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ANP-3215(NP), Rev. 0, Monticello Fuel Transition Cycle 28 Fuel Cycle Design (Epu/Mellla)
	ML13200A194
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Site:	Monticello
Issue date:	05/31/2013
From:	; AREVA NP
To:	; Office of Nuclear Reactor Regulation
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ML13200A185	List: L-MT-13-055, ANP-3139(NP), Rev. 1, Nuclear Fuel Design Report Monticello Cycle 28 Atrium 10XM Fuel; ML13200A187; ML13200A189; ML13200A190; ML13200A191; ML13200A192; ML13200A193; ML13200A194; ML13200A195; ML13200A196; ML13200A197; ML13200A199;
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Enclosure 15 AREVA Report ANP-3215(NP)

Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Revision 0 90 pages follow

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

May 2013 A

ARE VA AREVA NP Inc.

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ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA) sja

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ANP-3215(NP)

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Revision 0 Page i Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Nature of Changes Item Page 1.

All Description and Justification This is the initial release.

AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page ii Contents 1.0 In tro d u c tio n..................................................................................................................

1-1 2.0 S u m m a ry......................................................................................................................

2 -1 3.0 C ycle 28 Fuel C ycle D esign..........................................................................................

3-1 3.1 G eneral D escriptio n..........................................................................................

3-1 3.2 Control Rod Patterns and Thermal Limits...................................................

3-1 3.3 Hot Excess Reactivity and Cold Shutdown Margin............................................

3-1 4.0 R e fe re n c e s...................................................................................................................

4 -1 Appendix A Monticello Cycle 28 Step-Through Depletion Summary, Control Rod Patterns and Core Average Axial Power and Exposure D istrib utio ns............................................................................................

.. A -1 Appendix B Elevation Views of the Monticello Cycle 28 Fresh Reload Batch F ue l A ssem blies.......................................................................................

.. B -1 Appendix C Monticello Cycle 28 Fresh Fuel Locations..................................................

C-1 Appendix D Monticello Cycle 28 Radial Exposure and Power Distributions.................. D-1 Tables 2.1 Monticello Cycle 28 Energy and Key Results Summary...............................................

2-2 2.2 Monticello Cycle 28 Fuel Cycle Design Assembly ID Range by Nuclear F u e l T y p e.....................................................................................................................

2 -3 3.1 Cycle 28 Core Composition and Design Parameters....................................................

3-3 3.2 Monticello Cycle 28 Hot Operating Target k-eff versus Cycle Exposure....................... 3-4 3.3 Monticello Cycle 28 Cold Critical Target k-eff versus Cycle Exposure.......................... 3-4 3.4 Monticello Cycle 28 Reactivity Margin Summary..........................................................

3-5 AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page iii Figures 2.1 Monticello Cycle 28 Design Step-Through k-eff versus Cycle Exposure....................... 2-4 2.2 Monticello Cycle 28 Design Margin of Thermal Limits versus Cycle E x p o s u re......................................................................................................................

2 -4 3.1 Monticello Cycle 28 Reference Loading Pattern...........................................................

3-6 3.2 Monticello Cycle 28 Upper Left Quarter Core Layout by Fuel Type..............................

3-7 3.3 Monticello Cycle 28 Upper Right Quarter Core Layout by Fuel Type............................

3-8 3.4 Monticello Cycle 28 Lower Left Quarter Core Layout by Fuel Type.............................. 3-9 3.5 Monticello Cycle 28 Lower Right Quarter Core Layout by Fuel Type.......................... 3-10 AREVA NP Inc.

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Revision 0 Page iv Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

BOC BOL BWR Btu/lbm CPR CSDM EOC EOFP Nomenclature beginning of cycle beginning of life boiling water reactor Enthalpy, British Thermal units per pound mass critical power ratio cold shutdown margin end of cycle end of full power capability final feedwater temperature reduction gigawatt days per metric ton of initial uranium hot excess reactivity effective neutron multiplication factor (aka k-effective) linear heat generation rate FFTR GWd/MTU HEXR k-eff LHGR MCPR MICROBURN-B2 MAPLHGR Mlb/hr MTU MWd/MTU MWt NRC PPR psia R Value Ak/k minimum critical power ratio AREVA NP advanced BWR core simulator methodology with PPR capability maximum average planar linear heat generation rate million pounds per hour metric tons uranium megawatt days per metric ton of initial uranium megawatt thermal Nuclear Regulatory Commission, U. S.

Pin Power Reconstruction. The PPR methodology accounts for variation in local rod power distributions due to neighboring assemblies and control state. The local rod power distributions are reconstructed based on the actual flux solution for each statepoint.

pounds per square inch absolute pressure the larger of zero or the shutdown margin at BOC minus the minimum calculated shutdown margin in the cycle amount of reactivity AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page 1-1 1.0 Introduction AREVA NP Inc. (AREVA) has performed fuel cycle design and fuel management calculations for the Cycle 28 MELLLA operation of the Monticello BWR. These analyses have been performed with the approved AREVA neutronics methodology (Reference 1). The CASMO-4 lattice depletion code was used to generate nuclear data including cross sections and local power peaking factors. The MICROBURN-B2 three dimensional core simulator code, combined with the application of the SPCB critical power correlation (Reference 2) for GE14 fuel and the ACE critical power correlation (Reference 3, 4, and 5) for the ATRIUM 1OXM fuel, was used to model the core. The Reference 4 Supplement has been submitted to the NRC for their review.

The NRC approved methodology to demonstrate the acceptability of using the SPCB correlation for computing GE14 fuel CPR is presented in Reference 7. The MICROBURN-B2 pin power reconstruction (PPR) model was used to determine the thermal margins presented in this report.

All thermal limits used are assumed to be representative values which are expected to be supported by the licensing and safety analysis.

The Monticello Cycle 28 design was provided by Xcel Energy (Reference 6). Design results for the Cycle 28 reactor core loading including projected control rod patterns and evaluations of thermal and reactivity margins are presented. The Cycle 28 results are based on a Cycle 27 cycle projection as summarized in Table 2.1 AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page 2-1 2.0 Summary The Cycle 28 fresh batch size [

] and batch average enrichment [

] were determined by Xcel Energy to meet the energy requirements. For a complete description of the fresh reload assemblies, see Reference 8. The loading of the Cycle 28 fuel as described in this report results in a projected Cycle 28 full power energy capability of 1,337+/-25 GWd (15,775+/-300 MWd/MTU). Beyond the full power capability, the cycle has been designed to achieve 47 GWd additional energy via Coastdown operation.

The projected control rod patterns for Cycle 28 MELLLA were developed by AREVA. The cycle design calculations also demonstrate adequate hot excess reactivity and cold shutdown margin throughout the cycle. Key results from the design analysis are summarized in Table 2.1. Table 2.2 summarizes the assembly identification range by nuclear fuel type batch for the Cycle 28 design. Figures 2.1 and 2.2 provide a summary of the cycle design step-through projection.

AREVA NP Inc.

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Revision 0 Page 2-2 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table 2.1 Monticello Cycle 28 Energy and Key Results Summary Cycle Energy, GWd (Cycle Exposure, MWd/MTU)

Cycle 27 Best estimate depletion to Nominal EOC 27 1,257 (14,885)

Short window EOC 27 1,228 (14,545)

Long window EOC 27 1,277 (15,126)

Cycle 28 EOFP Energy 1,337+/-25 (15,775+/-300)

Coastdown Energy 47 (552)

EOC Energy 1,384+/-25 (16,327+/-300)

Key Results BOC CSDM, %Ak/k (based on short EOC 27) 1.17 Minimum CSDM, %Ak/k (based on short EOC 27) 1.17 Cycle Exposure of Minimum CSDM, MWd/MTU (short basis) 0 Cycle R Value, %Ak/k (short basis) 0.00 BOC HEXR, %Ak/k (based on long EOC 27) 1.54 Maximum HEXR, %Ak/k (based on long EOC 27) 1.54 Cycle Exposure of Maximum HEXR, MWd/MTU (long basis) 6,000 Minimum MAPLHGR Margin, %

15.4 Exposure of Minimum MAPLHGR Margin, MWd/MTU 6,000 Minimum LHGR Margin, %

10.4 Exposure of Minimum LHGR Margin, MWd/MTU 6,000 Minimum CPR Margin, %

8.3 Exposure of Minimum CPR Margin, MWd/MTU 15,500 AREVA NP Inc.

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Revision 0 Page 2-3 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table 2.2 Monticello Cycle 28 Fuel Cycle Design Assembly ID Range*

by Nuclear Fuel Type Nuclear Number of Assembly ID Fuel Type Assemblies Range 16

[ ]

JYH286-JYH295 18

[ ]

JYH327-JYH368 20

[ ]

JYH426-JYH429 21

[

]

JYS001-JYS032 22

[

]

JYS033-JYS072 23

[

]

JYS073-JYS104 24

[

]

JYS105-JYS148 25

[

]

mnjOl7-mnjl36 26

[

]

mnj008-mnjl45 27

[

]

mnjOO1-mnjl52 28

[

]

mnj002-mnjl5l 29

[

]

[

]

30

[

]

[

]

31

[

]

[

]

The range is simply the minimum to maximum assembly name alphanumeric sequence of each fuel type assembly group. Assembly name range overlap in the table indicates that fabricated batches were split across different cycle reload batches with different nuclear fuel types assigned.

AREVA NP Inc.

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Revision 0 Page 2-4 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA) 1.010 1.005 1.000

=,

,v,

-- Target A Cycle 28 0.995 0.990 0

2 4

6 8

10 Cycle Exposure (GWd/MTU) 12 14 16 18 Figure 2.1 Monticello Cycle 28 Design Step-Through k-eff versus Cycle Exposure 1.0 0.9 E

- 0.8 I-.

0 0.7 LL 0.6 0

2 4

6 8

10 12 14 16 18 Cycle Exposure (GWd/MTU)

Figure 2.2 Monticello Cycle 28 Design Margin of Thermal Limits versus Cycle Exposure AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page 3-1 3.0 Cycle 28 Fuel Cycle Design 3.1 General Description The assembly design for the Cycle 28 MON-28 fresh reload fuel for Monticello is described in detail in Reference 8. Elevation views of the fresh reload fuel design axial enrichment and gadolinia distributions are shown in Appendix B, Figures B.1 through B.3. The loading pattern maintains full core symmetry, with the exception of some interior locations, within a scatter load fuel management scheme. This loading in conjunction with the control rod patterns presented in Appendix A shows acceptable power peaking and associated margins to limits for projected Cycle 28 operation. The analyses supporting this fuel cycle design were based on the core parameters shown in Table 3.1. Figures 3.1 through 3.5, along with Table 3.1 define the reference loading pattern used in the fuel cycle design. The specific core location of the fresh assemblies in Cycle 28 is provided in Appendix C. Key results for the cycle are summarized in Table 2.1.

3,2 Control Rod Patterns and Thermal Limits Projected control rod patterns for Cycle 28 and resultant key operating parameters including thermal margins are shown in Appendix A. The thermal margins presented in this report were determined using the MICROBURN-B2 3D core simulator PPR model and provide adequate margin to the assumed thermal limits. A detailed summary of the core parameters resulting from the step-through projection analysis is provided in Tables A.1 and A.2. Limiting results from the step-through are summarized in Table 2.1 and in Figure 2.2. The hot operating target k-eff versus cycle exposure which was determined to be appropriate for Cycle 28 is shown in Table 3.2. The k-eff and margin to limits results from the design cycle depletion are presented graphically in Figures 2.1 and 2.2. The k-eff values presented in Figure 2.1 and in Appendix A are not bias corrected. Selected exposure and radial power distributions from the design step-through are presented in Appendix D.

3.3 Hot Excess Reactivity and Cold Shutdown Margin The cycle design calculations demonstrate adequate hot excess reactivity and cold shutdown margin throughout the cycle. Key shutdown margin and R-Value results are presented in Table 2.1. The shutdown margin for Cycle 28 is in conformance with the Technical Specification limit of R + 0.38 %Ak/k. The cold target k-eff versus exposure determined to be appropriate for calculation of cold shutdown margin in Cycle 28 is shown in Table 3.3. The core hot excess AREVA NP Inc.

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Revision 0 Page 3-2 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA) reactivity was calculated at full power with all rods out, 57.60 Mlb/hr core flow, (100% of rated) with equilibrium xenon. Table 3.4 summarizes the Cycle 28 reactivity margins versus cycle exposure.

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Revision 0 Page 3-3 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table 3.1 Cycle 28 Core Composition and Design Parameters Cycle Nuclear Number of Fuel Description Loaded Fuel Type Assemblies GE-14 GE14-P1ODNAB392-16GZ-100T-145-T6 (2931) 25 16

[ ]

GE-14 GE14-P1ODNAB375-16GZ-100T-145-T6 (3101) 25 18

[ ]

GE-14 GE14-P1ODNAB391-12GZ-100T-145-T6 (3103) 25 20

[ ]

GE-14 GE14-P1ODNAB373-16GZ-100T-145-T6 (3375) 26 21

[

]

GE-14 GE14-P1ODNAB391-16GZ-100T-145-T6 (3376) 26 22

[

]

GE-14 GE14-P1ODNAB391-15GZ-100T-145-T6 (3377) 26 23

[

]

GE-14 GE14-P10DNAB391-12GZ-100T-145-T6 (3378) 26 24

[

]

GE-14 GE14-P1ODNAB376-17GZ-100T-145-T6 (11201) 27 25

[

]

GE-14 GE14-P1ODNAB390-16GZ-100T-145-T6 (11203) 27 26

[

]

GE-14 GE14-P1ODNAB391-11GZ-100T-145-T6 (11204) 27 27

[

]

GE-14 GE14-P10DNAB390-16GZ-100T-145-T6 (21202) 27 28

[

]

ATRIUM TM 1OXM* [

]

28 29

[

]

ATRIUM 1OXM[

]

28 30

[

]

ATRIUM 1OXM[

]

28 31

[

]

Number of Fuel Assemblies in Core 484 Total Number of Fresh Assemblies

[

]

Total Core Mass, MTU 84.76 Rated Thermal Power Level, MWt 2,004 Rated Core Flow, MIb/hr 57.60 Reference Pressure, psia 1,0251 Reference Inlet Subcooling, Btu/Ibm 19 - 26*

ATRIUM is a trademark of AREVA NP.

t Value is representative of MICROBURN-B2 input for dome pressure at rated conditions and varies depending on core state point.

Value is typically determined by MICROBURN-B2 using a heat balance method based on nominal feedwater temperature and other parameters identified in the cycle specific plant parameters document.

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Revision 0 Page 3-4 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table 3.2 Monticello Cycle 28 Hot Operating Target k-eff versus Cycle Exposure Cycle Exposure Hot Operating (MWd/MTU) k-eff*

0.0 1.0035 6,000.0 0.9975 10,000.0 0.9975 14,000.0 0.9990 20,000.0 0.9990 Table 3.3 Monticello Cycle 28 Cold Critical Target k-eff versus Cycle Exposure Cycle Exposure Cold Critical (MWd/MTU) k-eff*

0.0 0.9950 4,000.0 0.9930 20,000.0 0.9930 Values are linearly interpolated between cycle exposure points.

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Revision 0 Page 3-5 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table 3.4 Monticello Cycle 28 Reactivity Margin Summary Cold Shutdown Hot Excess Cycle Exposure Margin*

Reactivityt (MWd/MTU)

(% Ak/k)

(% Ak/k) 0 1.17 1.54 220 1.31 1.47 1,000 1.58 1.38 2,000 1.74 1.42 3,000 1.82 1.44 4,000 1.99 1.45 5,000 2.25 1.47 6,000 2.46 1.52 7,000 2.76 1.49 8,000 2.80 1.47 9,000 2.85 1.46 10,000 2.82 1.45 11,000 2.73 1.41 12,000 2.58 1.37 13,000 2.39 1.22 14,000 2.15 0.89 15,000 2.28 0.35 15,775 2.09 16,000 2.10 Based on short window EOC 27 and most limiting value based on various temperatures between 68"F and 2201F.

t Based on long EOC 27.

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I I

Figure 3.1 Monticello Cycle 28 Reference Loading Pattern AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page 3-7

[

I No.

Per Quarter core Fuel Type Description Cycle Loaded 16 18 20 21 22 23 24 25 26 27 28 29 30 31 GE14-21ODNAB392-16GZ-100T-145-T6 GE14-P1ODNAB375-16GZ-100T-145-T6 GE14-P1ODNAB391-12GZ-100T-145-T6 GE14-P1ODNAB373-16GZ-100T-145-T6 GE14-P1ODNAB391-16GZ-100T-145-T6 GE14-P1ODNAB391-15GZ-100T-145-T6 GE14-P1ODNAB391-12GZ-100T-145-T6 GE14-PIODNAB376-17GZ-100T-145-T6 GE14-PIODNAB390-16GZ-100T-145-T6 GE14-P1ODNAB391-11GZ-100T-145-T6 GE14-PIODNAB390-16GZ-100T-145-T6 (2931)

(3101)

(3103)

(3375)

(3376)

(3377)

(3378)

(11201)

(11203)

(11204)

(21202) 25 25 25 26 26 26 26 27 27 27 27 28 28 28

((

[

I Figure 3.2 Monticello Cycle 28 Upper Left Quarter Core Layout by Fuel Type AREVA NP Inc.

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I I

Fuel Type Description No.

Per Quarter core Cycle Loaded 16 18 20 21 22 23 24 25 26 27 28 29 30 31 GE14-PIODNAB392-16GZ-100T-145-T6 GE14-FIODNAB375-16GZ-100T-145-T6 GEl4-P1ODNAB391-12GZ-100T-145-T6 GE14-PlODNAB373-16GZ-100T-145-T6 GE14-PlODNAB391-16GZ-10OT-145-T6 GEI4-PlODNAB391-15GZ-100T-145-T6 GE14-PlODNAB391-12GZ-100T-145-T6 GE14-PlODNAB376-17GZ-100T-145-T6 GE14-PlODNAB390-16GZ-100T-145-T6 GE14-PIODNAB391-11GZ-100T-145-T6 GE14-PlODNAB390-16GZ-100T-145-T6 (2931)

(3101)

(3103)

(3375)

(3376)

(3377)

(3378)

(11201)

(11203)

(11204)

(21202) 25 25 25 26 26 26 26 27 27 27 27 28 28 28

((

[

]

Figure 3.3 Monticello Cycle 28 Upper Right Quarter Core Layout by Fuel Type AREVA NP Inc.

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Fuel Type Description Cycle Loaded No.

Per Quarter core 16 18 20 21 22 23 24 25 26 27 28 29 30 31 GE14-PIODNAB392-16GZ-lQ0T-145-T6 GE14-P1ODNAB375-16GZ-100T-145-T6 GE14-P1ODNAB391-12GZ-100T-145-T6 GEI4-PlODNAB373-16GZ-100T-145-T6 GE14-PlODNAB391-16GZ-100T-145-T6 GEI4-PlODNAB391-15GZ-100T-145-T6 GE14-PlODNAB391-12GZ-100T-145-T6 GE14-P1ODNAB376-17GZ-100T-145-T6 GEl4-PIODNAB390-16GZ-100T-145-T6 GE14-PIODNAB391-11GZ-100T-145-T6 GEl4-PlODNAB390-16GZ-100T-145-T6 (2931)

(3101)

(3103)

(3375)

(3376)

(3377)

(3378)

(11201)

(11203)

(11204)

(21202) 25 25 25 26 26 26 26 27 27 27 27 28 28 28

((

[

))

]

Figure 3.4 Monticello Cycle 28 Lower Left Quarter Core Layout by Fuel Type AREVA NP Inc.

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Fuel Type Description No.

Per Quarter core Cycle Loaded 16 18 20 21 22 23 24 25 26 27 28 29 30 31 GE14-PlODNAB392-16GZ-100T-145-T6 GE14-PIODNAB375-16GZ-100T-145-T6 GE14-P1ODNAB391-12GZ-10OT-145-T6 GEl4-P1ODNAB373-16GZ-10OT-145-T6 GEI4-PlODNAB391-16GZ-10OT-145-T6 GE14-PIODNAB391-15GZ-10OT-145-T6 GE14-PlODNAB391-12GZ-10OT-145-T6 GE14-P1ODNAB376-17GZ-10OT-145-T6 GE14-PlODNAB390-16GZ-10OT-145-T6 GE14-PIODNAB391-11GZ-100T-145-T6 GE14-PlODNAB390-16GZ-100T-145-T6 (2931)

(3101)

(3103)

(3375)

(3376)

(3377)

(3378)

(11201)

(11203)

(11204)

(21202) 25 25 25 26 26 26 26 27 27 27 27 28 28 28

((

[

))

]

Figure 3.5 Monticello Cycle 28 Lower Right Quarter Core Layout by Fuel Type AREVA NP Inc.

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Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page 4-1 4.0 References

1.

