OOS).

2 Each EOOS option except TBPOOS requires the opening profile for the turbine bypass valves provided in Reference 21 to be met. These conditions also support Turbine Bypass flow of 29.6% of vessel rated steam flow, equivalent to 1 Turbine Bypass Valve OOS (or partially closed Turbine Bypass Valves equivalent to 1 closed Turbine Bypass Valve) ifthe assumed opening profile (Reference 21) for the remaining Turbine Bypass Valves is met. If the opening profile is NOT met, or if the Turbine Bypass Valve system can not pass an equivalent of 29.6%

of vessel rated steam flow, utilize the TBPOOS condition.

3 Coastdown operation is defined as any cycle exposure beyond the full power, all rods out condition with plant power slowly lowering to a lesser value while core flow is held constant. Coastdown analysis has been performed with bounding assumption of full power operation up to cycle exposure of 16,569 MWD/MTU. .

4 Operation up to 108% rated core flow is licensed for this cycle.

5 For operation with a pressure regulator out-of-service (PROOS), the TCV Slow Closure limits should be applied.

For operation with a PROOS and TCV slow closure, the TCV slow closure limits are applicable. For operation with a PROOS and PLUOOS, the PLUOOS limits are applicable. (Reference 3) 6 A single MSIV may be taken OOS (shut) under all OOS Options, so long as core thermal power is maintained

<75% of 2957 MWth (Reference 3).

7 The cycle specific stability analysis may impose restrictions on the Power-to-Flow map and/or restrict the applicable temperature for feedwater temperature reduction. See Reference 11.

8 For Base DLO and Base SLO cases, as well as all EOOS conditions, operation for both nominal FWT and up to 120'F reduction in Feedwater temperature are supported. For both Base DLO/SLO and EOOS conditions, for operation at nominal feedwater temperature, the OLMCPR limit is applicable to a variation of +10 'F/- 30'F in feedwater temperature, and an operating steam dome pressure region bounded by the maximum value of 1020 psia and the minimum pressure curve in Reference 3 report.

9 For operation with one Turbine Stop Valve (TSV) Stuck Closed, the TCV Stuck Closed limits should be applied (Reference 3). One TSV Stuck Closed and one TCV Stuck Closed is not analyzed. For TSV Stuck Closed or TCV Stuck Closed, operation above 80% rated core thermal power is not an analyzed out-of-service combination.

10 For operation with a PROOS and TCV Stuck Closed, or for operation with a PLUOOS and TCV Stuck Closed, apply the more restrictive of the flow dependent limits (established by TCV Stuck Closed) and power dependent limits (established by TCV Slow Closure and PLUOOS limits). (Reference 3).

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COLR Quad Cities 1 Revision 2 , Page 40 1

10. Methodology The analytical methods used to determine the core operating limits shall be those previously reviewed and approved by the NRC, specifically those described in the following documents:

1. Commonwealth Edison Topical Report NFSR-0085, Revision 0, "Benchmark of BWR Nuclear Design Methods," November 1990.

2. Commonwealth Edison Topical Report NFSR-0085, Supplement 1 Revision 0, "Benchmark of BWR Nuclear Design Methods - Quad Cities Gamma Scan Comparisons," April 1991.

3. Commonwealth Edison Topical Report NFSR-0085, Supplement 2 Revision 0, "Benchmark of BWR Nuclear Design Methods - Neutronic Licensing Analyses," April 1991.

4. Commonwealth Edison Company Topical Report NFSR-0091, "Benchmark of CASMO/MICROBURN BWR Nuclear Design Methods," Revision 0 and Supplements on Neutronics Licensing Analysis (Supplement 1) and La Salle County Unit 2 benchmarking (Supplement 2),

December 1991, March 1992, and May 1992, respectively:

5. Westinghouse Topical Report CENPD-300-P-A, "Reference Safety Report for Boiling Water Reactor Reload Fuel," July 1996.

6. Westinghouse Topical Report CENPD-390-P-A, "The Advanced PHOENIX and POLCA Codes for Nuclear Design of Boiling Water Reactors," December 2000.

7. Westinghouse Report WCAP-16081-P-A, "10x10 SVEA Fuel Critical Power Experiments and CPR Correlation: SVEA-96 Optima2," March 2005.

8. Westinghouse Report WCAP-1 5682-P-A, "Westinghouse BWR ECCS Evaluation Model:

Supplement 2 to Code Description, Qualification and Application," April 2003.

9. Westinghouse Report WCAP-16078-P-A, "Westinghouse BWR ECCS Evaluation Model:

Supplement 3 to Code Description, Qualification and Application to SVEA-96 Optima2 Fuel,"

November 2004.

10. Westinghouse Topical Report WCAP-1 5836-P-A, "Fuel Rod Design Methods for Boiling Water Reactors - Supplement 1," June 2002.

11. Westinghouse Topical Report WCAP-1 5942-P-A, "Fuel Assembly. Mechanical Design Methodology for Boiling Water Reactors, Supplement 1 to CENP-287," October 2004.

12. NEDE-2401 1-P-A-14 (Revision 14), "General Electric Standard Application for Reactor Fuel (GESTAR-II)," June 2000;

13. NEDO-32465-A, "Reactor Stability Detect and Suppress Solutions Licensing Basis Methodology for Reload Applications", August 1996.

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