EMF-2158(P)(A) Revision 0, Siemens Power Corporation Methodology for Boiling Water Reactors: Evaluation and Validation of CASMO-4/MICROBURN-B2, Siemens Power Corporation, October 1999.

2.

EMF-2209(P)(A) Revision 3, SPCB Critical Power Correlation, AREVA NP, September 2009.

3.

ANP-10298PA Revision 0, ACE/ATRIUM 1OXM Critical Power Correlation, AREVA NP, March 2010.

4.

ANP-1 0298PA Revision 0, Supplement 1 P Revision 0, Improved K-factor Mode/ for ACE/A TRIUM IOXM Critical Power Correlation, AREVA NP, December 2011.

5.

ANP-3138(P) Revision 0, Monticello Improved K-factor Model for ACE/ATRIUM IOXM Critical Power Correlation, AREVA NP, August 2012.

6.

Letter, D. J. Mienke (Xcel Energy) to A. W. Will (AREVA), "Transmittal of Requested Monticello Cycle 28 Reload Design Information," OC-FAB-ARV-MN-XX-2012-013, March 26, 2012. (38-2200994-000)

7.

EMF-2245(P)(A) Revision 0, Application of Siemens Power Corporation's Critical Power Correlations to Co-Resident Fuel, Siemens Power Corporation, August 2000.

8.

ANP-3139(P) Revision 1, Nuclear Fuel Design Report Monticello Cycle 28 ATRIUM TM IOXM Fuel, AREVA NP, May 2013.

AREVA NP Inc.

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Revision 0 Page A-1 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Appendix A Monticello Cycle 28 Step-Through Depletion Summary, Control Rod Patterns and Core Average Axial Power and Exposure Distributions AREVA NP Inc.

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Revision 0 Page A-2 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table A.1 Monticello Cycle 28 Design Depletion Summary Cycle Exposure (GWd/MT)

Total Control Core Calculated Rod Power K-eff Density MWt:

Total Core Flow (Mlb/hr)

Inlet Ref.

Sub-Pressure Cooling (psia)

(Btu/ib)

Core Core Core Maximum Maximum Minimum LHGR APLHGR CPR (kW/ft)

(kW/ft)

Void Fraction 0.000 0.220

0. 500 1.000 1.500 2.000 2.500 3.000 3.307 3.500 4'.000 4. 500 5.000 5.500 6.000 6.063 6.500 7.000 7.500 8.000 8.500 8.818 9.000 9.500 10.000 10.250 10.472

10. 500 10.000 11.500 12.000

12. 500 13.000 13.117 13.500 13.750 14.000 14.220 14.500 14.750 15.000 15.250 15.500 15.775 15.900 16.000 16.327 1 00332 1.00309 1.00279 1.00264 1.00209 1.00132 1.00089 1.00052 1.00003

0. 99984

0. 99934

0. 99879

0. 99833

0. 99786 0.99751

0. 99729 0.99732 0.99732 0.99753 0.99757 0.99744 0.99737 0.99737 0.99737 0.99736

0. 99750

0. 99765

0. 99766

0. 99774 0.99811

0. 99816

0. 99843 0.99854 0.99849 0.99861 0.99869 0.99988 0.99878 0.99881 0.99853 0.99879 0.99878 0.99883 0.99892 0.99884 0.99845 0.99882 4.82 4.82 4.82 4.82

4. 82 4.96 4.96 4.96 5.79 5.79 5.79 6.13 6.13 6.13 6.20 6.40 6.40 6.40

6. 40 6.40 6.40

6. 34 6.34 6.40 6.40 6.40 4. 96 4. 96 4. 96 4.96 4.96 4.96 4.68 5.37 5.23 5.23 5.10 4.13 3.31

3. 31 2.75

2. 62

1. 38 0.00 0.00 0.00 0.00 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004. 0 2004.0 2004. 0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004.0 2004. 0 2004.0 2004.0 2004.0 2004.0 1863.7 57.06 58.22 59.82 59.58 57.55 58.80 57.63 57.02

57. 38 57.43 57.17 58.63 58.31 57.71 58.20 57.60 57.84 58.20 58.64 58.90 58.61 57.51 57.53 58.08 57.85 58.03 58.07 58.20 58.45 59.03 59.27 60.47 59.71 59.60 58.65 60.00 59.25 59.12 58.41 60.48 59.97 60.10 59.61

57. 69 59.64 60.48 60.48 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1024.60 1011.79

- 3.99 3.37

.68 22.79 23.67 23.12 23.63

23. 91 23.75 23.72 23.84 23.19 23.33

'3.59 23.39 23.64 23.54 23.38 23.19 23.07 23.20 23.69 23.68 23.43 23.53 23.45 2.43

.38

-3.27 2

3.

0 2 2.91 22.42 22.73 22.77

23. 18 22.61 22.92 22.98 23.29 22.41 22.62 22.57 22.77 23.60 22.76 22.41 20.83 0.470 0.461 0.454 0.452 0.455 0.453 0.453 0.452 0.457 0.456 0.455 0.452 0.452 0.454 0.454 0.447 0.445 0.445 0.443 0.442 0.442 0.441 0.440 0.434 0.429 0.425 0.445 0.444 0.433 0.421 0.410 0.396 0.384 0.369 0.361 0.353 0.347 0.369 0.364 0.355 0.347 0.338 0.341 0.344 0.337 0.334 0.317 I. a18 1.816 1 832 1 832 1.811 1.877 1.867 1.868 1.764 1.778 1.802 1.830 1.852 1.899 1.874 1.896 1.926 1.948 1.960 1.962

1. 90H 1.908 1.903 1.885 1.881

1. 980 1.981

1. 9.1 1.969 1.952 1.939 1.913 1.774 1.782 1.800 1.769 1.831 1.840 1.858 1.931 1. 795 1.735 1.740 1.758 1.765 1.88P 11.54 11.16 10.98 10.85 10.72 10.76 10.64 10.55 11.22 11.13 11.06 11.24 11.34 11 49 11.77 11.18 11.27 11.37 11. 37 1.21 10.87 10.97 10.87 10.54

10. 19 10.07 10.85 10.81 10.07 9.38 8.78 8.88 9.10 9.34 9.43 9.48 9.66 9.52 9.52 9.59 9.50 9.74 9.78 9.89

9. 95 9.96 9.41 8.47 8.21 8.11 8.08 8.03 8.12 8.09 8.08

8. 62 8.59 8.67 8.89 9.05 9.30 9.65 9.03 9.19 9.40 9.56 9.59 9.42 9.35 9.24 8.89 8.75

8. 68 9.35 9.32 8.72 6.13 7.52 7.85 8.09 8.38 8.47 8.52 8.58 8.53 8.53 8.58 8.49 9.66 8.71 8.73 8.78 8.79 8.34 AREVA NP Inc.

uontrovied Uocument ANP-3215(NP)

Revision 0 Page A-3 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Table A.2 Monticello Cycle 28 Design Depletion Thermal Margin Cycle Exposure (GWd/MT) 0.000 0.220 0.500 1.000 1.500 2.000 2.500 3.000 3.307 3.500 4.000 4.500 5.000

5. 500 6.000 6.063 6.500 7.000 7.500 8.000 8.500 8.818 9.000 9.500 10.000 10.250 10.472 10.500 11.000 11.500 12.000 12.500 13.000 13.117 13.500 13.750 14.000 14.220 14.500 14.750 15.000 15.250 15.500 15.775 15.900 16.000 16.327 Cal cu lIated K-eff 1.00332 1.00309 1.00279 1.00264 1.00209 1.00132 1.00089 1.00052 1.00003

0. 99984

0. 99934 0.99879 0.99833 0.99786 0.99751 0.99729 0.99732 0.99732 0.99753 0.99757 0.99744 0.99737 0.99737 0.99737 0.99736 0.99750 0.99765 0.99766 0.99774 0.99811

0. 99816

0. 99843

0. 99854 0.99R49 0.99861 0.99869 0.99888 0.99878

0. 99881

0. 99853 0.99879 0.99878 0.99883

0. 99892

0. 99884

0. 99845 0.99882 Control Rod Density 4.821 4.821 4.821 4.821 4.821 4.959 4. 959 4.959 5.785 5.785 5.785 6.129 6.129 6.129 6.198 6.405 6.405 6.405 6.405 6.405 6.405 6.336 6.336 6.405 6.405 6.405 4.959

4. 959 4.959 4.959 4.959 4.959 4.683 5.372 5.234 5.234 5.096 4.132 3.306 3.30b 2.755 2.617 1.377 0.000 0.000 0.000 0.000 Core Limiting CPR 1.818 1.816 1.832 1.832 1.811 1.877 1.867 1.868 1.764 1.778 1.802 1.830 1.852 1.869 1.893 1.874 1.896 1.926 1.948 1.960 1.962 1.908 1.908 1.903 1.885 1.881

1. 980 1.981 1.981

1. 969 1.952 1.939

1. 913 1.774 1.782 1.800 1.769 1.831 1.840 1.858 1.831 1.795 1.735 1.740 1.758 1.765 1.888 Summary Fraction of Limiting CPR 0.874 0.875 0.868 0.868 0.878 0.847 0.851 0.851 0.901 0.894 0.882 0.869 0.858 0.851 0.840 0.848 0.838 0.825 0.816 0.811 0.810 0.833 0.833 0.835 0.843 0.845 0.803 0.803 0.802 0.808 0.814 0.820 0.831 0.896 0.892 0.883 0.899 0.868 0.864 0.856 0.869 0.886 0.917 0.914 0.905 0.901 0.842 Core Limiting LHGR (k1W/f t) 11.54 11.16 10.98 10.85 10.72 8.21 8.10 8.05 7.84 7.72 8.40

8. 51 8.55 8. 62 8.78 8.42 8.46 8.50 8.48

8. 37 8.19 7.99 7.86 7.82 7.70

7. 62 8.06 8.03 7.47 6.93

5. 64 5.83 5. 21 6.53 6.71 6.78 6.87 6.72 6.71 6.76 6. 92 7.03 6.94 6.84 6.88 6.88

6. 50 Fraction of Limiting LHGR 0.819 0.792 0.779 0.770 0. 7 60 0.764 0.762 0.763 0.823 0.813 0.816 0.836 0.850 0.868 0.896 0.844 0.857 0.872 0.881 0.881 0.868 0.854 0.844 0.835 0.833 0.830 0.859 0.856 0.807 0.756 0.722 0.729 0.741 0.791 0.802 0.815 0.831 0.812 0.816 0.828 0.830 0.847 0.848 0.846 0.854 0.857 0.816 Core Limiting APLHGR (kW/ft) 8.15 7.88 7.77

7. 66 7.55 7.56 7.45 7.37 8.17 8.03 7.85 7.92 7.85 7.94 8.10 7.79 7.85 7.90 7. 90 7.81 7. 60 7.43 7.31 7.32 7.22 7.15 7.45 7.43

6. 93 5.36 5.44 5.77

5. 98 6.27 6.45 6.53

6. 62 6.43 6.42 6.47 6.60

6. 70

6. 69

6. 62

6. 67

6. 68 6.32 Fraction of Limiting APLHGR 0.815 0.788 0.776 0.765 0.754 0.756 0.747 0.739 0.816 0.803 0.786 0.794 0.804 0.821 0.846 0.798 0.811 0.825 0.834 0.833 0.820 0.807 0.797 0.794 0.792 0.789 0.802 0.799 0.754 0.708 0.688 0.701 0.726 0.771 0.784 0.797 0.812 0.792 0.796 0.807 0.807 0.824 0.829 0.823 0.831 0.834 0.794 AREVA NP Inc.

(Jontrolled Uccument ANP-3215(NP)

Revision 0 Page A-4 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWL Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 1

3 5

7 9 11 13 15 1

3 5

7 9

..- 14 12 --

11---------------

13 12-------

15-----------------

17

..- 14 12 --

19 21 28 0.0 0.00 0.0 0.00 2004.0 (100.00 %)

1024.6

-23.89 57.06 ( 99.05 M) 17 19 21 23 25 Core Average Exposure: MWd/MTU 17056.6 14 14 --------

51 47 43 39 35 31 27 23 19 15 11 7

Axial Profile N(PRA)

Power Exposure Top 24 0.127 2.328 23 0.303 5.069 22 0.519 10.140 21 0.654 13.059 20 0.759 15.276

JR 19 0.817 16.986 19 0.833 17.993 17 0.835 18.974 16 0.830 19.153 15 0.854 19.922 14 0.928 20.092 13 1.001 19.708 12 1.078 20.404 11 1.172 20.R61 10 1.266 20.961 9

1.367 20.999 8

1.459 21.236 7

1.535 21.398 6

1.603 21.695 5

1.616* 21.874*

4 1.583 21.181 3

1.450 18.829 1.104 14.260 Bottom 1

0.307 4.182 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR JR 0.263 0.270 47 40 0.234 0.244 21 2

0.228 0.230 51 32 0.468 0.625 33 48 0.651 1.178 11 28 0.905 1.287 27 28 0.685 1.217 41 28 1.114 1.294 31 24 1.128 1.330 39 30 1.164 1.255 43 30 1.212 1.377 27 30 1.297 1.347 29 30 1.270 1.345 39 32 1.121 1.261 43 28 23 25 IR: 2 3

6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow ():

Source Convergence 4.82 1.00332 0.470 22.398 17.964 545.8

49. 62 13.0 3.5 0.00032

% AXIAL TILT -29.504

-12.149 AVG BOT 8ft/O2ft 1.1971 1.1233 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 47,60 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT 1 377 28 1 376 28 1.347 29 1.345 30 1.340 30 1.330 26 1.324 30 1.323 29 1.322 26 1.321 28 IR JR 27 30 29 28 29 30 39 32 31 40 39 30 41 30 39 28 29 40 37 28 MCPR Value Margin FT IF JR 1.818 0.874 28 27 30 APLHGR Value Margin Exp.

FT IR JR K

8.15 0.815 23.0 28 39 20 4

1.821 1.894

1. 903

1. 905 1.914 1.915 1.922 1.922 1.926 0.873 28 0.840 26 0.836 28 0.835 26 0.831 28 0.830 28 0.827 26 0.827 28 0.825 28 29 28 39 30 37 28 29 40 27 38 11 22 37 22 21 12 39 34 8.10 9.09 8.09 8.05 8.02 7.89 7.33 7.82 7.81 0.810 23.2 28 0.809 25.3 28 0.808 25.4 26 0.805 25.3 28 0.801 25.4 26 0.788 24.4 26 0.782 24.6 26 0.781 23.7 28 0.781 24.0 27 33 40 41 32 39 30 31 42 23 40 37 22 21 16 37 26 43 30 4

5 4

4 4

45 Value Margin 11.54 0.819 11.51 0.816 11.49 0.815 11.45 0.812 11.37 0.806 11.28 0.800 11.26 0.799 11.17 0.792 11.15 0.790 8.86 0.790 LHGR Exp.

FT 0.0 30 0.0 30 0.0 30 0.0 30 0.0 29 0.0 29 0.0 29 0.0 29 0.0 30 21.0 26 IR JR 39 22 41 30 21 40 23 42 37 30 29 38 39 28 27 4 0 37 20 13 30 Y

5 5

55 5

5 5

4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.1 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 0.0 MWd/MTU AREVA NP Inc.

tJontrolled uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-5 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 220.0

(

18.65 220.0

(

18.65 2004.0 (100.00 8) 1024.6

-23.37 58.22 (101.07 %)

Core Average Exposure: MWd/MTU 17276.7 1

3 5

7 9 11 13 15 17 19 21 23 25 1

35 7

9 13 15 17 19 21 23 25 IR:

2 14 12 12..

14 12 6 10 14 18 22 26 14 12 14 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.133 2.357 23 0.317 5.142 22 0.545 10.269 21 0.685 13.222 20 0.794 15.464

JR 19 0.852 17.088 18 0.865 18.199 17 0.864 19.180 16 0.855 19.357 15 0.876 20.132 14 0.948 20.295 13 1.017 19.917 12 1.090 20.629 11 1.179 21.105 10 1.266 21.223 9

1.361 21.282 8

1.444 21.537 7

1.511 21.714 6

1.567 22.013 5

1.569* 22.205*

4 1.525 21.503 3

1.389 19.124 2

1.056 14.484 Bottom 1

0.294 4.244 Edit Zone 16 18 20 21 222,3 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.265 0.271 47 0.235 0.246 21 0.230 0.231 51 0.470 0.626 3

0.653 1.176 11 0.906 1.291 27 0.687 1.215 41 1.117 1.297 23 1.130 1.330 39 1.165 1.253 43 1.215 1.382 27 1.295 1.346 29 1.274 1.340 39 1.116 1.254 43 JR 40 2

32 48 28 28 28 32 30 30 30 30 32 28 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

(%):

Total Water Rod Flow (%):

Source Convergence 4.82 1.00309 0.461 23.002 18.568 545.8 50.68 12.9 3.5

0. 00032

% AXIAL TILT -27.093 -12.280 AVG BOT 8ft/12ft 1.1841 1.1236 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.64 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.382

1. 38)

1. 346 1.34)

1. 336 1.33) 1.32' 1.322 1.319 1.31)

Power e FT 28 0 28 t 29 0 30 6 30 0 26 4 28 226 9 29 8 26 IR 27 29 29 39 31 39 37 29 39 37 JR 30 28 30 32 40 30 28 40 28 32 Value 1.816 1.819 1.901 1.912 1.923 1.933 1.938 1.943 1.950 1.954 MCPR Margin FT 0.875 28 0.874 25 0.836 28 0.832 28 0.827 26 0.822 26 0.820 23 0.818 26 0.815 26 0.814 28 IR 27 29 37 27 39 29 27 37 21 39 JR 30 28 28 38 30 4028 22 38 14 Value 7.88 7.88 7.85 7.85 7.84 7.79

7. 66

7. 62 7.61 7.57 Margin 0.788 0.788 0.785 0.784 0.784 0.778 0.766 0.761 0.760 0.757 APLHGR 23.4 25.7 24.4 25.7 S26. 3 625.4 125. 6 24.5 24.9 FT 28 28 28 26 28I 26

Ž6 26 27 28 IR 39 41 33 39 31 29 37 21 43 37 JR 20 32 40 30 42 40 22 38 30 28 K

4 5

5 5

55 5

5 55 Value 11.16 11.13 11.11 11.07 10.99 10.90 10.89 8.54 8.57 8.49 Margin 0.792 0.789 0.788 0.785 0.779 0.773 0.772 0.770 0.767 0.766 LHGR Exp.

FT 0.6 30 0.6 30 0.6 30 0.6 10 0.6 29 0.6 29 0.6 29 22.1 26 21.4 28 22.2 26 IR 39 41 21 23 37 29 39 13 11 29 JR 32 30 40 42 30 38 28 30 22 14 K

5 5

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.2 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 220.0 MWd/MTU AREVA NP Inc.

Uontrolled Ucocument ANP-3215(NP)

Revision 0 Page A-6 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 500.0 42.38 280.0 23.73 2004.0 (100.00 %)

1024.6

-22.6n 59.82 (103.85 9) 15 17 19 21 23 25 Core Average Exposure:

MWd/MTU 17556.7 1

3 5

7 9

1 3

5 7

9 13 15 17 19 21 23 25 IR: 2 14 12 14 11 13

-- 12 12 22 26 30 14---------

12 14-------

51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA) Power Exposure Top 24 0.138 2.395 23 0.32.9 5.240 22 0.565 10.440 21 0.708 13.437 20 0.818 15.713

JR 19 0.874 17.355 18 0.884 13.469 17 0.880 19.449 16 0.867 19.623 15 0.8R6 20.404 14 0.958 20.559 13 1.025 20.186 12 1.095 20.916 11 1.180 21.415 10 1.264 21.556 9

1.355 21.640 8

1.434 21.916 7

1.495 22.110 6

1.545' 22.424 5

1.541 22.615' 4

1.490 21.901 3

1.353 19.485 2

1.029 14.759 Bottom 1

0.288 4.320 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.264 0.270 47 0.234 0.244 21 0.229 0.230 51 0.468 0.624 33 0.653 1.176 11 0.905 1.288 27 0.686 1.216 41 1.117 1.299 23 1.131 1.332 39 1.167 1.254 43 1.216 1.381 27 1.295 1.345 29 1.274 1.341 39 1.115 1.254 43 JR 40 2

32 48 28 29 28 32 30 30 30 30 32 28 34 3 6 10 14 18 8 42 46 50 Control Rod Density:

8 k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (1):

Total Water Rod Flow (6)

Source Convergence 4.82 1.00279 0.454

23. 911 19.476 545.8 52.13 12.9 3.5 0.00033

% AXIAL TILT -25.575 -12.411 AVG BOT 9ft/12ft 1.1753 1.1238 Active Channel Flow: MIb/hr (of total core flow)

(of total core flow) 50.04 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR LHGR Value 1.381 1.379 1.345 1.341 1.337 1

. 332 1.326 1.325 1.322 1.320 FT 28 28 29 30 30 26 28 26 26 29 IR JR 27 30 29 28 29 30 39 32 31 40 39 30 37 28 29 40 37 32 39 28 Value 1.832 1.835 1.912 1.923 1.952 1.954 1.954 1.961 1.962 1.970 Margin 0.868 0.867 0.831 0.827 0.815 0.814 0.814 0.811 0.810 0.807 FT 28 28 28 28 26 23 26 26 26 26 IP 27 29 37 27 39 27 37 21 29 35 JR 30 28 28 38 30 28 22 38 40 30 Value Margin 7.77 0.776 7.75 0.775 7.73 0.773 7.73 0.772 7.73 0.772 7.67 0.766 7.54 0.753 7.50 0.750 7.49 0.748 7.46 0.745 Exp.

26.3 24.9 26.3 25.0 26.9 26.9 25.9 25.0 26.3 25.0 FT 28 28 28 28 26 26 2 6 27 26 27 IR 41 39 31 33 39 29 37 43 31 23 JR 32 34 42 40 30 40 22 30 38 44 K

5 5

Value Margin 10.98 0.779 10.95 0.777 10.92 0.775 10.89 0.773 10.79 0.765 8.41 0.763 8.44 0.760 10.70 0.759 8.36 0.759 10.69 0.758 Exp.

1.4 1.4 1.4 1.4 1.4 22.8 22.1 1.4 22.9 1.4 FT 30 30 30 30

,9 26 28 2926 29 IR JR 39 32 41 30 21 40 23 42 37 30 13 30 11 22 29 38 29 14 39 28 K

5 5

55 5

5 5

5 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.3 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 500.0 MWdIMTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-7 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (Gwd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr Core Average Exposure: MWd/MTU 18056.7 1000.0

(

84.76 500.0 (

42.38 2004.0 (100.00 6) 1024.6

-22.79 59.58 (103.43 %)

1 3

5 7

9 11 13 15 17 19 21 23 25 1

3 5

7 9

11 13 15 17 19 21 23

-14 12 12 14 14 12 14 --

51 47 43 39 35 31 27 23 19 15 11 7

Axial Profile N(PRA) Power Exposure Top 24 0.144 2.465 23 0.341 5.422 22 0.585 10.757 21 0.731 13.834 20 0.840 16.170

JR 19 0.893 17.842 18 0.899 18.961 17 0.891 19.938 16 0.875 20.104 15 0.892 20.894 14 0.961 21.032 13 1.026 20.668 12 1.092 21.431 11 1.174 21.969 10 1.254 22.149 9

1.342 22.275 8

1.417 22.588 7

1.475 22.810 6

1.523' 23.147 5

1.520 23.336*

4 1.471 22.599 3

1.339 20.119 1.025 15.243 Bottom 1

0.290 4.456 Edit Zone 16 18 20 21 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR JR 0.262 0.268 47 40 0.231 0.242 21 2

0.226 0.228 51 32 0.465 0.620 33 48 0.651 1.176 11 28 0.901 1.279 27 28 0.683 1.216 41 28 1.113 1.296 29 32 1.130 1.332 39 30 1.167 1.253 43 30 1.215 1.374 27 30 1.301 1.348 29 30 1.280 1.349 39 32 1.118 1.260 43 28 25 IR:

2 6

10 14 18 22 26 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F in Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

():

Source Converqence 30 34 38 42 46 50 4. 82 1.00264 0.452 23.730 19.295 545.8 51.92 Active 12.8 (of lot 3.5 (of tot 0.00029 3

% AXIAL TILT -24.355 -12.595 AVG BOT 8ft/12ft 1.1673 1.1239 Channel Flow: Mlb/hr tal core flow) tal core flow) 49.85 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT 1.374 28

1. 372 28 1.349 30 1.348 29 1.345 30 1.332 26 1.328 29 1.326 28 1.326 30 1.325 29 IR 27 29 39 29 31 39 39 37 41 37 JR 30 28 32 30 40 30 28 28 30 30 Value 1.832 1.834 1.901 1.910 1.940 1.946 1.951 1.953 1.959 1.961 MCPR Margin FT 0.868 28 0.867 28 0.836 28 0.832 28 0.820 26 0.817 26 0.815 26 0.914 23 0.812 26 0.811 26 IR

-17 29 37 27 37 21 39 27 35 29 JR 30 28 28 3822 38 30 28 30 40 APLHGR Value

7.

6 7.6 2 7.62 7.61

7. 60 7.55 7.41 7.39

7. 37 7.35 Margin 0.765 0.762 0.761 0.760 0.759 0.754 0.740 0.739 0.736 0.734 Exp.

27.3 25.9 27.3 27. 9 26.0 27.9 26.0 26.9 25.9 27.2 FT 28 28 28 26 28 26 27 26 27 26 IR JR 41 33 39 34 31 42 39 30 33 40 29 40 43 30 37 22 23 44 31 38 K

5 5

Value 10.85 10.84 10.79 10.78 8.28

8. 32 8.23 8.29 10.64 10.55 LHGR Margin Exp.

FT 0.770 2.9 30 0.769 2.8 30 0.765 2.8 30 0.765 2.8 30 0.759 24.0 26 0.758 23.3 28 0.755 24.0 26 0.755 23.3 28 0.754 2.8 29 0.748 2.8 29 I R 39 41 21 23 13 11 29 21 37 29 JR 32 30 40 42 30 22 14 12 30 38 K

5 5

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.4 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 1,000.0 MWd/MTU AREVA NP Inc.

(Jontrolled Uocument ANP-3215(NP)

Revision 0 Page A-8 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Onlet Subcooling: Btu/lbm Flow: Mlb/hr 1

3 5

7 9 11 13 15 1

3 5

7 9

..- 14 12 --

11 13-12 28 1500.0 127.14 500.0

(

42.33 2004.0 (100.00 1) 1024.6

-23.67 57.55

( 99.91 %)

17 19 21 23 25 Core Average Exposure:

MWd/MTU 18556.7 15 17 19 21 23 25 IR:

2 14 6 10 14 19 12 22 20 14 12 14 51 47 43 39 35 31 2 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.151 2.538 23 0.353 5.610 22 0.605 11.084 21 0.753 14.243 20 0.860 16.639

JR 19 0.909 18.339 13 0.911 19.460 17 0.900 20.431 16 0.882 20.558 15 0.896 21.387 14 0.963 21.507 13 1.024 21.150 12 1.087 21.944 11 1.163 22.519 10 1.239 22.735 9

1.323 22.903 8

1.395 23.251 7

1.452 23.500 6

1.501 23.859 5

1.503* 24.049*

4 1.462 23.290 3

1.339 20.750 1.033 15.725 Bottom 1

0.295 4.594 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.261 0.267 47 0.230 0.240 21 0.225 0.226 51 0.463 0.617 33 0.650 1.175 25 0.897 1.269 27 0.681 1.215 41 1.109 1.291 29 1.128 1.329 39 1.165 1.250 43 1.212 1.364 27 1.306 1.351 29 1.285 1.355 39 1.122 1.266 43 JR 40 2

32 48 42 28 28 32 30 30 30 30 32 28 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%)

Source Convergence 4.82 1.00209 0.455 22.496 18.063 545.7 50.13 12.9 3.5 0.00047

% AXIAL TILT -23.272 -12.737 AVG BOT 8ft/12ft 1.1598 1.1237 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.13 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.36' 0.36:

1. 355 1.351 1.351 1 336 1.332

1. 332 1.329 1.327 Power e FT 4 28 3 28 5 30 1 30 1 29 6 29 30 2 29 9 26 1 29 IR 27 29 39 31 29 39 41 37 39 29 JR 30 28 32 40 30 28 30 30 30 38 Value 1.811 1.814 1.869 1.878 1.904

1. 908

1. 915 1.925 1.926 1.927 MCPR Margin FT 0.878 28 0.877 28 0.851 28 0.847 28 0.835 26 0.833 26 0.830 26 0.826 26 0.825 26 0.825 29 IR 27 29 37 27 37 21 39 29 35 23 JR 30 2828 38 22 38 30 40 30 24 Value 7.55 7.51 7.49 7.48 7.47 7.42 7.32 7.28 7.25 7.21 Margin 0.754 0.751 0.749 0.748 0.746 0.742 0.731 0.727 0.725 0.721 APLHGR Exp.

O 28.3 28.3 9 26.0 8 28.9 6 27.0 23.8 1 26.9 7 26.9 5 27.8 2 28.2 FT 28 28 28 26 28 26 27 27 26 26 IP.

41 31 39 39 33 29 43 23 37 31 JR 32 42 20 30 40 40 30 44 22 38 K

5 5

4 5

5 55 5

55 Value 10.72 10.71 10.66

10. 66 8.15 8.20 8.17 8.10 6.95

6. 92 Margin 0.760 0.760 0.756 0.756 0.755 0.755 0.752 0.751 0.745 0.745 LHGR Exp.

FT 4.2 30 4.2 30 4.2 30 4.2 30 25.1 26 24.4 28 24.4 28 25.2 26 39.3 24 39.6 22 IR 41 39 23 21 13 11 21 29 41 11 JR 30 32 42 40 30 22 12 14 26 28 K

55 5

5 5

5 LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.5 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 1,500.0 MWd/MTU AREVA NP Inc.

uontroiled uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-9 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 2000.0 1 169.52 500.0 (

42.38 2004.0 (100.00 %)

1024.6

-23.12 58.80 (102.08 %)

15 17 19 21 23 25 Core Average Exposure: MWd/MTU 19056.7 1

3 5

7 9

ii 13 15 17 1

3 5

7 9

11 13 14 --

10 --

14 10 10..

..- 10 14 --

10 --

14 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA) Power Exposure Top 24 0.152 2.613 23 0.354 5.801 22 0.606 11.418 21 0.747 14.657 20 0.843 17.109

JR 19 0.880 18.832 18 0.893 19.958 17 0.389 20.925 16 0.877 21.073 15 0.896 21.881 14 0.967 21.983 13 1.031 21.634 12 1.094 22.457 11 1.169 23.068 10 1.243 23.319 9

1.326 23.527 8

1.397 23.909 7

1.453 24.184 6

1.502 24.567 5

1.508' 24.758-4 1.469 23.981 3

1.351 21.384 2

1.050 16.219 Bottom 1

0.302 4.734 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.261 0.267 47 0.229 0.239 21 0.223 0.225 51 0.462 0.618 33 0.647 1.178 25 0.896 1.244 27 0.676 1.217 41 1.102 1.273 29 1.126 1.328 39 1.166 1.256 43 1.203 1.341 27 1.305 1.343 39 1.291 1.366 39 1.133 1.280 43 JR 40 2

32 48 42 28 28 32 30 30 30 28 32 28 19 21 23 25 IR:

2 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

(%):

Total Water Rod Flow (%)

Source Convergence 4.96 1.00132 0.453 23.260 18.825 545.8 51.24 12.9 3.5 0.00037

% AXIAL TILT -23.876 -12.866 AVG BOT 8ft/12ft 1.1647 1.1236 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.19 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.366

1. 36

1. 345 1.34:

1.34:

1. 34)

1. 340 1.331 1.334 1.330 Power e FT 6 30 2 30 5 30 3 29 L 28 0 29 0 28 6 30 4 29 1 29 IR 39 31 41 39 27 29 29 29 37 27 JR 32 40 30 23 30 30 28 42 30 40 Value 1.877 1.880 1.927 1.935 1.942 1.946 1.947 1.957 1.968 1.970 MCPR Margin FT 0.847 28 0.846 28 0.825 28 0.822 28 0.819 26 0.817 26 0.817 26 0.813 26 0.808 28 0.807 28 IR 27 29 37 27 37 21 39 29 39 33 JR 30 28 28 38 22 38 30 40 34 40 Value 7.56 7.52 7.49 7.48 7.46 7.42 7.34

7. 30 7.24 7.19 Margin 0.756 0.753 0.749 0.748 0.745 0.743 0.733 0.729 0.724 0.720 APLHGR Exp.

6 29.3 3 29.3 9 26.9 29.8 27.9 3 29.8 3 27.9 9 27.8 28.8 29.1 FT 28 28 28 26 28 26 27 27 26 26 IR 41 31 39 39 33 29 43 23 37 31 JR 32 42 20 30 40 40 30 44 22 38 K

5 5

4 5

5 5

Value 8.21 10.76 8.15 10.74 8.18 8.10 10.71 10.69

6. 96

6. 93 Margin 0.764 0.763 0.763 0.762 0.761 0.759 0.759 0.758 0.755 0.754 LHGR Exp.

FT 25.6 28 5.6 30 26.3 26 5.6 30 25.5 28 26.3 26 5.6 30 5.6 30 40.3 24 40.6 22 IR 10 41 13 39 21 29 23 21 41 I1 JR 22 30 30 32 12 14 42 40 26 28 K

5 5

55 LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0

Thermal limit file:

Figure A.6 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 2,000.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Page A-10 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling:

Btu/ilb Flow: Mlb/hr 1

3 5

7 9 11 1

3 28 2500.0

( 211.90 500.0

(

42.38 2004.0 (100.00 %)

1024.6 m

-23.63 57.63 (100.05 9) 13 15 17 19 21 23 25 Core Average Exposure:

MWd/MTU 19556.7 7

9 13 15 1 7 19 21 23 25 IR:

2 6 10 14 --

1 10 14 1

0 --

47 43 39 14 35

-_31 10 27 4---23 15

-7 N (PRA)

Top 24 23 22 21 20 JR 19 18 17 16 15 14 13 12 11 10 9

8 7

6 5

4 3

2 Bottom I

Axial Profile Power Exposure 0.159 2.691 0.368 5.997 0.628 11.757 0.770 15.076 0.864 17.579 0.897 19.322 0.907 20.454 0.900 21.418 0.886 21.559 0.902 22.377 0.971 22.461 1.031 22.119 1.090 22.971 1.160 23.616 1.230 23.901 1.309 24.148 1.377 24.562 1.431 24.863 1.480 25.269 1.490' 25.464*

1.456 24.670 1.343 22.019 1.048 16.713 0.304 4.877 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.259 0.266 47 0.227 0.237 21 0.222 0.223 51 0.460 0.615 33 0.645 1.178 25 0.592 1.234 27 0.673 1.217 41 1.091 1.269 29 1.123 1.325 39 1.165 1.254 43 1.200 1.332 27 1.310 1.350 39 1.296 1.372 39 1.138 1.287 43 JR 40 2

32 48 42 28 32 30 30 30 28 32 28 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (6):

Total Water Rod Flow (9)

Source Convergence 4.96 1.00089 0.453 22.536 18.103 545.7 510. 21 12.9 3.5 0.00046

% AXIAL TILT -22.647 -12.960 AVG BDT Sft/12ft 1.1567 1.1234 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 43.21 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.372 1.36) 1.352 1.35) 1.34:

1.34; 1.34]

1.338 1.33) 1.332 Power e FT 2 30 8 30 30 0 29 3 30 2 29 1 29 1 29 6 29

?238 IR 39 31 41 39 29 29 37 27 29 27 JR 32 40 30 28 42 30 30 40 38 30 Value 1.867 1.871 1.908 1.916 1. 922 1.926 1.927 1.935 1.945 1.947 MCPR Margin FT 0.851 28 0.850 28 0.833 28 0.830 28 0.327 26 0.826 26 0.825 26 0.822 26 0.818 28 0.817 28 IR 27 29 37 27 37 21 39 29 39 33 JR 30 28 28 38 22 38 30 40 34 40 Value 7.45 7.42 7.39 7.36

7. 34 7.30 7.25 7.21 6.40 6.37 APLHGR Margin Exp.

FT 0.747 30.3 28 0.743 30.2 28 0.738 27.9 28 0.737 30.8 26 0.734 28.9 28 0.732 30.8 26 0.725 28.8 27 0.721 28.8 27 0.716 42.4 22 0.712 42.3 22 IR JR 41 32 31 42 39 20 39 30 33 40 29 40 43 30 23 44 11 28 25 42 K

55 4

5 5

55 5

55 Value 3.10 8.02 8.06 7.98 10.64 6.85 6.87 10.61 10.59 10.55 Margin 0.762 0.760 0.759 0.756 0.755 0.753 0.753 0.752 0.751 0.748 LHGR Exp.

FT 26.7 28 27.4 26 26.7 28 27.4 26 7.0 30 41.5 22 41.3 24 7.0 30 6.9 30 7.0 30 IR 11 13 21 29 41 11 41 39 23 21 JR 22 30 12 14 30 28 26 32 42 40 K

5 5

+ LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0

Thermal limit file:

Figure A.7 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 2,500.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-i 1 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWr Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 3000.0 C 254.28 500.0 C 42.38 2004.0 (100.00 %)

1024.6

-23.91 57.02

( 99.00 9)

Core Average Exposure:

MWd/MTU 20056.7 1

3 5

7 9 11 13 15 17 19 21 23 25 1

3 5

7 9

11 13 15 17 19 21 23 25 IR:

14 10 14 10 14 10 51 47 43 39 35 31 27 123 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.165 2.771 23 0.382 6.200 22 0.648 12.108 21 0.792 15.506 20 0.882 18.061

JR 19 0.912 19.821 18 0.919 20.957 17 0.910 21.917 16 0.892 22.050 15 0.906 22.876 14 0.973 22.941 13 1.030 22.604 12 1.085 23.482 11 1.150 24.159 10 1.216 24.476 9

1.292 24.761 8

1.358 25.206 7

1.411 25.533 6

1.462 25.962 5

1.476' 26.163k 4

1.446 25.354 3

1.338 22.651 2

1.048 17.207 Bottom 1

0.305 5.020 Edit Zone 16 18 20 21 22 23 24 25 26 2728 29 30 31 Radial Power Avg.

Max.

IR 0.258 0.264 47 0.225 0.236 21 0.220 0.221 51 0.457 0.612 33 0.643 1.178 25 0.888 1.223 27 0.670 1.216 41 1.094 1.264 29 1.120 1.323 39 1.163 1.253 43 1.197 1.323 27 1.315 1.358 39 1.302 1.379 39 1.143 1.294 43 JR 40 2

32 48 42 28 28 32 30 30 30 28 32 28 10 --

14 2

6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

(-):

Total Water Rod Flow (1):

Source Converqence 4.96 1.00052 0.452 22.156 17.724 545.7 49.68 12.9 3.5 0.00037

% AXIAL TILT -21.570 -13.059 AVG BOT Sft/12ft 1.1494 1.1231 Active Channel Flow: Mlb/hr 47.71 (of total core flow)

(of total core flow)

Top Ten Thermal Limits Summary -

Sorted by Margin Power Value 1.379 1.375 1.360 1.358 1.351 1.347 1.346 1.345 1.343 1.325 FT 30 30 30 29 30 29 29 29 29 30 IR 39 31 41 39 29 37 27 29 29 31 JR 32 40 30 28 42 30 40 30 38 32 Value 1.868 1.871 1.900 1.907 1.913 1.916 1.919 1.927 1.934 1. 934 MCPR Margin FT 0.851 28 0.850 28 0.837 28 0.834 28 0.831 26 0.830 26 0.829 26 0.825 26 0.822 28 0.822 28 APLHGR IR 27 29 37 27 37 21 39 29 39 33 JR 30 28 28 38 22 38 30 40 34 40 Value 7.37 7. 34 7. 31 7.27 7.26 7.21 7.19 6.34 7.15 6.31 Margin 0.739 0.736 0.731 0.729 0.726 0.723 0.719 0.716 0.715 0.712 Exp.

31.2 31.2 28.9 31.8 29.1 31.7 29.8 43.2 29.7 43.1 FT 28 28 28 26 28 26 27 22 27 22 IR JR 41 32 31 42 39 20 39 30 33 40 29 40 43 30 11 28 23 44 25 42 K

55 4

5 5

Value 8.05 7.97 8.00 7.88 6.78 6.79 6.91 10.55 10.51 10.50 LHGR Margin Exp.

FT 0.763 27.5 28 0.759 27.9 26 0.759 27.5 28 0.755 28.5 26 0.754 42.5 22 0.753 42.2 24 0.749 40.2 22 0.748 8.3 30 0.745 8.4 30 0.744 8.3 30 IR 11 13 21 29 11 41 27 41 39 23 JR 22 30 12 14 28 26 12 30 32 42 K

44 4

5 5

5

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.8 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 3,000.0 MWd/MTU AREVA NP Inc.

uontrollea Uocument ANP-3215(NP)

Revision 0 Page A-12 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr Core Average Exposure:

MWd/MTU 20363.8 3307.0

( 230.30 307.0

(

26.02 2004.0 (100.00 %)

1024.6

-23.75 57.38

( 99.61 %)

15 17 19 21 23 25 1

3 5

7 9

1 3

5 7

9 13 15 17 19 21 23 25 IP: 2 11

-0

- 0 13

16 51 47 43 39 35 31

-27 23 19 15 0 --

0 --

0 -

Axial Profile N(PRA)

Power Exposure Top 24 0.134 2.816 23 0.314 6.316 22 0.540 12.309 21 0.665 15.753 20 0.755 18.338

JR 19 0.812 20.113 18 0.851 21.257 17 0.881 22.220 16 0.986 22.351 15 0.916 23.184 14 0.997 23.239 13 1.063 22.906 12 1.122 23.801 11 1.188 24.497 10 1.254 24.833 9

1.329 25.140 8

1.393 25.604 7

1.447 25.946 6

1.502 26.391 5

1.528 26.598' 4

1.516 25.782 3

1.429 23.051 1.142 17.523 Bottom 1

0.337 5.112 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR JR 0.251 0.266 47 40 0.175 0.184 21 2

0.216 0.218 51 32 0.434 0.612 47 34 0.702 1.290 27 34 0.842 1.266 27 28 0.671 1.301 25 34 1.062 1.356 29 32 1.117 1.382 31 38 1.272 1.425 33 36 1.240 1.401 27 30 1.318 1.440 25 32 1.303 1.450 31 36 1.093 1.298 43 28 16 8

6 10 14 18 22 26 30 34 38 42 46 50 11 7

3 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence 1.00003 0.457 22.450 18.014 545.7 49.96 12.9 3.5 0.00033

% AXIAL TILT -26.557 -13.136 AVG BOT 8ft/12ft 1.1905 1.1231 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 47.94 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPP Value 1

.450 1.447 1.444 1.440 1.425 1.409 1.401 1.388 1.385

1. 383 FT 30 30 30 29 27 29 28 30 30 30 IR 31 29 33 25 33 29 27 39 37 31 JR 36 34 38 32 36 30 30 32 34 40 Value Margin 1.764 0.901 1.796 0.885 1.826 0.871 1.828 0.870 1.837 0.866 1.839 0.864 1.845 0.862 1.846 0.861 1.848 0.860 1.853 0.85:1 FT 27 28 26 26 28 28 27 29 26 IR 19 27 31 29 27 39 29 35 27 35

-JR 36 30 38 36 36 34 28 34 32 38 Value 8.17 7.94 7.23 7.79 7.77 7.76 7.74 7.66 7.64

7. 61 APLHGR Margin Exp.

FT 0.816 23.7 27 0.795 29.5 28 0.786 39.6 22 0.781 32.0 26 0.779 31.9 26 0.777 29.7 28 0.776 31.4 28 0.766 26.8 27 0.765 30.8 26 0.793 31.6 26 LHGR IR 19 39 17 17 15 19 41 17 21 39 JR 18 20 36 38 36 14 22 34 16 30 K

3 4

4 4

Value Margin 7.84 0.823 8.42 0.816 8.45 0.807 8.61 0.806 8.35 0.806 8.35 0.801 8.63 0.801 8.53 0.800 11.22 0.796 7.05 0.789 Exp.

37.2 29.7 28.2 26.1 29.2 28.6 25.3 26.3 8.1 43.1 FT 22 26 28 28 26 26 27 28 30 22 IR 35 35 11 13 37 13 19 19 19 11 JR 36 38 22 20 36 30 36 14 38 28 K

4 4

4 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.9 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 3,307.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-1 3 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Bu/ilbm Flow: Mlb/hr 28 3500.0 ( 296.66 193.0

(

16.36 2004.0 (100.00

%)

1024.6

-23.72 57.43 ( 99.71 %)

Core Average Exposure:

MWd/MTU 20556.7 1

35 7

9 11 13 1

3 5

7 9 11 13 15 8 --

16 0-------

17 19 21 23 25 0

0 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.136 2.842 23 0.318 6.382 22 0.547 12.425 21 0.673 15.895 20 0.762 18.499

JR 19 0.819 20.287 18 0.858 21.439 17 0.886 22.408 16 0.891 22.540 15 0.920 23.380 14 0.999 23.429 13 1.064 23.099 12 1.122 24.005 11 1.187 24.713 10 1.251 25.061 9

1.324 25.381 8

1.387 25.857 7

1.440 26.209 6

1.495 26.664 5

1.521" 26.875*

4 1.509 26.057 3

1.421 23.310 2

1.135 17.730 Bottom 1

0.336 5.173 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 O9 30 31 Radial Power Avg.

Max.

IR 0.251 0.265 47 0.176 0.184 21 0.216 0.217 51 0.434 0.611 47 0.700 1.284 27 0.841 1.260 27 0.671 1.296 25 1.060 1.351 29 1.116 1.380 31 1.270 1.420 33 1.238 1.395 27 1.319 1.439 25 1.304 1.450 31 1.096 1.303 43 JR 40 2

32 34 34 28 3432 38 36 30 32 36 28 15 17 19 21 25IR: 2 16 8

6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (3)

Source Convergence 0.99984 0.456 22.471 18.034 545.7 50.01 12.9 3.5 0.00032

% AXIAL TILT -26.064 -13.204 AVG BOT 8ft/12ft 1.1876 1.1233 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.00 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR LHGR Value 1.450 1.446 1.444 1.439 1.420 1.408 1.395 1.391 1.387 1.386 FT 30 30 30 29 27 29 28 30 30 30 IR 31 29 33 25 33 29 27 39 31 37 JR 36 34 38 32 36 30 30 32 40 34 Value 1.779 1

04 1.82 I

33 1 842 1.H48 1.85 1.852 0 861 1 862 Margin 0.894 0.881 0.870 0.867 0.863 0.860 0.859 0.858 0.854 0.854 FT 27 28 26 26 28 28 29 28 30 27 IR 19 27 31 29 27 39 27 29 31 35 JR36 30 30 36 34 32 28 36 34 Value 8.03 7.89 7.2 7.72 7.71 7.71

7. 69 7.58 7.57 7.56 Margin Exp.

0.803 24.1 0.790 29.9 0.777 40.0 0.774 31.8 0.774 32.3 0.772 30.1 0.772 32.3 0.760 32.2 0.759 31.2 0.755 27.2 FT 27 28 22 28 26 28 26 26 26 27 IR 19 39 17 41 17 33 15 39 21 17 JR 18 20 3622 38 40 36 30 16 34 K

3 4

4 44 4

4 4

Value Margin 7.72 0.813 8.32 0.810 8.42 0.808 8.55 0.804 8.28 0.802 8.32 0.801 6.47 0.797 8.51 0.793 7.02 0.790 11.13 0.789 Exp.

37. 6 30.1 28.6 26.6 29.7 29.0 26.8 25.8 43.5 8.6 FT 22 26 28 28 26 26 28 27 22 30 IR 35 35 11 13 37 13 19 19 11 19 JR 36 38 22 20 36 30 14 36 28 38 K

4 4

5 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.10 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 3,500.0 MWd/MTU AREVA NP Inc.

Uontrolled uocumenit ANP-3215(NP)

Revision 0 Page A-14 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 4000.0

( 339.03 500.0

(

42.38 2004.0 (100.00 1) 1024.6

-23.84 57.17

( 99.26 %)

Core Average Exposure:

MWd/MTU 21056.8 1

3 5

7 1

3 5

7 9

13 --

15 --

17 19 21 23 25 IR:

9 11 0

0 --

6 10 14 18 22 13 8

16 16 8

26 15 30 17 19 21 23 25 51 47 43 39 35 0

31 27 0

23 19 15 11 7

34 38 42 46 50 Axial Profile N(PRA)

Power Exposure Top 24 0.141 2.911 23 0.328 6.557 22 0.562 12.730 21 0.688 16.271 20 0.776 18.924

JR 19 0.831 20.742 18 0.867 21.915 17 0.893 22.899 16 0.896 23.033 15 0.923 23.888 14 1.001 23.923 13 1.062 23.600 12 1.117 24.532 11 1.177 25.269 10 1.238 25.646 9

1.310 26.001 8

1.372 26.507 7

1.426 26.884 6

1.483 27.365 5

1.514* 27.590*

4 1.505 26.767 3

1.419 23.979 2

1.134 18.265 Bottom 1

0.337 5.331 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.250 0.264 47 0.175 0.184 21 0.214 0.216 51 0.433 0.609 47 0.697 1.275 27 0.839 1.247 27 0.668 1.287 25 1.056 1.343 29 1.113 1.376 31 1.266 1.409 33 1.234 1.383 27 1.324 1.440 25 1.309 1.452 31 1.103 1.313 43 JR 40 2

32 34 34 28 34 32 38 36 30 32 36 28 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence 5.79 0.99934 0.455 22.300 17.564 545.7 49.79 12.9 3.5 0.00031 AXIAL TILT -25.270 -13.361 AVG BOT 8ft/12ft 1.1821 1.1237 Active Channel Flow: Nlb/hr (of total core flow)

(of total core flow) 47.79 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.452 1.44)

1. 44

1. 44) 1.409 1.40) 1.399 1.394 1.390 1.383 Power e FT 2 30 8 30 7 30 0 29 9 27 8 29 9 30 4 30 0 30 3 28 IR 31 33 29 25 33 29 39 31 37 27 JR 36 38 34 32 36 30 32 40 34 30 Value 1.802 1.817 1.828 1.840 1.850 1.856 1.862 1.863 1.866 1.878 MCPR Margin FT 0.882 27 0.875 28 0.870 26 0.864 2 6 0.859 28 0.857 29 0.854 30 0.853 28 0.852 28 0.847 30 IR 19 27 31 29 27 27 31 39 29 29 JR 36 30 3S 36 36 32 36 34 28 20 Value Margin 7.85 0.786 7.86 0.786 7.71 0.774 6.99 0.770 7.61 0.767 7.65 0.767 7.60 0.765 7.55 0.759 6.57 0.755 6.54 0.751 APLHGR Exp.

30.9 28.4 32.8 40.9 33.4 31.1 33.3 33.2 44.9 45.7 FT 28 27 28 92 28 26 26 22 24 IR 39 19 41 17 17 33 15 39 11 41 JR 20 18 22 36 16 40 36 30 28 26 K

4 4

5 5

Value 8.40 8.49 8.28 8.18 7.56 8.20 8.39 6.99 7.00 8.24 Margin 0.816 0.807 0.807 0.806 0.805 0.604 0.799 0.796 0.795 0.791 LHGR Exp.

FT 29.8 28 27.8 28 30.2 26 31.3 26 38.7 22 30.8 26 27.9 28 44.5 22 44.2 24 28.7 27 IR 11 13 13 35 35 37 19 11 41 43 JR 22 20 30 38 36 36 14 28 26 30 K

4 4

4 44 4

4 5

5 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.11 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 4,000.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-15 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr 28 4500.0 ( 381.41 500.0 42.38 2004.0 (100.00 %)

1024.6

-23.19 58.63 (101.79 9)

Core Average Exposure: MWd/MTU 21556.8 1

3 5

7 9

11 13 15 17 19 21 23 1

3 5

7 9 11 13 15 17 19 0-------

14 0

0 14 0--

0 0

21 23 25 51 47 43 39 35 31 2-7 23 19 15 11 7

3 N (P1 Top

JR Bottom Axial Profile RA) Power Exposure 24 0.138 2.980 23 0.321 6.733 22 0.551 13.037 21 0.675 16.647 20 0.766 19.349 19 0.821 21.197 18 0.855 22.390 17 0.878 23.388 16 0.888 23.524 15 0.919 24.396 14 0.999 24.416 13 1.063 24.100 12 1.118 25.05S i1 1.179 25.823 10 1.240 26.229 9

1.312 26.619 8

1.376 27.155 7

1.432 27.557 6

1.493 28.067 5

1.529* 28.307*

4 1.523 27.481 3

1.436 24.6,52 1.148 18.803 1

0.342 5.491 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.247 0.264 47 0.166 0.174 21 0.214 0.216 51 0.428 0.612 47 0.692 1.265 27 0.832 1.239 27 0.662 1.277 25 1.052 1.338 29 1.112 1.368 31 1.265 1.403 33 1.230 1.376 27 1.32;9 1.444 25 1.319 1.455 91 1.109 1.333 43 JR 40 2

32 34 34 28 34 32 38 36 30 32 36 28 25 IR: 2 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

9 k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (9)

Source Convergence 6.13 0.99879 0.452 23.290 18.851 545.8 51.05 12.9 3.5 0.00043

% AXIAL TILT -26.060 -13.509 AVG BOT 8ft/12ft 1.1873 1.1241 Active Channel Flow: Mib/hr (of total core flow)

(of total core flow) 49.00 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR Value 1.455 1. 455 1.449 1.444 1.420 1.415 1.404 1.403 1.403 1.397 FT 30 30 30 29 30 29 30 27 30 30 IR 31 33 29 25 39 29 37 33 41 31 JR 36 38 34 32 32 30 34 36 30 40 Value Margin 1.830 0.869 1.853 0.858 1.875 0.348 1.876 0.847 1.88S 0.842 1.890 0.841 1.898 0.838 1.900 0.837 1.905 0.834 1.907 0.834 FT 27 28 28 26 26 29 28 28 26 30 IR 19 27 39 31 29 27 33 29 35 31 JR 36 3O 34 28 36 32 40 28 38 36 Value 7.92 7.81 7.83 7.63

6. 96

7. 62

7. 62 7.71

6. 65

6. 62 APLHGR Margin Exp.

FT 0.794 31.9 28 0.792 34.1 28 0.783 29.5 27 0.775 34.3 26 0.774 41.8 22 0.774 34.2 26 0.774 34.3 26 0.773 32.1 28 0.771 45.8 22 0.768 46.5 24 LHGR IR 39 41 19 17 17 39 15 33 11 41 JR 20 32 18 38 36 30 36 40 28 26 K

4 4

4 44 4

4 4

5 5

Value Margin 8.51 0.836 8.36 0.824 8.55 0.823 8.23 0.817 8.22 0.815 7.06 0.814 8.43 0.813 8.36 0.812 7.07 0.812 7.50 0.809 Exp.

31.0 31.4 29.0 32.0 32.0 45.5 29.1 29.9 45.2 39.8 FT 28 2 6 28 2 6 26 22 28 27 24 22 IR it 13 13 37 35 11 19 43 41 35 JR 22 30 20 36 38 28 14 30 26 36 K

4 4

4 5

4 4

5 4

LHGE calculated with pin-power reconstruction CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.12 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 4,500.0 MWd/MTU AREVA NP Inc.

Uontrolled uocument ANP-3215(NP)

Revision 0 Page A-16 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power:

MWt Core Pressure:

psia Inlet Subcooling:

Btu/Ibm Flow: Mlb/hr 23 5000.0 C 423.79 1 500.0 C 42.38 2004.0 (100.00 %)

1024.6

-23.33 58.31 (101.23 %)

15 17 19 21 23 25 Core Average Exposure: MWd/MTU 22056.7 1

3 7

9 13 15 17 19 21 23 IR: 2' 3

5 7

9 11 13 0

0 0

14 0

0 51 47 43 39 35 31 27 23 19 15 11 7

N (PC Top TR Bottom Axial Profile RA) Power Exposure 24 0.141 3.050 23 0.329 6.909 22 0.563 13.343 21 0.687 17.022 20 0.775 19.774 19 0.328 21.652 13 0.861 22.863 17 0.882 23.873 16 0.890 24.014 15 0.919 24.903 14 0.997 24.909 13 1.058 24.599 12 1.110 25.582 11 1.167 26.375

[0 1.226 26.809 9

1.296 27.233 8

1.361 27.799 7

1.419 28.229 6

1.485 28.768 5

1.530k 29.029*

4 1.529 28.200 3

1.445 25.331 2

1.157 19.346 1

0.346 5.652 Edit Zone 16 18 20 21 2223-24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.246 0.263 47 0.165 0.173 21 0.213 0.214 51 0.427 0.610 47 0.688 1.256 27 0.829 1.225 27 0.660 1.268 25 1.048 1.330 29 1.109 1.363 31 1.261 1.392 33 1.225 1.364 27 1.334 1.446 25 1.325 1.460 33 1.117 1.350 43 JR 40 2

32 34 34 28 34 3238 36 30 32 38 28 I

6 30 34 38 42 6 10 14 18 22 2 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (3):

Total Water Rod Flow (9)

Source Convergence 6.13 0.99833 0.452 23.089 18.650 545.8 50.77 12.9 3.5 0.00049 5 AXIAL TILT -25.583 -13.655 AVG BOT 8ft/12ft 1.1834 1.1245 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.73 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR LHGR Value 1.460 1.458 1.451 1.446 1.429 1.415 1.414 1.409 1.405 1.403 FT 30 30 30 29 30 29 30 30 30 29 IR 33 31 29 25 39 29 41 37 31 39 JR 38 36 34 32 32 30 30 34 40 28 Value 1.852 1.868 1.878 1.889 1.895 1.896 1.907 1.909 1.915 1.920 Margin 0.858 0.851 0.847 0D. 342 0.339 0.839 0.334 0.833 0.830 0.828 FT 27 23 2S 28 29 26 30 28 28 26 IR 33 27 31 39 27 29 31 33 29 35 JR 36 30 38 34 32 36 36 40 28 38 Value 7.85

7. 92 7.64 6.78 6.64 7.57 7.57

7. 66 7.72 6.87 Margin Exp.

0.304 35.1 0.795 33.0 0.783 35.2 0.782 45.3 0.779 47.4 0.777 35.3 0.776 35.3

0. 773 33.6 0.773 30.5 0.771 42.7 FT 2828 23 22 24 26 26 28 27 22 IR 41 39 39 11 41 17 15 19 19 17 JR 32 20 30 26 38 36 40 18 36 K

4 4

4 4j 4

4 4

Value Margin 8.55 0.850 8.37 0.835 8.53 0.831 8.43 0.828 7.40 0.827 7.28 0.824 8.20 0.823 8.17 0.820 8.40 0.820 7.53 0.806 Exp.

32.2 32.5 30.2 31.0 42.9 43.9 33.1 33.1 30.3 39.1 FT 28 26 28.

,7 22 24 26 26 2823 IR 11 13 13 43 11 41 37 35 19 11 JR 22 30 20 30 28 26 36 38 14 36 K

4 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.13 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 5,000.0 MWd/MTU AREVA NP Inc.

u;ontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-1 7 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr 28 5500.0

( 466.17 500.0

(

42.38 2004.0 (100.00 %)

1024.6

-23.59 57.71 (100.20 %)

Core Averaqe Exposure: MWd/MTU 22556.8 13 5

1 3

5 7

9 13 15 17 19 2123 25 I R: 2 7

9 11 13 0

14 0

0 14 0

6 10 14 18 22 26 15 17 19 21 23 25 0

0

0 34 38 42 46 50 6.13

0. 99786 0.454 22.740 15. 302 545.7 50.24 Active 12.9 (of to:

3.5 (of tot 0.00045 51 47 43 39 35 31 27 23 19 15 11 7

3 N (PPA)

Top 2423 22 21 20 JR 19 18 17 16 15 14 13 12 11 10 9P 7

6 5

4 Bot tom 1

Axial Profile Power Exposure 0.144 3.120 0.334 7.088 0.571 13.655 0.693 17.403 0.779 20.202 0.830 22.109 0.861 23.338 0.881 24.359 0.883 24.505 0.916 25.409 0.993 25.400 1.051 25.095 1.101 26.102 1.155 26.921 1.212 27.383 1.282 27.841 1.348 28.437 1.410 28.895 1.482 29.467 1.536 29.751*

1.544' 28.924 1.464 26.016 1.173 19.895 0.352 5.816 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.245 0.261 47 0.164 0.172 21 0.211 0.213 51 0.425 0.609 47 0.684 1.247 27 0.826 1.211 27 0.657 1.258 25 1.043 1.321 29 1.105 1.358 31 1.256 1.382 33 1.220 1.351 27 1.338 1.447 25 1.331 1.464 33 1.125 1.362 43 JR 40 2

32 34 34 28 34 32 38 36 30 32 38 28 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence

% AXIAL TILT -25.486 -13.788 AVG BOT 8ft/12ft 1.1817 1.1247 Channel Flow: Mlb/hr tal core flow) tal core flow) 48.22 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.464 1.460 1.452 1.447 1.43) 1.426 1.415 1.414 1.41 1.413 Power FT 30 0 30 2 30 7 29 9 30 6 30 5 29 30 3 29 3 30 IR JR 33 38 31 36 29 34 25 32 39 32 41 30 29 30 37 34 39 28 31 40 Value 1.869 1.880 1.882 1.892 1.898 1. 904 1. 906 1.914

1. 927

1. 928 MCPR Margin FT 0.851 27 0.846 26 0.845 28 0.840 28 0.838 29 0.835 26 0.834 30 0.831 28 0.825 30 0.825 28 IR 33 31 27 39 27 29 31 33 29 29 JR 36 38 30 34 32 3636 40 20 28 Value

7. 94

7. 97 6.87 7.70 6.84 7.74 7.68 7.55 7.56 6.81 Mergin 0.821 0.807 0.799 0.797 0.797 0.787 0.782

0. 782 0.782 0.772 APLHGR Exp.

36.1 34.0 46.2 36.2 46.8 34.3 34.6 36.3 2 36.3 243. 6 FT 28 28 22 26 24 27 28 26 26 22 IR 41 39 11 39 41 43 19 17 15 17 JR 32 20 28 30 26 30 40 38 36 36 K

4 4

Value

8. 62 8.42 8.53 7.48 8.62

7. 37 8.20 8.17 8.40 7.59 Margin 0.868 0.851 0.848 0.846 0.845 0.844 0.833 0.830 0.829 0.823 LHGR Exp.

FT 33.4 28 33.7 26 32.2 27 43.9 22 30.8 28 45.0 24 34.3 26 34.2 26 31.5 28 40.2 23 IR 11 13 43 11 13 41 37 35 19 11 JR 22 30 30 28 20 26 36 38 14 36 K

4 4

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.14 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 5,500.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-18 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr 28 6000.0

( 508.55 500.0 (

42.38 2004.0 (100.00 1) 1024.6

-23.38 58.20 (101.05 %)

Core Average Exposure:

MWd/MTU 23056.8 13 5

13 5

7 9

13 15 17 19 21 2 3 25 IR:

2 6

7 9 11 13 0

12 15 17 19 21 23 25 0 --

U --

12 0

0 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.145 3.192 23 0.335 7.269 22 0.570 13.970 21 0.688 17.784 20 0.770 20.630

JR 19 0.816 22.563 18 0.842 23.808 17 0.867 24.841 16 0.877 24.992 15 0.908 25.912 14 0.985 25.888 13 1.044 25.588 12 1.094 26.619 11 1.147 27.463 10 1.205 27.952 9

1.276 28.444 8

1.345 29.072 7

1.411 29.560 6

1.490 30.167 5

1.556 30.479*

4 1.572* 29.658 3

1.496 26.714 2

1.199 20.454 Bottom 1

0.360 5.984 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.243 0.260 47 0.162 0.170 21 0.210 0.212 51 0.423 0.609 47 0.680 1.232 27 0.824 1.196 27 0.654 1.243 25 1.038 1.310 29 1.101 1.348 31 1.253 1.370 33 1.213 1.338 39 1.340 1.446 25 1.338 1.468 33 1.135 1.383 43 JR 40 2

32 34 34 28 34 32 38 36 34 32 38 28 0

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (M)

Total Water Rod Flow (%)

Source Convergence 6.20 0.99751 0.454 23.057 18.618 545.8 50.67 12.9 3.5 0.00035

% AXIAL TILT -26.265 -13.923 AVG BOT 8ft/12ft 1.1854 1.1251 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.63 Top Ten Thermal Limits Summary -

Sorted by Margin Value i.46) 1.45) 1.455 1.449 1.441 1.446 1.43) 1.424 1.416 1.41)

Power e FT 8 30 9 30 5 30 9 30 6 30 6 29 1 29 30 6 30 6 29 IR 33 31 39 29 41 25 39 37 31

'9 JR 38 36 32 34 30 32 28 34 40 30 Value 1.893 1.899 1.914 1.918 1.927 1.928 1.934 1.943 1.944 1.944 MCPR Margin FT 0.840 27 0.837 28 0.831 28 0.829 26 0.825 28 0.825 29 0.822 28 0.818 30 0.818 27 0.818 26 IR 33 39 27 31 33 27 41 31 43 35 JR 36 34 30 38 40 32 32 36 30 38 Value 8.10 8.09 7.03 7.00 7.84 7.93 7.78

7. 61

7. 60 6.81 Margin 0.84) 0.827 0.826 0.824 0.819 0.813 0.800 0.796 0.795 0.779 APLHGR Exp.

6 37.2 35.0 47.1 47.7 37.2 35.3 35.6 37.3 37.3 44.5 FT 28 28 22 24 26 27 28 26 26 22 IR JR 41 32 39 20 11 28 41 26 39 30 43 30 19 40 15 36 17 38 17 36 K

4 4

4 44 4

Value 8.78 8.72

8. 56 7.64 7.53 8.74 8.28 8.48 7.73 8.23 Margin 0.896 0.878 0.876 0.875 0.873 0.867 0.851 0.848 0.847 0.847 LHGR Ezp.

FT 34.7 28 33.4 27 34.9 26 45.0 22 46.0 24 32.0 28 35.4 26 32.7 28 41.2 23 35.4 26 IR 11 43 13 11 41 13 37 19 11 35 JR 22 30 30 28 26 20 36 14 36 38 K

4 4

4 44 4

4 4

LHGR calculated with pin-power reconstruction SCPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.15 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 6,000.0 MWdlMTU AREVA NP Inc.

Uontrolled uocument ANP-3215(NP)

Revision 0 Page A-19 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 6063.0

( 513.89 63.0

(

5.34 2004.0 (100.00

%)

1024.6

-23.64 57.60 (100.00

%)

Core Average Exposure:

MWd/MTU 23119.7 1

3 5

7 9 11 3

5 38 79 0

11-----------

13 18 8

15-17 0

19 21 38 23 25 IR: 2 6

10 14 18 22 13 26 15 38 0

0 38 17 19 21 23 25 8 --

51 47 43 39 35 31 18 --

27

-23 19 15 11 7

Axial Profile N(PRA)

Power Exposure Top 24 0.154 3.202 23 0.355 7.293 22 0.603 14.010 21 0.724 17.833 20 0.804 20.684

JR 19 0.853 22.621 18 0.888 23.868 17 0.917 24.903 16 0.926 25.054 15 0.951 25.977 14 1.028 25.951 13 1.087 25.651 12 1.138 26.685 11 1.192 27.532 10 1.249 28.024 9

1.317 28.521 1.376 29.152 7

1.422 29.644 6

1.462 30.255 5

1.465-30.569-4 1.427 29.747 3

1.318 26.797

? 1.035 20.520 Bottom 1

0.307 6.003 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.252 0.260 39 0.217 0.227 21 0.180 0.181 51 0.433 0.599 33 0.691 1.227 33 0.879 1.189 27 0.637 1.238 19 1.044 1.307 33 1.096 1.349 37 1.245 1.369 35 1.197 1.336 39 1.324 1.437 21 1.326 1.470 37 1.140 1.315 27 JR 48 2

32 48 28 28 28 32 32 34 34 28 34 44 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence 30 34 38 42 46 50 6.40 0.99729 0.447 22.431 17.992 545.6 50.21 Active 12.8 (of cot 3.5 (of rot 0.00049 3

i AXIAL TILT -22.576 -13.935 AVG BOT 8ft/12ft 1.1688 1.1251 Channel Flow: Mlb/hr tal core flow) tal core flow) 48.21 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT IR 1.470 30 37 1.457 30 35 1.444 30 33 1.437 29 21 1.427 30 39 1.413 30 31 1.411 30 39 1.409 30 33 1.409 29 29 1.402 29 37 JR 34 32 30 28 32 40 36 38 30 38 Value 1.874 1.887 1.903 1.907 1.911 1.915 1.916 1.921

1. 929 1.931 MCPR Margin FT 0.848 27 0.842 30 0.835 26 0.834 28 0.832 28 0.830 28 0.830 30 0.828 29 0.824 26 0.823 26 ItR 35 35 37 39 33 29 19 31 35 37 JR 20 32 32 34 40 28 30 28 3036 Value 7.79 7.42 7.52 7.59

7. 32 7.50 6.44 7.14 7.45

6. 58 APLHGR Margin Exp.

FT 0.798 35.2 28 0.777 37.4 26 0.775 35.9 26 0.771 34.4 28 0.763 37.0 28 0.753 32.1 27 0.750 46.2 22 0.749 37.7 26 0.748 32.6 27 0.743 43.3 23 IR 13 15 15 31 11 17 17 35 29 11

,JR 34 36 32 42 32 34 36 38 44 36 K

4 4

4 7

4 4

5 5

7 4

Value 8.42 8.04

8. 10

7. 35 8.05 8.15 7.89 7.72 8.16 11.18 Margin 0.844 0.828 0.824 0.807 0.806 0.806 0.802 0.795 0.794 0.793 LHGR Exp.

FT 32.9 28 35.5 26 34.4 26 41.4 23 32.9 27 31.6 28 34.3 28 35.6 26 30.1 27 16.5 30 IR 13 37 37 11 13 31 11 35 29 37 JR 34 36 22 36 38 42 22 38 44 20 K

4 4

4 44 7

4 5

7 4

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction 5 CPR limit type 0 Thermal limit file:

Figure A.16 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 6,063.0 MWd/MTU AREVA NP Inc.

Uontrolled ucocument ANP-3215(NP)

Revision 0 Page A-20 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposur Delta Power:

Core Pr Inlet Floew:

e: FWd/MTU (GWd) 6500.0

( 550.93 5: MWd/MTU, (GWd) 437.0

(

37.04 HWt 2004.0 (100.00 1) ressure: psia 1024.6 Subcooling: Btu/ibm

-23.54 m1b/hr 57.84 (100.41

%)

1 3

5 7

9 11 13 15 17 1921 23 25 9

Core Average Exposure:

MWd/MTJ 23556.7 l

I 3

5 7

973 -- 1 15-------

17 19 21 23 38

-- (

47 47 0

35 31 13 --

27 0-

-19 15

.11 7

Axial Profile N(PRA)

Power Exposure Top 24 0.155 3.269 23 0.359 7.462 22 0.609 14.302 21 0,723 18.183 20 0.807 21.072

JR 19 0.855 23.033 18 0.839 24.296 17 0,917 25.346 16 0-,925 2,.500 15 0.950 26.435 14 1.025 26.394 13 1.083 26.097 12 1.131 27.151 11 1.183 28.021 10 1,238 28.536 9

1 06

29. 061 8

1.366 29.717 7

1,415 30.228 6

1.461 30.857 5

1.472' 31.174*

4 1,440 30.337 3

1.332 27.343 1 1.045 20.948 Bottom 1

0.311 6.130 Edit Zone 16 18 21

'231 2425 26 27 28 29 30 31 Rad i Avg.

0.250 0.214 0.178 0. 4 30 0. 697 0.376 0.634 1.039 1.094 1.242 1.193 1.329 1.333 1.147 al Power Max.

IR 0.258 39 0.224 21 0.180 51 0.595 33 1.220 35 1.176 27 1.229 19 1.299 33 1.346 37 1.361 35 1.335 39 1.433 31 1.476 37 1.322 27 JR 48 2

32 43 36 23 29 32 32 34 34 34 44 (38-25 IR.:

2 10 14 18 22 16 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Dag-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (9)

Source Converentce

6. 40 0.9D732 0.445 22.709 18. 269 545.6

50. 39 12.9 3.5 0.001341 2 AXIAL TILT -22.481

-13.934 AVG BOT 8ft,1l2ft 1.1675 1.1251 Active Channel Flow: Mlb/hr (of total tore flow)

(of total Core flow) 41.38 Top Ten Thermel Limits Summary -

Surted by Margin Power MC PP.

APLHGP HG4R Value 1.476 1.459 1.444 1.438 1.438 1.421 I.420 1.415 1. 4039 1. 4(9 FT 30 30 30 30 29 30 30 30 29 29 IP 37 35 33 39 31 31 39 33 37 37 JR 34 30 32 26 40 36 33 30 Value 1.896 1.898 1.915

1. 917 1.926 1.935 1.936 1.940 1.943 1. 946 Margin

0. 833 0.9333 0.829 0.326 0.a22 U c.

031 0.320 0.817 FT 30 27 26 23 23 30 30 26C OR,JR 35 3 2 35 20 37 32 31 34 33 40 31 23 29 29 13 30 37 34 37 36 VaiLe Margin 7.85 0.5'11 7.4' 0.784 7.53 0.783 7.39 0.786 7.52 0.771

6. 65 0.758 7.12 0.754 S6.40 0.751 7.31 0.750 7.45 0.748 Exp.

36.1 38.2

6. 7 38.1 35.2 44.1

35. 4

32. 9 ET

'P28 28 22 2 7 27 IR 13 15 15 41 31 11 35 17 13 17 JR 34 36 3 2-32 42 33 34 (3

4 4

4 7

4 5

4 Value 3.46 9.06 8.13 7.42 7.99 9.08 3.08 7.74 11.27 7.35 Margin 0.57 0,839 0 823 0.836 0.82 0 3057 I.799 0.705 EXp.

34.0U 3

. 5

35. 4

42. 3 35.33 3* 2C 36.5 17.8 34.1 FT

-3 26

-3 2'8

.7 28 2r 3U

-7 IR 13 37 37 1I 1i 13 31 35 37 37 JR 34 36 22 3(5 22 38 42 38 20 14 4

4 4

4 44 LHGR calculated with pin-power reconstruction k CPR calculated with pin-power reconstruction c CPR limit type 0

. Thermal limte file:

Figure A.17 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 6,500.0 MWdIMTU AREVA NP Inc.

Uontrolled Uo~cument ANP-3215(NP)

Revision 0 Page A-21 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subrooling: Btu/lbm Flow: Mlb/hr 28 7000.0

( 593.31 500.0 (

42.38 2004.0 (100.00 6) 1024.6

-23.38 58.20 (101.03 %)

Core Average Exoosure:

MWd/MTU 24056.7 1

3 5

7 9

11 13 15 17 19 21 23 25 3

5 7

9 13 - -

13 --

15 --

17 19 21 2 3 25 IR: 2 18 --

8 38 0

38 0

0 38 8

51 47 43 39 35 31 18 --

27

-23 19 15 11 7

3 N (PRA)

Top 242 3 21 20 JR 19 18 17 16 15 14 13 12 11 10 9

7 6

54 Bottom I

Axial Profile Power Exposure 0.158 3.346 0.363 7.658 0.615 14.639 0.733 18.586 0.809 21.518 0.856 23.505 0.889 24.786 0.916 25.851 0.923 26.010 0.946 26.958 1.020 26.898 1.075 26.605 1.122 27.681 1.170 28.574 1.225 29.115 1.292 29.673 1.353 30.357 1.406 30.893 1.459 31.545 1.482* 31.870*

1.458 31.020 1.353 27.975 1.061 21.444 0.316 6.277 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radi Avg.

0.248 0.211 0.176 0.427

0. 682 0.873 0.630 1.034 1.090 1.238 1.189 1.334 1.339 1.156 al Power Max.

IR 0.256 39 0.221 21 0.178 51 0.592 33 1.212 35 1.162 27 1.219 19 1.289 33 1.341 37 1.351 35 1.334 39 1.440 31 1.483 37 1.333 27 JR 482 32' 48 36 28 28 32 32 3434 28 34 44 0

38 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Vold Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow Total Water Rod Flow (6)

Source Convergence 6.40 0.99732 0.445 22.925 18.485 545.6 50.71 12.9 3.5 0.00043

% AXIAL TILT -22.472 -14.037 AVG BOT 8ft/12ft 1.1664 1.1250 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.68 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value 1.483 1.460 1.448 1.443 1.440 1.431 1.430 1.422 1.418 1.417 FT 30 30 30 30 29 30 30 30 29 30 IR 37 35 39 33 31 31 39 33 37 35 JR 34 32 32 30 28 40 36 38 38 40 Value 1.926 1.932

1. 934 1.944 1. 945 1.953 1.953 1.960 1.965 1.966 MCPR Margin FT 0.825 27 0.823 28 0.822 26 0.818 28 0.816 30 0.814 30 0.814 29 0.811 29 0.809 26 0.809 26 APLHGR IR 35 39 37 33 35 37 31 29 37 35 JR 20 34 32 40 32 34 28 28 36 30 Value 7.90 7.4.8 7.44 7.55 6.75 7.46 7.36 7.15 6.47 7.14 Margin 0.825 0.797 0.794 0.793 0.776 0.772 0.763 0.762 0.753 0.752 Exp.

37.1 39.1 39.2 37.7 45.0 36.2 36.3 39.2 46.2 38.0 FT 28 26 26 23 28 27 26 22 28P IR 13 41 15 15 11 31 13 17 17 19 JR 34 32 36 32 36 42 38 38 36 40 K

4 4

4 7

4 4

4 5

Value 8.50 8.09 8.15 7.51 8.10

8. 13 7.75 7.89 8.00 11.37 LHGR Margin Exp.

FT 0.872 35.2 28 0.852 37.7 26 0.849 36.5 26 0.843 43.3 23 0.942 36.4 28 0.832 35.0 27 0.816 37.6 26 0.810 35.2 27 0.809 33.7 28 0.808 19.2 30 IR 13 37 37 1i 11 13 35 37 31 37 JR 34 36 22 36 22 38 38 14 42 20 K

4 44 4

4 4

7 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.18 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 7,000.0 MWd/MTU AREVA NP Inc.

uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-22 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 7500.0 6 635.69 500.0 (

42.38 2004.0 (100.00 6) 1024.6

-23.19 58.64 (101.80 8)

Core Average Exposure:

MWd/MTU 24556.8 1

3 5

7 9

13 -

15 -

17 19 21 23 25 1

3 5

7 9

11 38 0

18 13 15 17 19 21 38 0

038 38---------

23 25 51 47 43 39 35 31 18 --

27 S 12 19 15 11 7

3 N (PC Top JR Bottom Axial Profile RA) Power Exposure 24 0.159 3.425 23 0.367 7.855 22 0.621 14.980 21 0.736 18.991 20 0.810 21.964 19 0.856 23.977 18 0.888 25.276 17 0.915 26.356 16 0.922 26.519 15 0.945 27.479 14 1.017 27.401 13 1.070 27.110 12 1.115 28.208 11 1.161 29.123 10 1.214 29.689 9

1.281 30.279 8

1.344 30.993 7

1.400 31.554 6

1.459 32.232 5

1.489* 32.570*

4 1.471 31.710 3

1.368 28.616 2

1.071 21.947 1

0.319 6.427 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.246 0.254 39 0.209 0.218 21 0.174 0.176 51 0.425 0.589 33 0.678 1.204 35 0.869 1.148 27 0.626 1.210 19 1.029 1.281 31 1.087 1.336 37 1.235 1.341 35 1.184 1.331 39 1.339 1.442 31 1.346 1.489 37 1.165 1.346 27 JR 48 2

32 48 36 28 28 30 32 34 34 28 34 44 0

38 IR: 2 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

(%):

Source Convergence 6.40

0. 99753 0.443

23. 193 18.752 545.7 51.10 12.9 3.5 0.00036

% AXIAL TILT -22.436 -14.087 AVG BOT Sft/12ft 1.1654 1.1249 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.07 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLOGR Value FT 1.489 30 1.462 30 1.457 30 1.444 30 1.442 29 1.441 30 1.439 30 1.428 30 1.426 30 1.426 29 IR 37 35 59 33 31 31 39 33 35 37 JR 34 32 32 40 36 38 40 38 Value 1.948 1.949 1.956 1.961 1.965 1.965 1.971 1.986

1. 987

1. 987 Margin 0.816 0.816 0.813 0.811 0.809 0.809 0.807 0.801 0.800 0.800 FT 28 26 27 29 30 30 29 26 30 28 IR 39 37 35 33 35 37 31 37 39 29 JR 34 32 20 40 32 34 2r 36 36 29 Value

7. 90 7.52 7.42 7.53 6.80 7.42 7.38 7.12 7.13 7.18 Margin 0.834 0.810 0.800 0.799 0.790 0.775 0.771 0.767 0.759 0.752 Exp.

38.2 40.1 40.2 38.7 45.8 37.2

37. 3 40.1 39.0 37.4 FT 28 28 26 26233 28 27 26 28 27 IOR 13 41 15 15 11 31 13 17 19 15

.JR 34 32 36 36 42 38 38 40 40 K

4 4

4 7

4 4

5 4

Value 8.48 8.07 7.54 6.15 8.13 6.14 7.74

7. 90 11.37 7.70 Margin 0.881 0.861 0.858 0.857 0.857 0.843 0.824 0.820 0.818 0.815 LHGR Exp.

FT 36.4 28 38.8 26 44.4 23 37.6 29 37.7 26 36.1 27 38.6 26 36.3 27 20.7 30 38.1 26 IR 13 37 11 11 37 13 35 37 37 13 JR 34 36 36 22 22 38 38 14 20 30 K

4 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.19 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 7,500.0 MWd/MTU AREVA NP Inc.

Uontrolled Document ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-23 Cycle:

Exposure: MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr Core Average Exposure: MWd/MTU 25056.8 8000.0 678.07 500.0 42.38 2004.0 (100.00 %)

1024.6

-23.07 58.90 (102.25 %)

1 3

5 7

9 11 13 15 17 19 21 23 25 3

5 7

9 11 13 --

15 17 19 21 23 25 IR: 2 19 8

38 38 --

0 0

0 --

0 38 38 --

51 47 43 39 35 31 8

27 23 19 15 1i 7

3 N (PR Top JR Bottom Axial Profile RA) Power Exposure 04 0.161 3.505 23 0.371 8.055 22 0.627 15.323 21 0.740 19.398 20 0.814 22.412 19 0.859 24.450 18 0.890 25.767 17 0.917 26.861 16 0.923 27.027 15 0.945 28.001 14 1.017 27.903 13 1.069 27.613 12 1.111 28.731 1i 1.154 29.667 10 1.206 30.258 9

1.273 30.881 8

1.336 31.624 7

1.395 32.212 6

1.457 32.919 5

1.490* 33.271, 4

1.474 32.403 3

1.374 29.262 1.076 22.453 1

0.320 6.577 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radi Avg.

0.244 0.207 0.172 0.422 0.673 0.866 0.622 1.024 1.083 1.231 1.179 1.345 1.352 1.174 al Power Max.

IR 0.252 39 0.216 21 0.174 51 0.587 33 1.195 35 1.135 27 1.202 19 1.273 31 1.330 37 1.331 35 1.327 39 1.446 31 1.493 37 1.360 27 JR 48 2

32 48 36 28 26 30 32 34 34 28 34 44 6 10 14 18 22 26 30 34 3S 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence 6.40

0. 99757 0.442 23.343 18.902 545.7 51.33 12.8 3.5 0.00031

% AXIAL TILT -22.225 -14.133 AVG BOT 8ft/12ft 1.1638 1.1248 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.29 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR LHGR Value 1.493 1.464 1.463 1.450 1.446 1.446 1.445 1.434 1.433 1.432 FT 30 30 30 30 29 30 30 30 30 29 IR 37 35 39 31 31 33 39 35 33 17 JR 34 32 32 40 28 30 36 40 38 38 Value margin 1.960 0.811 1.965 0.809 1.974 0.805 1.975 0.805 1.976 0.805 1.977 0.804 1.980 0.803 1.992 0.798 1.999 0.795 1.999 0.795 FT 26 28 30 27 28 30 29 30 30 30 IR 37 39 37 35 33 35 31 39 19 39 JR 32 34 34 34 40 32 28 36 30 Value Margin 7.81 0.833 7.48 0.812 7.44 0.798 7.31 0.798 6.78 0.795 7.38 0.779 7.32 0.773 7.02 0.766 7.09 0.762 7.14 0.755 Exp.

39.2 40.8 39.7 41.1 46.7 38.2 39.2 41.0

39. 9

38. 3 FT 28 28 26 26 23 28 27 26 28 27 IR 13 11 15 15 11 31 13 17 19 15 JR 34 32 32 36 36 42 38 38 40 40 K

4 4

4 7

4 4

5 4

Value Margin 8.37 0.881 8.10 0.863 7.50 0.863 7.97 0.860 8.02 0.856 8.06 0.845 7.65 0.824 7.94 0.823 7.91 0.918 11.21 0.816 Exp.

37.6 38.7 45.4 39.8 38.8 37.2 39.7 37.4 36.0 22.0 FT 28 28 23 26 26 27 26 2728 30 IR 13 11 11 15 37 13 35 37 31 15 JR 34 22 36 36 22 38 38 14 42 34 K

4 44 4

4 4

7 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction 6 CPR limit type 0 Thermal limit file:

Figure A.20 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 8,000.0 MWd/MTU AREVA NP Inc.

Uontrolled uocument ANP-3215(NP)

Revision 0 Page A-24 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 8500.0

( 720.45 500.0

(

42.38 2004.0 (100.00 5) 1024.6

-23.20 58.61 (101.75 6)

Core Average Exposure:

MWd/MTU 25556.8 1

3 5

7 9 11 13 15 17 19 21 23 25 3

5 7

9 13 --

15 --

17 19 21 23 25 IR: 2 18 8

38 0

0 38 38 0

0 33 51 47 43 39 35 31 8 --

18 --

27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.164 3.585 23 0.376 8.258 22 0.634 15.670 21 0.747 19.808 20 0.819 22.863

JR 19 0.864 24.925 18 0.896 26.260 17 0.923 27.369 16 0.929 27.538 15 0.951 28.524 14 1.022 28.406 13 1.072 28.116 12 1.112 29.254 11 1.153 30.210 10 1.203 30.825 9

1.269 31.480 8

1.332 32.253 7

1.390 32.868 6

1.450 33.604 5

1.479' 33.9711 4

1.461 33.095 3

1.365 29.907 2

1.070 22.959 Bottom 1

0.318 6.727 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.243 0.251 39 0.206 0.214 21 0.171 0.172 51 0.421 0.586 33 0.670 1.186 35 0.864 1.123 27 0.620 1.194 19 1.020 1.266 31 1.079 1.324 37 1.226 1.320 35 1.174 1.321 39 1.350 1.450 31 1.356 1.494 37 1.182 1.375 27 JR 48 2

3 2 4836 23 28' 30 32 34 34 28 34 44 6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

I k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%)

Source Convergence 6.40 0.99744 0.442 23.155 18.715 545.7 51.08 12.8 3.5 0.00050

% AXIAL TILT -21.689 -14.170 AVG BOT 8ft/12ft 1.1610 1.1247 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.05 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.49' 1.46' 1.466 1.45) 1.45) 1.44)

1. 447 1.43)

1. 436 1.435 Power e FT 4 30 6 30 03 8 30 0 29 8 30 7 30 9 30 6 30 5 29 IR 37 35 09 31 31 33 39 35 33 37 JR 34 32 32 40 28 30 36 40 38 38S Value 1.962 1. 974 1.975 1.976

1. 977 1.931 1.992 1.987 1.991 1.995 MCPR Margin FT 0.810 26 0.806 30 0.805 29 0.805 30 0.804 28 0.802 28 0.802 27 0.800 30 0.799 30 0.797 30 IR 37 37 31 35 39 33 35 39 39 19 JR32 34 28 32 34 40 34 36 32 30 Value 7.60 7.31

6. 66 7.25 7.11 7.35 7.17 6.21 6.98 6.19 Margin 0.820 0.802 0.789 0.786 0.784 0.783 0.765 0.759 0.759 0.757 APLHGR Exp.

40.2 41.3 47.6 40.6 42.1 39.1 39.2 50.6 40.8 50.8 FT 29 28, 23 26 26 28 27 22 28 24 IR 13 11 11 15 15 31 13 25 19 27 JR 34 32 36 32 36 42 38 42 40 42 K

4 4

4 7

5 7

Value 8.19

7. 34

7. 92 7.75 7.80 7.87 7.86 7.67 7.46 7.90 Margin 0.868 0.855 0.855 0.847 0.843 0.835 0.824 0.816 0.814 0.814 LHGR Exp.

FT 38.1 28 46.5 23 39.8 28 40.9 26 39.9 26 38.3 27 37.1 29 38.4 27 40.8 26 35.5 27 IP JR 13 34 11 36 11 22 15 36 37 22 13 38 31 42 37 14 35 38 29 44 K

4 4

44 4

4 7

4 4

7 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.21 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 8,500.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-25 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: B5u/ibm Flow: Mlb/hr 28 8818.0 ( 747.40 318.0 (

26.95 2004.0 (100.00 8) 1024.6

-23.69 57.51

( 99.84 %)

Core Average Exposure:

MWd/MTU 25874.8 35 7

9 11 --

13 15 --

17 19 21 23 25 IR: 2 3

5 38 38 7

9 11 13 12 0

15 17 19 21 23 25 51 47 43 39 35 S --

38 31 27 8 --

38 23 19 15 11 7

3 N (P1 Top JR Bottom Axial Profile RA) Power Exposure 24 0.178 3.640 23 0.404 8.392 22 0.674 15.899 21 0.783 20.077 20 0.843 23.154 19 0.875 25.230 18 0.894 26.574 17 0.914 27.691 16 0.920 27.862 15 0.946 28.856 14 1.019 28.727 13 1.069 28.437 12 1.109 29.587 11 1.149 30.555 10 1.198 31.184 9

1.263 31.859 8

1.324 32.651 7

1.379 33.283 6

1.435 34.036 5

1.460, 34.4111 4

1.442 33.530 3

1.347 30.314 2

1.058 23.278 1

0.315 6.821 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.237 0.252 47 0.164 0.172 21 0.201 0.203 51 0.415 0.590 47 0.661 1.190 35 0.821 1.138 27 0.645 1.221 41 1.029 1.279 29 1.083 1.309 31 1.224 1.323 33 1.175 1.317 39 1.359 1.480 39 1.369 1.490 33 1.174 1.412 43 JR 40 2

32 34 36 28 28 32 3S 36 34 28 38 28 0

12 --

6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

():

Total Water Rod Flow ():

Source Convergence 6.34

0. 99737 0.441 22.475 18.037 545. 6 50.12 12.9 3.5 0.00039

% AXIAL TILT -20.658 -14.182 AVG BOT 8ft/12ft 1.1521 1.1246 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.13 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.490 1.483 1.480 1.472 1.466 1.461 1.456 1.447 1.446 1.444 FT 30 30 29 30 29 30 30 30 30 29 IR 33 39 39 31 25 29 37 39 31 29 JR 38 32 28 36 32 34 34 36 40 30 Value Margin 1.908 0.833 1.912 0.832 1.925 0.826 1.931 0.824 1.935 0.822 1.946 0.817 1.955 0.813 1.956 0.813 1.959 0.811 1.961 0.811 FT 29 29 27 30 30 30 28 26 2830 IR 27 39 33 39 21 29 37 39 39 19 JR 32 28 36 32 36 20 28 30 34 38 Value 7.43 7.40 7.39

6. 55 7.11 6.24

6. 94 6.22 7.29 6.97 Margin 0.807 0.796 0.790 0.777 0.773 0.768 0.768 0.765 0. 763 0.752 Exp.

FT 40.8 28 39.9 28 39.4 28 47.7 23 40.9 26 51.3 24 42.5 26 51.1 22 37.5 27 40.1 27 IF.

19 21 41 17 21 41 17 11 43 37 JR 40 42 32 42 38 2 6 38 28 24 40 K

4 4

7 4

7 7

4 Value Margin 7.99 0.854 7.96 0.844 7.20 0.839 7.57 0.832 7.91 0.831 7.66 0.930 7.95 0.821 7.65 0.319 6.40 0.804 7.51 0.803 LHGR Exp.

FT 33.9 28 38.3 28 46.4 23 41.4 26 37.4 28 40.2 26 35.8 27 39.1 27 52.4 22 39.0 27 IR 19 21 35 35 41 21 43 37 11 13 JR 40 12 12 38 22 38 30 14 28 39 K

4 4

7 4

6 4

LHGR calculated with pin-power reconstruction

+ CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.22 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 8,818.0 MWd/MTU AREVA NP Inc.

Uontrolled uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-26 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr 28 9000.0 ( 762.83 182.0

(

15.43 2004.0 (100.00 %)

1024.6

-23.68 57.53 ( 99.88 %)

Core Average Exposure:

MWd!MTU 26056.8 1

5 7

9 11 13 15 17 19 21 23 25 13 5

7 9

11 --

13 15 --

17 19 21 23 25 IR: 2 38 --

8 38 --

8 --

12 0

8 --

38 --

v 8 __ 38 --

51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.179 3.672 23 0.407 8.472 22 0.679 16.035 21 0.788 20.235 20 0.848 23.324

JR 19 0.880 25.406 18 0.899 26.754 17 0.919 27.875 16 0.925 28.047 15 0.952 29.047 14 1.025 28.910 13 1.074 28.620 12 1.113 29.777 01 1.152 30.752 10 1.200 31.390 9

1.264 32.076 8

1.323 32.878 7

1.376 33.519 6

1.429 34.282 5

1.448" 34.661-4 1.427 33.776 3

1.333 30.544 2

1.047 23.458 Bottom 1

0.312 6.875 Edit Zone 16 18 20 21 22 23 24 252 6 27 28 29 30 31 Radial Power Avg.

Max.

IR JR 0.236 0.252 47 40 0.164 0.172 21 2

0.200 0.202 51 32 0.414 0.589 47 34 0.659 1.187 35 36 0.820 1.134 27 28 0.644 1.221 41 28 1.027 1.276 29 32 1.081 1.306 31 38 1.223 1.319 33 36 1.173 1.316 39 34 1.361 1.482 39 28 1.370 1.490 33 38 1.177 1.416 43 28 0

12 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

(%):

Source Convergence 6. 34 0.99737 0.440 22.475 18.036 545.6 50.14 12.8 3.5 0.00042

% AXIAL TILT -20.192 -14.184 AVG BOT 8fr/12ft 1.1499 1.1245 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.15 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT 1.490 30 1.485 30 1.482 29 1.472 30 1.467 29 1.461 30 1.457 30 1.448 30 1.446 30 1.445 29 IR JR 33 38 39 32 39 28 31 36 25 32 29 34 37 34 39 36 31 40 29 30 Value

1. 908 1.909 1.927 1.928 1.935 1.945 1.955 1.957 1.958

1. 962 MCPR Margin FT 0.833 29 0.833 29 0.825 30 0.825 27 0.822 30 0.817 30 0.813 26 0.812 28 0.812 28 0.810 30 IR JR 27 32 39 28 39 32 33 36 31 36 29 20 39 30 37 28 39 34 19 38 Value 7.31 7.37 7.30 6.47 6.22 6.20 7.26 6.99 6.82 6.89 APLHGR Margin Exp.

FT 0.797 41.1 28 0.791 39.7 28 0.788 40.2 28 0.770 48.0 23 0.768 51.6 24 0.765 51.4 22 0.764 37.9 27 0.763 41.2 26 0.758 42.9 26 0.743 40.2 27 IR JR 19 40 41 32 21 42 17 42 41 26 11 28 43 24 21 38 17 16 15 40 K

4 7

4 4

7 77 4

4 4

Value 7.86 7.86 7.89 7.11 7.44 7.92 7.54 7.53 6.46

6. 50 LHGR Margin Exp.

FT 0.844 39.3 28 0.837 38.7 28 0.832 37.8 28 0.832 46.8 23 0.822 41.8 26 0.821 36.2 27 0.320 40.6 26 0.R30 39.5 27 0.802 51.5 22 0.801 51.0 24 IR JR 19 40 21 12 41 32 35 12 35 38 43 30 21 38 37 14 11 28 41 26 K

4 4

7 4

4 74 4

7 7

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.23 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 9,000.0 MWd/MTU AREVA NP Inc.

Uontrolled uocument ANP-3215(NP)

Revision 0 Design (EPU/MELLLA)

Page A-27 Monticello Fuel Transition Cycle 28 Fuel Cycle Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 9500.0

) 805.21 500.0 (

42.38 2004.0 (100.00 9) 1024.6

-23.43 58.08 (100.83 6)

Core Average Exposure:

MWd/MTU 26556.7 1

3 5

7 9 11 13 15 17 19 21 23 25 1

3 5

7 9

13 15 17 19 21 23 25 IR:

2 6

10..

38 38 8

8 0

8 38 51 47 43 39 35 31 27 23 19 15 11 7

Axial Profile N(PRA) Power Exposure Top 24 0.183 3.762 23 0.415 8.695 22 0.690 16.412 21 0.798 20.672 20 0.856 23.794

JR 19 0.887 25.894 18 0.911 27.253 17 0.935 28.386 16 0.943 28.563 15 0.972 29,578 14 1.047 29.421 13 1.097 29.131 12 1.135 30.306 11 1.170 31.298 10 1.216 31.958 9

1.276 32.674 8

1.329 33.503 7

1.371 34.167 6

1.408 34.950 5

1.409' 35.334' 4

1.373 34.436 3

1.277 31.159 2

1.003 23.941 Bottom 1

0.298 7.018 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IF 0.235 0.251 47 0.160 0.167 21 0.199 0.201 51 0.411 0.589 47 0.656 1.187 11 0.815 1.126 27 0.640 1.226 41 1.024 1.272 29 1.079 1.306 39 1.220 1.311 33 1.171 1.316 39 1.367 1.492 39 1.375 1.494 39 1.183 1.432 43 JR 40 2

32 34 28 28 28 32 30 36 34 28 32 28 0

10 8 --

38 --

t0 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

%):

Source Convergence 6.40 0.99737 0.434 22.754 18.315 545.5

50. 65 12.8 3.4 0.00039

% AXIAL TILT -18.889 -14.172 AVG BOT 8ft/12ft 1.1454 1.1241 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.65 Top Ten Thermal Limits Summary -

Sorted by Margin Valu1 1.494 1.492 1.490 1.474 1.47:

1.465 1.461 1.45:

1.450 1.448 Power e FT 30 29 3n 30 3 29 5 30 30 3 30 29 30 IR 39 39 33 31 25 29 37 39 29 31 JR 32 28 38 36 32 34 34 36 30 40 Value 1.903 1.912 1.922 1.938 1.942 1.949 1.952 1.956 1.962 1.969 MCPR Margin FT 0.835 29 0.832 29 0.827 30 0.821 27 0.819 30 0.816 30 0.815 26 0.813 28 0.811 28 0.808 30 IR 39 27 39 33 21 29 39 39 37 39 JR 28 32 32 36 36 20 30 34 28 36 Value 7.32

6. 19 6.17

6. 98 7.05 7.23 6.22 6.74 6.67 6.51 Margin 0.794 0.772 0.769 0.769 0.769 0.767 0.747 0.737 0.736 0.733 APLHGR Exp.

40.7 52.4 52.2 42.0 41.2 38.8 48.8 41.3 42.1 43.9 FT 28 24 22 28 28 27 23 26 26 26 IR JR 41 22 41 26 11 28 19 40 21 42 43 24 17 42 39 30 21 38 35 38 K

7 7

7 4

4 7

4 5

Value 7.82 7.87 7.59 7.56 6.82 6.42 6.49

7. 18 7.07 7.17 Margin 0.835 0.826 0.819 0.814 0.807 0.806 0.805 0.791 0.790 0.780 LHGR Exp.

FT 38.9 28 37.3 27 39.8 28 39.6 28 47.8 23 52.4 22 51.4 24 41.6 26 42.9 26 40.5 27 IR 41 43 21 19 35 11 41 21 35 37 JR 22 30 12 14 12 28 26 38 38 14 K

7 74 4

4 7

7 45 4

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.24 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 9,500.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-28 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWr Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 10000.0

( 847.59 500.0 (

42.38 2004.0 (100.00 %)

1024.6

-23.53 57.85 (100.43 %)

Core Average Exposure:

MWd/MTU 27056.8 1

1 3

5 7

9 11 13 10 0

15 17 19 21 23 25 5

7 9

11 --

13 15 --

17 19 21 23 25 IR: 2 38 --

S --

38 --

8 6 10 14 18 22 0

S 0--

51 47 43 39 35 38...-

31 27 38 -

23 19 15 11 7

N4 (PR Top

JR Bottom Axial Profile RA) Power Exposure 24 0.188 3.854 23 0.426 8.923 22 0.707 16.796 21 0.816 21.117 20 0.875 24.271 19 0.908 26.388 18 0.934 27.761 17 0.960 28.908 16 0.970 29.090 15 1.000 30.122 14 1.076 29.945 13 1.126 29.654 12 1.162 30.846 11 1.193 31.854 10 1.234 32.534 9

1.287 33.278 8

1.330 34.129 7

1.356 34.809 6

1.373" 35.605 5

1.351 35.984' 4

1.300 35.066 3

1.202 31.743 2

0.945 24.400 1

0.281 7.155 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.234 0.250 47 0.159 0.167 21 0.199 0.200 51 0.411 0.589 47 0.653 1.189 11 0.814 1.122 41 0.639 1.228 41 1.020 1.267 29 1.076 1.305 39 1.217 1.302 33 1.167 1.313 39 1.370 1.500 39 1.377 1.499 39 1.190 1.444 43 JR 40 2

32 34 28 36 28 32 30 36 34 28 32 28 10 26 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (6):

Total Water Rod Flow (A):

Source Convergence 30 34 38 42 46 50 6.40 0.99736 0.429 22.552 18.113 545.5 50.47 Active 12.8 (of to:

3.4 (of to' 0.00048 3

% AXIAL TILT -16.785

-14.128 AVG BOT 8ft/12ft 1.1366 1.1236 Channel Flow: Mlb/hr tal core flow) tal core flow) 48.48 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value 1.500 1.499 1.488 1.476 1.474 1.466 1.462 1.455 1.452 1.448 FT 29 30 30 29 30 30 30 30 29 30 IR 39 39 33 25 31 29 37 39 29 31 JR 28 32 38 32 36 34 34 36 30 40 Value 1.885 1.903 1. 905 1.933 1.935 1.936 1.939 1.944 1.955 1.957 MCPR Margin FT 0.843 29 0.835 29 0.835 30 0.823 30 0.822 27 0.821 26 0.820 30 0.818 28 0.813 28 0.812 30 APLHGR IR 39 27 39 31 33 39 29 39 37 39 JR 28 32 32 36 36 30 20 34 28 36 Value 7.22 6.12 6.11 7.15

6. 69

6. 65 6.54 5.81

6. 50 5.72 Margin 0.792 0.772 0.769 0.767 0.737 0.734 0.732 0.718 0.717 0.708 Exp.

41.7 53.2 53.0 39.7 42.1 42.2 43.5 51.3 42.1 51.3 FT 28 24 22 27 28 26 28 23 28 23 IR 41 41 11 43 21 39 19 35 39 41 JR 22 26 28 24 42 30 40 42 34 36 K

7 7

4 7

5 5

6 6

Value 7.70 7.77

6. 33 6.41 7.22

7. 14 6.32 7.07 10.19 6.22 Margin 0.833 0.825 0.805 0.804 0.787 0.775 0.773 0.771 0.759 0.759 LHGR Exp.

FT 40.0 28 38.4 27 53.4 22 52.4 24 40.8 28 40.4 28 50.4 23 40.7 26 24.6 30 50.1 23 IR JR 41 22 43 30 11 28 41 26 21 12 19 14 35 12 39 24 41 24 11 36 K

7 7

4 4

5 7

7 6

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.25 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 10,000.0 MWd/MTU AREVA NP Inc.

uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-29 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 10250.0

( 868.78 250.0

(

21.19 2004.0 (100.00 %)

1024.6

-23.45 58.03 (100.74

%)

Core Average Exposure:

MWd/MTU 27306.8 1

3 5

7 9

11 13 15 17 19 21 23 25 IR:

1 3

5 7

9 11 38 --

8 --

38 8 --

13 10 0

15 17 8

19 21 23 25 51 47 43 39 35 38 31 27 38 2-19 15 11 7

3 N (P1 Top JR Bottorm Axial Profile RA) Power Exposure 24 0.191 3.901 23 0.433 9.040 22 0.717 16.992 21 0.827 21.343 20 0.887 24.515 19 0.920 26.640 18 0.948 28.021 17 0.975 29.175 16 0.986 29.360 15 1.017 30.400 14 1.094 30.213 13 1.143 29.921 12 1.177 31.121 11 1.206 32.136 i0 1.244 32.826 9

1.293 33.582 S

1.329 34.442 7

1.347 35.128 6

1.352-35.926 5

1.317 36.299*

4 1.259 35.367 3

1.159 32.021 2

0.910 24.619 1

0.271 7.219 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.233 0.250 47 0.158 0.166 21 0.198 0.200 51 0.410 0.588 47 0.652 1.191 11 0.813 1.121 41 0.638 1.229 41 1.019 1.264 29 1.075 1.305 39 1.216 1.298 33 1.165 1.312 39 1.372 1.504 39 1.379 1.502 39 1.193 1.450 43 JR 40 2

32 34 28 36 28 32 30 36 34 28 3228 O

2 6 10 14 18 22 10 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (:)

Total Water Rod Flow (%)

Source Convergence 26 30 34 38 42 46 50 6.40 0.99750 0.425 22.617 18.178 545.4 50.64 Active 12.7 (of to 3.4 (of tol 0.00049 2 AXIAL TILT -15.534

-14.091 AVG POT Sft/12ft 1.1314 1.1233 Channel Flow: Mlb/hr tal core flow) tal core flow) 48.66 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.504 1.502 1.488 1.477 1.474 1.467 1.463 1.456 1.453 1.451 FT 29 30 30 29 30 30 30 30 29 30 IR 39 39 33 25 31 29 37 39 29 41 JR 28 32 38 32 36 34 34 36 30 30 Value 1.881 1.900 1.903 1.932

1. 933 1.936 1.939 1.940 1.951 1.954 Margin 0.845 0.837 0.835 0.823 0.822 0.821 0.820 0.820 0.815 0.814 FT 29 30 29 26 30 27 30 28 31 28 IR 39 39 27 39 31 33 29 39 43 37 JR 28 32 32 30 36 36 20 34 26 28 Value 7.15 6.18 6.14 7.10 6.59 6.49

6. 37 6.55 5.66 5.63 Margin 0.789 0.772 0.768 0.765 0.731 0.718 0.717 0.713 0.703 0.700 Exp.

42.2

52. 5

52. 6 40.2 42.7 42.5 43.9 41.0 51.7 51.7 FT 28 24 22 27 26 28 28 28 23 23 IR 41 41 11 43 39 21 19 39 35 41 JR 22 26 28 24 30 42 40 34 42 36 K

7 8

8 7

7 4

5 7

5 6

Value

7. 62 7.71 6.39 6.45 7.00 7.00 6.16 6.80 10.07 6.12 Margin 0.830 0.823 0.806 0.805 0.768 0.768 0.758 0.757 0.754 0.750 LHGR Exp.

FT 40.6 28 38.9 27 52.7 22 51.9 24 41.3 28 41.2 26 50.8 23 42.5 28 25.2 30 50.6 23 IR 41 43 11 41 21 13 35 19 41 11 JR 22 30 28 26 12 30 12 40 24 36 K

7 7

8 84 7

5 5

7 6

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.26 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 10,250.0 MWdlMTU AREVA NP Inc.

uontrolleci Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-30 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 2I 10472.0

( 387.59 222.0

(

18.82 2004.0 (100.00 %)

1024.6

-23.43 58.07 (100.82 %)

Core Average Exposure:

MWd/MTU 27528.8 1

3 5

7 9

1 3

5 7

9 13 15 17 19 21 0

11 13 15 17 0

0 0

0 22 26 30 34 0

19 21 23 25 51 47 43 39 35 31 27 2 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.156 3.939 23 0.357 9.135 22 0.602 17.154 21 0.709 21.531 20 0.790 24.720

JR 19 0.845 26.856 18 0.889 28.246 17 0.929 29.408 16 0.951 29.597 15 0.989 30.645 14 1.069 30.450 13 1.120 30.157 12 1.155 31.365 11 1.184 32.386 10 1.223 33.083 9

1.275 33.851 8

1.318 34.719 7

1.354 35.410 6

1.396 36.214 5

1.429 36.586*

4 1.431* 35.648 3

1.376 32.286 2

1.116 24.831 Bottom 1

0.338 7.283 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

OR 0.234 0.242 39 0.203 0.211 21 0.184 0.185 51 0.420 0.585 33 0.651 1.185 25 0.852 1.102 35 0.642 1.193 27 1.000 1.213 33 1.050 1.276 37 1.212 1.266 29 1.144 1.289 31 1.335 1.469 27 1.354 1.494 29 1.247 1.445 27 JR 48 2

32 48 42 42 42 32 32 44 42 40 42 44 23 25 IR:

2 6 10 14 18 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delca-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (9):

Total Water Rod Flow

(%)

Source Convergence 4.96 0.99765 0.445 22.841 18.407 545.7 50.60 12.9 3.5 0.00030

% AXIAL TILT -21.625 -14.078 AVG BOT 8ft/12ft 1.1702 1.1232 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.59 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.494 1.47 1.469 1.465 1.453 1.445 1.444 1.435 1.427 1.426 Power e FT 30 5 30 9 29 30 330 31 30 30 7 30 6 9 IR JR 29 42 31 40 27 40 37 34 39 32 27 44 35 32 33 42 39 36 31 28 Value 1. 980 1.993 1. 995 1.998 2.005 2.012 2.016 2.019 2.021 2.023 MCPR Margin FT 0.803 27 0.798 30 0.797 28 0.796 29 0.793 30 0.790 30 0.789 31 0.787 28 0.787 30 0.786 30 IR JR 29 44 29 42 31 42 27 40 31 40 35 32 25 44 39 14 37 34 39 36 Value Margin 7.45 0.802 7.15 0.795 6.37 0.788 6.28 0.782 6.66 0.746 6.59 0.745 6.66 0.731 6.47 0.731 6.43 0.724 5.81 0.723 APLHGR Exp.

39.9 42.8 51.6 52.3 2 43.6 2 44.2 41.8 44.3 44.0 9 51.9 FT 27 28 22 24 26 28 (7

(8 28 23 IR 29 31 27 27 29 33 3

33 13 17 JR 10 12 12 42 14 24 14 34 42 K

4 4

4 5

5 5

Value 9.06 7.74 6.88 6.71 7.32 7.13 10.85 10.75 10.79 7.17 Margin 0.859 0.854 0.840 0.829 0.807 0.801 0.793 0.793 0.788 0.785 LHGR Exp.

FT 38.7 27 41.8 28 50.3 22 51.1 24 41.8 26 43.3 28 22.5 30 23.5 31 22.3 31 41.1 27 IR 29 21 27 27 29 11 29 31 27 43 JR 10 12 12 42 14 2 2 12 10 10 30 K

4 4

44 4

4 LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.27 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 10,472.0 MWd/MTU AREVA NP Inc.

uontrolled uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-31 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 10500.0

( 889.97 28.0

(

2.37 2004.0 (100.00 %)

1024.6

-23.38 58.20 (101.04 %)

Core Average Exposure:

MWd/MTU 27556.8 1

3 5

7 9

1 3

5 7

9 13 0

15-17 19 21 23 25 IR: 2 6 10 14 18 11 13 0

0 15 17 19 0

0 0

51 47 43 39 35 31 27 23 19 15 11 7

3 21 23 25 Axial Profile N(PRA)

Power Exposure Top 24 0.156 3.944 23 0.358 9.145 22 0.603 17.172 21 0.711 21.553 20 0.792 24.744

JR 19 0.847 26.883 18 0.891 28.273 17 0.932 29.437 16 0.953 29.626 15 0.991 30.676 14 1.072 30.480 13 1.122 30.187 12 1.158 31.395 11 1.187 32.417 10 1.224 33.116 9

1.275 33.885 8

1.318 34.754 7

1.352 35.446 6

1.393 36.251 5

1.424 36.623*

4 1.425' 35.686 3

1.370 32.322 2

1.112 24.860 Bottom 1

0.336 7.292 Edit Radial Power Zone Avg.

Max.

IR JR 16 0.234 0.242 39 48 18 0.203 0.211 21 2

20 0.183 0.185 51 32 21 0.420 0.585 33 48 22 0.651 1.185 25 42 23 0.852 1.102 35 42 24 0.642 1.193 27 42 25 1.000 1.213 33 32 26 1.050 1.275 37 32 27 1.212 1.266 29 44 28 1.144 1.289 31 42 29 1.335 1.470 27 40 30 1.354 1.495 29 42 31 1.247 1.446 27 44 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow ():

Source Convergence 4.96 0.99766 0.444

22. 912 18.477 545.7 50.72 12.9 3.5 0.00030

% AXIAL TILT -21.440 -14.080 AVG BOT 8ft/12ft 1.1695 1.1232 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.70 Top Ten Thermal Limits Summary -

Sorted by Margin Valu1

1. 495

1. 475

1. 470

1. 465 1. 452 1.44' 1.444 1.436 1.427 1.427 Power e FT 5 31 5 30 0 29 5 30 30 7 29 30 IR 31 27 37 39 27 35 33 31 39 JR 42 40 40 34 32 44 32 42 28 36 Value 1.981 1.994 1.996 1.998 2.005 2.015 2.016 2.022 2.023 2.024 MCPR Margin FT 0.803 27 0.797 30 0.797 28 0.796 29 0.793 30 0.789 31 0.789 30 0.7:6 28 0.786 30 0.785 30 IR 29 29 31 27 31 25 35 39 37 39 JR 44 42 42 40 40 44 22 34 34 36 Value Margin 7.43 0.799 7.13 0.792 6.35 0.785 6.25 0.779 6.63 0.7413 6.55 0.740 6.44 0.729 6.62 0.727 6.40 0.722 5.78 0.721 APLHGR Exp.

40.0 42.9 51.6 52.3 43.6 44.3 44.4 41.9 44.1 52.1 FT 27 28 22 24 26 28 28 27 23 IR 29 31 27 27 29 33 9

13 35 JR 10 12 12 42

1412, 14 24 34 42 K

4 4

4 45 4

5 5

Value 8.03 7.71 6.85

6. 68 7.28 7. 08 10.81 10.70 10. 77 7.13 Margin 0.856 0.852 0.837 0.626 0.804 0.796 0.791 0.791 0.786 0.751 LHGR Exp.

FT 38.3 27 41.3 26 50.3 22 11.2 24 41.8 26 43.4 28 22.5 30 23.6 31 22.4 31 41.1 27 IR JR 29 10 21 12 17 12 27 42 29 14 1i 22 29 12 31 10 27 10 43 30 K

4 4

4 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.28 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 10,500.0 MWd/MTU AREVA NP Inc.

u.ontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-32 Cycle:

Exposure: MWd/MTU (GWd) 1]

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr 1

3 5

7 9 11 13 15 1

28 I000.0

( 932.35 500.0

(

42.38 2004.0 (100.00 8) 1024.6

-23.27 58.45 (101.47 %)

17 19 21 23 25 51 47 Core Average Exposure:

MWd/MTU 28056.8 5

7 9

11 13 0

0 0

43 39 35 31 0

..- 27 23 19 15 11 7

3 N (PRA)

Top 24 23 22 21 20 JR 19 18 17 16 15 14 13 12 11 10 9

8 7

6 5

4 3

2 Bottom 1

Axial Profile Power Exposure 0.163 4.023 0.374 9.344 0.629 17.511 0.741 21.954 0.826 25.191 0.885 27.360 0.933 28.776 0.977 29.963 1.001 30.165 1.041 31.236 1.123 31.021 1.173 30.727 1.204 31.951 1.226 32.985 1.254 33.699 1.291 34.489 1.314 35.374 1.322 36.076 1.334" 36.893 1.332 37.273-1.307 36.330 1.241 32.937 1.005 25.359 0.303 7.442 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR JR 0.234 0.242 39 48 0.201 0.209 21 2

0.183 0.184 51 32 0.419 0.582 33 48 0.649 1.183 25 42 0.851 1.101 35 42 0.641 1.192 27 42 0.998 1.210 31 30 1.048 1.274 37 32 1.210 1.265 29 44 1.142 1.287 31 42 1.339 1.472 27 40 1.356 1.495 29 42 1.251 1.449 27 44 17 19 21 23 25 IR: 2 0

0 6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence

0. 99774 0.433 22.949 18.515 545.6 51.00 12.7 3.4 0.00045

% AXIAL TILT -17.777

-14.071 AVG BOT 8ft/12ft 1.1544 1.1231 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 48.99 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR LHGR Value 1.495 1.476 1.472 1.466 1.455 1.449 1.446 1.436 1.431 1. 429 FT 30 30 29 30 30 31 30 30 29 30 IR 29 31 27 37 39 27 35 33 31 33 JR 42 40 40 34 32 44 32 42 28 30 Value Margin 1.981 0.802 1.988 0.800 1.989 0.800 1.995 0.797 1.997 0.796 2.002 0.794 2.003 0.794 2.006 0.793 2.009 0.792 2.010 0.791 FT 30 27 29 30 31 28 30 30 30 289 IR 2929 27 31 25 31 35 37 39 39 JR 42 44 40 40 44 42 22 34 36 34 Value

6. 93 5.78 6.59 5.71 6.11 6.09 6.03 6.09 5.44 6.08 Margin 0.754 0.740 0.740 0.736

0. 699

0. 698

0. 689

0. 683 0.683 0.680 Exp.

FT 40.9 27 54.4 22 43.8 28 55.1 24 45.3 26 45.5 28 45.2 28 43.7 28 52.6 23 43.3 27 IP.

29 25 31 27 29 11 33 13 17 9

JR 10 12 12 42 14 22 14 34 12 24 K

4 54 5

5 55 6

55 Value Margin 7.47 0.807 7.13 0.797 6.18 0.736 6.03 0.777 6.67 0.752 6.54 0.747 10.07 0.744 10.01 0.741 5.90 0.738 9.87 0.737 Exp.

39.9

42. 9 53.4 54. 3 43.7 44.7

23. 7 23.9 52.1 24.9 FT 27 28 22 24 26 28 31 30 23 31 IR 29 21 27 27 29 11 27 29 35 31 JR 10 12 12 42 14 22 10 12 12 10 K

4 4

5 5

4 4

5 4

LHGR. calculated with pin-power reconstruction CPP calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.29 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 11,000.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Design (EPU/MELLLA)

Page A-33 Monticello Fuel Transition Cycle 28 Fuel Cycle Cycle:

Exposure: MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 11500.0

( 974.72 500.0 (

42.38 2004.0 (100.00 %)

1024.6

-23.02 59.03 (102.48 %)

Core Averaqe Exposure: MWd/MTU 28556.8 1

35 7

9 11 13 15 17 19 21 23 1

3 5

7 9

11 0

0..

..0 0

13 15 17 19 21 23 25 0

0 0

51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.170 4.105 23 0.391 9.551 22 0.657 17.865 21 0.773 22.371 20 0.863 25.656

JR 19 0.925 27.860 18 0.977 29.303 17 1.025 30.515 16 1.050 30.731 15 1.092 31.825 14 1.177 31.559 13 1.224 31.291 12 1.250 32.529 11 1.263 33.570 10 1.280 34.295 9

1.301 35.100 8

1.303* 35.991 7

1.287 36.,690 6

1.270 37.506 5

1.239 37.879, 4

1.192 36.918 3

1.116 33.493 2

0.902 25.808 Bottom 1

0.272 7.577 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.233 0.241 39 0.200 0.208 21 0.182 0.184 51 0.417 0.580 33 0.647 1.185 25 0.849 1.100 35 0.640 1.194 27 0.995 1.205 31 1.046 1.271 37 1.208 1.266 29 1.139 1.287 31 1.341 1.477 27 1.359 1.499 29 1.256 1.456 27 JR 48 2

32 48 42 42 42 30 32 44 42 40 42 44 IR: 2, 6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (5):

Total Water Rod Flow (%):

Source Convergence 4.96 0.99811 0.421 23.167 18.733 545.5 51.54 12.7 3.4 0.00039

% AXIAL TILT -13.961

-13.996 AVG BOT 8ft/12ft 1.1387 1.1227 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.54 Top Ten Thermal Limits Summary -

Sorted by Margin Value 1.49) 1.47k 1.477

1. 46 1.45)

1. 456 1.44) 1.44) 1.432 1.43:

Power e FT 9 30 8 30 7 29 7 30 8 36 6 31 8 30 0 30 2 29 1 30 IR 29 31 27 37 39 27 35 33 21 33 JR 42 40 40 34 32 44 32 42 28 30 Value

1. 969 1.979

1. 982 1.982 1.991 1.993 1.996 1.998 1. 999 2.000 MCPR Margin FT 0.808 30 0.303 31

0. 802 30 0.802 29 0.799 27 0.795 30 0.797 28 0.796 30 0.796 30 0.795 30 IR 29 25 31 297 29 37 39 35 39 39 JR 42 44 40 40 44 34 34 22 32 36 Value 5.36 6.44 5.43 6.09 6.11 5.30 6.04 5.97 5.78 5.91 Ma rg in 0.708 0.707 0.702

0. 698

0. 671

0. 663

0. 662

0. 659 APLHGR i Exp.

55.8 41.8 2 55.1 45.5 1 41.8 52.6 41.8 42.7 45.4 43.1 FT 24 27 22 28 28 22 28 28 26 26 IR 27 29 25 21 39 35 33 41 23 37 JR 42 10 12 12 34 36 40 32 14 36 K

5 4

5 8

9 8

8 6

8 Value 6.93

6. 55 5.79

5. 65 6.23 5.59 6.09 5.68 6.45 9.37 LHGR Margin Exp.

FT 0.756 40.9 27 0.747 44.6 28 0.745 54.3 22 0.735 55.1 24 0.710 44.6 26 0.703 52.5 23 0.703 45.6 28 0.701 51.0 23 0.701 40.5 28 0.700 24.9 31 IR 29 21 27 27 29 35 11 41 39 27 JR 10 12 12 42 14 12 22 36 34 10 K

45 5

5 5

6 5

8 8

4 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.30 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 11,500.0 MWd/MTU AREVA NP Inc.

Controlled uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-34 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 12000.0 (1017.10 500.0 ( 42.38 2004.0 (100.00 %)

1024.6

-22.91 59.27 (102.91 %)

Core Average Exposure:

M*d/MTU 29056.8 13 5

7 9

11 13 15 17 19 21 23 25 IR:

1 3

5 7

9 11 0

13 15 0

0 17 19 21 23 25 0--.

2 0

0 6 10 14 18 22 51 47 43 39 35 31 27 23 19 15 11 7

3 N (PF Top JR Bottom Axial Profile P-A) Power Exposure 24 0.178 4.192 23 0.408 9.767 22 0.686 18.235 21 0.806 22.807 20 0.900 26.143 19 0.967 28.381 18 1.023 29.855 17 1.074 31.094 16 1.101 31.324 15 1.144 32.441 14 1.230 32.183 13 1.274 31.879 12 1.294 33.127 11 1.297 34.172 10 1.300 34.902 9

1.304' 35.714 8

1.285 36.600 7

1.245 37.287 6

1.202 38.089 5

1.147 38.441*

4 1.082 37.454 3

1.002 33.992 0.808 26.211 1

0.244 7.698 Edit Zone 16 18 20 21 22 "23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.233 0.241 39 0.199 0.208 21 0.182 0.183 51 0.417 0.579 33 0.645 1.186 25 0.848 1.100 35 0.639 1.196 27 0.992 1.198 31 1.045 1.268 37 1.206 1.268 29 1.136 1.287 31 1.342 1.482 27 1.361 1.503 29 1.261 1.463 27 JR 48 2

32 48 42 42 42 30 32 44 42 40 42 44 26 Control Rod Density:

3 k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow ():

Total Water Rod Flow (%):

Source Convergence 30 34 38 42 46 50 4.96 0.99816 0.410

23. 197 18.7b3 545.3 51.80 Active 12.6 (of to1 3.4 (of teo 0.00036

% AXIAL TILT -10.074

-13.856 AVG BOT 8ft/12ft 1.1224 1.1221 Channel Flow: Mlb/hr tal core flow) tal core flow) 49.81 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.503 1.482 1.480 1.467 1.463 1.461 1.448 1.444 1.433 1.431 FT 30 29 30 30 31 30 30 30 31) 30 IR 29 27 31 37 27 39 35 33 39 33 JR 42 40 40 34 44 32 32 42 36 30 Value 1 952 1 956 1 964 1.967 1.976 1.977 1.979 1.985 1.986 1.990 Margin 0.814 0.813 0.810 0.808 0.805 0.804 0.803 0.801 0.800 0.799 FT 30 31 30 29 28 30 30 30 31 30 IR 29 25 31 27 39 37 39 39 31 33 JR 42 44 40 40 34 34 32 36 44 42 Value 5.44 5.10 5.64 5.44 6.13

5. 95 5.72

5. 92

5. 95 6.33 Margin

0. 688 0.688

0. 676 0.674 0.670 0.666 0.665

0. 664 0.661 0.660 Esp.

53.5 56.3 48.9 51.7 41.4 43.4 46.6 43.6 42.7 37.1 FT 22 24 22 22 28 28 24 27 26 26 IR 25 27 33 35 39 31 33 29 37 37 JR 42 42 28 36 34 42 26 10 36 3 2 K

9 6

15 11 9

8 155 9

15 Value 5.64

5. 68 6.34 6.10 5.66 5.60 6.46

6. 34

5. 59 6.36 Margin 0.722 0.712 0.709 0.703 0.700

0. 698 0.698 0.695 0.695 0.691 LHGR Exp.

FT 53.9 22 52.3 24 43.0 27 45.5 28 51.2 22 51.8 23 40.0 28 41.3 26 51.5 23 40.5 26 IR 25 27 29 21 35 41 39 37 3537 JR 42 42 44 12 36 36 34 36 42 22 K

9 9

55 11 8

9 9

8 9

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.31 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 12,000.0 MWd/MTU AREVA NP Inc.

uontrolled Document ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-35 Cycle:

Exposure: MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 12500.0 (1059.50 500.0

(

42.38 2004.0 (100.00 %)

1024.6

-22.42 60.47 (104.98 %)

Core Average Exposure:

MWd/MTU 29556.8 1

3 5

7 9 11 13 15 17 19 21 23 25 1

3 5

7 9

13 --

15 17 19 21 23 25 IR: 2 0

0 0

0 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.186 4.282 23 0.428 9.994 22 0.718 18.621 21 0.844 23.262 20 0.943 26.651

JR 19 1.013 28.928 18 1.073 30.433 17 1.126 31.701 16 1.154 31.946 15 1.197 33.087 14 1.283 32.803 13 1.323 32.490 12 1.335* 33.746 11 1.327 34.789 10 1.316 35.517 9

1.301 36.327 8

1.261 37.200 7

1.197 37.862 6

1.130 38.638 5

1.054 38.959' 4

0.973 37.938 3

0.888 34.437 2

0.715 26.570 Bottom 1

0.216 7.806 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.232 0.240 39 0.198 0.207 21 0.181 0.182 51 0.410 0.578 33 0.643 1.189 25 0.847 1.101 35 0.637 1.198 27 0.983 1.188 31 1.043 1.266 29 1.205 1.271 29 1.132 1.288 31 1.342 1.488 27 1.363 1.509 29 1.268 1.472 27 JR 48 2

32 48 42 42 42 30 40 44 42 40 42 44 6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence 4.96

0. 99843 0.396 23.789

19. 354 545.2

52. 91 12.5 3.3 0.00043

% AXIAL TILT

-5.932

-13.651 AVG BOT 8ft/12ft 1.1042 1.1213 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 50.90 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT IR 1.509 30 29 1.488 29 27 1.483 30 31 1.472 31 27 1.467 30 37 1.463 30 39 1.449 30 33 1.448 30 35 1.436 30 39 1.433 30 35 JR 42 40 40 44 34 32 42 32 36 40 Value 1.939 1.942 1.961 1.962 1.968 1.970 1.975 1.977 1.979 1.979 MCPR Margin FT 0.820 31 0.819 30 0.811 30 0.811 29 0.808 28 0.807 30 0.805 31 0.804 30 0.803 30 0.803 27 IR 27 29 31 27 39 37 31 39 39 29 JR 44 42 40 40 34 20 44 32 36 44 Value 5.77 5.78

5. 59 5.64 6.57 5.86 6. 52 6.39

6. 34 6.45 APLHGR Margin Exp.

FT 0.701 50.1 22 0.698 49.6 22 0.695 52.0 22 0.691 50.9 24 0.691 37.9 26 0.688 47.4 24 0.686 37.8 28 0.684 39.6 26 0.683 40.2 26 0.677 37.7 28 IR 35 33 25 27 37 33 39 37 29 33

-JR 36 28 42 42 32 26 34 36 40 40 K

15 15 11 11 15 15 15 15 15 15 Value 5.83 6.01 5.90 5.99 5.69 6.61 6.50 6.90 5.66

6. 12 Margin 0.729 0.718 0.717 0.706 0.704 0.703 0.701 0.700 0.693 0.697 LHGR Exp.

FT 52.0 22 48.5 22 49.9 24 47.4 22 51.2 23 38.6 28 39.8 26 35.5 26 50.9 23 44.6 24 I R 25 35 27 33 41 39 37 37 35 19 JR 42 36 42 28 36 34 36 22 42 29 K

11 15 11 15 9

11 11 15 9

15

+ LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction

& CPR limit type 0

Thermal limit file:

Figure A.32 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 12,500.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-36 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibi Flow: Mlb/hr 1

3 5

7 9 11 28 13000.0 (1101.90 500.0 (

42.38 2004.0 (100.00

%)

1024.6 m

-22.73 59.71 (103.66 %)

13 15 17 19 21 23 25 C

Core Average Exposure:

MWd/MTU 30056.8 1

3 7

9 13.

15 17 19 21 23 25 IR: 2 6 10 I

0 0

8 47 43 39 35 31 8

27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.210 4.381 23 0.479 10.240 22 0.795 19.038 21 0.923 23.750 20 1.015 27.191

J3 19 1.080 29.505 18 1.134 71.041 17 1.182 32.337 16 1.202 32.596 15 1.239 33.759 14 1.319 33.445 13 1.351 33.119 12 1.352* 34.378 11 1.331 35.415 10 1.305 36.134 9

1.273 36.934 8

1.213 37.783 7

1.130 38.410 6

1.046 39.151 5

0.955 39.433*

4 0.866 38.372 3

0.782 34.831 2

0.628 26.886 Bottom 1

0.190 7.902 Edit Zone 16 18 20 2122 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.232 0.239 39 0.196 0.206 21 0.183 0.184 51 0.416 0.573 33 0.640 1.180 25 0.843 1.094 35 0.639 1.190 27 0.982 1.182 33 1.042 1.270 37 1.202 1.262 29 1.133 1.277 31 1.347 1.480 27 1.363 1.499 29 1.272 1.466 27 JR 48 2

32 48 42 42 42 3232 44 42 40 42 44 0 --

0 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (9):

Total Water Rod Flow

():

Source Convergence 4.68 0.99854 0.384 23.183 18.750 544.9 52.29 12.4 3.3 0.00045

% AXIAL TILT

-0.591

-13.373 AVG BOT Sft/12ft 1.0738 1.1200 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 50.33 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.499 1.480 1.474 1.472 1.467 1.466 1.452 1.441 1.436 1.436 FT 30 29 30 30 30 31 30 30 30 30 IR 29 27 39 31 37 27 35 33 39 41 JR 42 40 32 40 34 44 32 42 36 34 Value 1 913 1 915 1 915 1.924 1.927 1.927 1.940 1.944 1.946 S.953 Margin 0.831 0.830 0.830 0.827 0.325 0.825 0.320

0. 813 0.817 0.814 FT 30 31 26 23 30 30 30 29 30 27 IR 29 27 37 39 37 39 31 27 35 29 JR 42 44 32 34 20 32 40 14 22 44 Value 5.98

5. 90 6.07 6.73 5.86 6.72

6. 51

6. 55

5. 94

6. 63 Margin 0.726 0.723 0.718 0.715 0.714 0.713 0.709 0.709 0.703 0.702 Exp.

50.0

50. 9 48.0 38.8 50.4 38.7 41.0 40.5 48.1

38. 6 FT 22 22 24 26 22 28 26 26 24 26 IR JR 25 42 35 36 27 42 37 32 33 28 39 34 29 40 37 36 33 26 33 40 K

15 15 15 15 15 15 15 15 15 15 Value 6.21 6.13 6.31 6.98 6.85 7.01 6.06 6.77 6.77 6.19 Margin 0.741 0.740 0.729 0.726 0.725 0.724 0.721 0.718 0.715 0.713 LHGR Exp.

FT 48.4 22 49.3 22 45.8 24 36.5 26 38.0 26 35.8 28 48.3 22 38.3 26 37.9 26 45.5 24 IR 25 35 27 37 37 39 33 29 35 19 JR K

42 15 36 15 42 15 22 15 36 15 34 15 28 15 40 15 38 15 28 15

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.33 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 13,000.0 MWd/MTU AREVA NP Inc.

Uontrolled uocument ANP-3215(NP)

Revision 0 Page A-37 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 13117.0 (1111.80 117.0 (

9.92 2004.0 (100.00 %)

1024.6

-22.77 59.60 (103.48

%)

5 17 19 21 23 25 Core Average Exposure:

MWd/MTU 30173.7 1

3 5

7 9

11 13 1 1

35 7

9 13 --

15 --

17 19 21 23 25 IR:

2 10 --

8 10 8

10 51 47 43 39 35 31 8 --

10 27 23 19 15 11 7

3 N (P Top JR Bottom Axial Profile RA) Power Exposure 24 0.255 4.408 23 0.576 10.306 22 0.940 19.150 21 1.069 23.378 20 1.137 27.330 19 1.162 29.650 18 1.186 31.191 17 1.209 32.492 16 1.209 32.751 15 1.231 33.918 14 1.298 33.596 13 1.321" 33.266 12 1.315 34.525 11 1.289 35.559 10 1.258 36.275 9

1.223 37.071 8

1.160 37.914 7

1.073 38.532 6

0.984 39.263 5

0.886 39.534*

4 0.789 38.463 3

0.702 34.912 2

0.559 26.952 1

0.168 7.921 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.230 0.239 39 0.176 0.186 21 0.168 0.170 51 0.400 0.543 33 0.621 1.185 19 0.827 1.105 35 0.558 0.864 25 1.053 1.292 31 1.099 1.316 31 1.212 1.316 33 1.127 1.302 33 1.416 1.464 37 1.451 1.527 31 1.170 1.335 43 JR 48 2

32 48 34 42 34 34 38 36 40 30 36 32 6 10 14 18 22 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

(%)

Source Convergence 26 30 34 38 42 46 50 5.37 0.99849 0.369 22.973 18.540 544.7 52.28 Active 12.3 (of to:

3.2 (of to1 0.00050

% AXIAL TILT 4.942 -13.287 AVG BOT 8ft/12ft 1.0291 1.1196 Channel Flow: Mlb/hr tal core flow) tal core flow) 50.35 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLLHGR Value 1.527 1.525 1.523 1.520 1.499 1.499 1.491 1.468 1.467 1.464 FT 30 30 30 30 30 30 30 30 30 29 IR 31 33 37 35 31 39 31 35 39 37 JR 36 38 34 32 40 32 32 40 36 30 Value 1.774 1.806 1.812 1.820 1.821 1.823 1.842 1.843 1.844 1.847 Margin 0.896 0.880 0.878 0.873 0.873 0.872 0.863 0.863 0.862 0.861 FT 30 27 27 26 26 30 30 30 30 30 IR 21 19 35 31 37 35 39 19 31 S7 JR 36 36 20 38 32 22 32 38 40 210 Va1 Lie 6.27 6.18 6.80 6.80 6.92 6.90 7.00 7.00 6.86 6.84 Margin 0.771 0.758 0.738 0.737 0.736 0.733 0.732 0.731 0. 730 0.726 Exp.

51.1 50.9 40.7 40.6 39.0 38.8 37.3 37.1 38.9 3:,. q FT 22 22 26 26 26 26 27 27 28 28 IR 35 33 37 35 37 31 35 33 39 33 JR K

36 15 34 15 36 15 38 15 32 15 38 15 34 15 36 15 34 15 40 15 Value

6. 53 6.47 7.10 7.09

7. 17 7.15 7.18 7.16 7.41 7.37 Margin 0.791 0.781 0.753 0.752 0.748 0.744 0.744 0.740 0.738 0.735 LHGR Exp.

FT 49.6 22 49.3 22 38.2 26 38.2 26 36.7 26 36.6 26 36.1 28 35.9 28 45.6 25 45.6 25 IR 35 33 37 35 37 21 39 33 21 19 JR 36 34 36 38 22 38 34 40 20 22 K

15 17 15 15 15 15 15 15 17 17 LHGR calculated with pin-power reconstruction CPP calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.34 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 13,117.0 MWdlMTU AREVA NP Inc.

(ontrollea uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-38 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 29 13500.0 (1144.20 383.0 (

32.46 2004.0 (100.00

%)

1024.6

-23.18 58.65 (101.82

%)

Core Average Exposure:

MWd/MTU 30556.8 3

5 7

9 11 13 15 -

17 19 21 23 25 IR:

1 3

5 7

9 11 12 8-13 15 1 12 12 7 19 21 23 25 2

8 51 47 43 39 35 31 12 27 23 19 15 11 7

3 Axial Profile N(PRA) Power Exposure Top 24 0.269 4.507 23 0.608 10.552 22 0.992 19.557 21 1.130 24.343 20 1.209 27.825

JR 19 1.243 30.158 19 1.249 31.705 17 1.258 33.013 16 1.245 33.269 15 1.257 34.444 14 1.316 34.090 13 1.331ý 33.744 12 1.315 34.999 11 1.280 36.022 10 1.238 36.724 9

1.191 37.507 8

1.117 38.325 7

1.018 38.909 6

0.919 39.606 5

0.815 39.841*

4 0.715 38.734 3

0.631 35.153 2

0.503 27.143 Bottom 1

0.151 7.979 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.231 0.239 39 0.179 0.189 21 0.171 0.172 51 0.402 0.546 33 0.621 1.170 17 0.827 1.101 35 0.565 0.900 41 1.045 1.264 31 1.094 1.307 31 1.209 1.299 33 1.122 1.295 33 1.410 1.461 37 1.445 1.514 31 1.184 1.346 43 JR 48 2

32 48 36 42 28.

34 38 36 40 30 16 32 6 10 14 18 22 26 30 34 38 42 46 50 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence 5.23

0. 99861

0. 361 22.297 17.864 544.4 51.45 12.3 3.2 0.00033

% AXIAL TILT 9.215 -12.950 AVG BOT 8ft/12ft 1.0027 1.1178 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.56 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT IR 1.514 30 31 1.513 30 33 1.511 30 37 1.509 30 35 1.496 30 31 1.496 30 39 1.471 30 31 1.461 30 35 1.461 29 37 1.460 29 29 JR, 36 38 34 32 40 32 32 40 30 38 Value 1.782 1.791 1.793 1.794 1.799 1.806 1.808 1.810 1.815 1.816 MCPR Margin FT 0.892 30 0.887 26 0.887 2' 0.887 27 0.884 27 0.881 30 0.879 30 0.878 30 0.876 30 0.975 30 IR 21 31 37 19 35 39 31 35 37 19 JR 36 3.2.

36 32 40 22 Value 6.45 6.39 7.17 0.97 6.8.7 7.15 7.20 7.21

6. 96

6. 94 Margin 0.794 0.777 0.754 0.751 0.750 0.750 0.748 0.747 0.746 0.742 APLHGR i Exp.

50.1 7 50.2 4 37.8 41.4 41.3 37.6 36.6 7 36.4 6 39.6 39.5 FT 22 22 26 26 26 26 27 27 28 28 IR JR 35 36 33 34 37 32 37 36 35 38 31 38 35 34 33 36 39 34 33 40 K

17 17 17 15 15 17 17 17 15 15 Value 6.71 6.57 7.46 7.17 7.16 7.43 7.27 7.25 7.52 7.49 LHGR Margin Exp.

FT 0.802 49.5 22 0.800 50.1-22 0.767 35.4 26 0.767 39.0 26 0.765 38.9 26 0.763 35.3 20 0.760 36.9 29 0.756 36.7 28 0.755 46.3 25 0.753 46.4 25 IR 35 33 37 37 35 21 39 33 21 19 JR 36 34 36 38 38 34 40 20 22 K

17 17 17 15 15 17 15 15 17 17 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction

& CPR limit type 0 Thermal limit file:

Figure A.35 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 13,500.0 MWd/MTU AREVA NP Inc.

uontroiled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-39 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 13750.0 (1165.40 250.0 (

21.19 2004.0 (100.00 %)

1024.6

-22.61 60.00 (104.17

%)

Core Average Exposure:

MWd/MTU 30806.8 1

3 5

7 9

1 3

5 7

9 13 --

15 17 19 21 23 25 IR: 2 12 8

11 13 12 8

15 8

17 19 21 23 25 12 51 47 43 39 35 31 27 23 19 15 11 7

N (PRA)

Top 24 23 22 21 20 JR 19 18 17 16 15 14 13 12 11 10 98 7

6 5

4 3

2 Bottom 1

Axial Profile Power Exposure 0.277 4.575 0.626 10.719 1.020 19.334 1.162 24.659 1.241 28.163 1.273 30.504 1.275 32.053 1.281 33.363 1.263 33.615 1.271 34.792 1.328 34.416 1.340" 34.058 1.321 35.309 1.280 36.323 1.232 37.015 1.179 37.786 1.096 38.585 0.991 39.146 0.885 39.819 0.776 40.029-0.676 38.998 0.594 35.297 0.473 27.258 0.142 8.013 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.230 0.238 39 0.179 0.189 21 0.171 0.172 51 0.402 0.546 33 0.620 1.165 17 0.826 1.101 35 0.565 0.904 41 1.042 1.257 31 1.093 1.303 31 1.209 1.293 33 1.120 1.293 33 1.407 1.459 37 1.445 1.511 31 1.190 1.351 43 JR 48 2

32 48 36 42 28 34 38 36 40 30 36 32 6 10 14 18 22 8

12 2 6 30 34 38 42 46 50 5.23 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%):

Source Convergence

0. 99869 0.353 23.026

18. 592 544.4

52. 68 12.2 3.2 0.00034

% AXIAL TILT 11.300 -12.708 AVG BOT Sft/12ft 0.9904 1.1165 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 50.76 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT IR 1.511 30 31 1.510 30 33 1.508 30 37 1.506 30 35 1.496 30 39 1.496 30 31 1.463 30 31 1.460 30 35 1.459 29 37 1.459 30 39 JR 36 38 34 32 32 40 32 40 30 36 Value 1.800 1.800 1.802 1.805 1.811 1.814 1.818 1.820 1.824 1.825 MCPR Margin FT 0.883 26 0.883 26 0.882 30 0.881 27 0.878 27 0.876 30 0.875 30 0.874 30 0.872 30 0.871 30 IR 37 31 21 19 35 39 31 35 37 19 JR 32 38 36 36 2032 40 22 20 38 Value 6.53 6.45 7.26 7.24 7.06 7.28 7.05 7.28 7.02 6.99 Margin 0.797 0.788 0.767 0.763 0.761 0.759 0.759 0.758 0.756 0.752 APLHGR n Exp.

F 50.5 2 8 50.6 2 38.3 2 38.1 2

- 40.1 2 37.1 2 40.0 2 36.9 2 40.1 2 3j.9 2 TT 6

6 6

7 6

7 8

8 IR JR 35 36 33 34 37 32 31 38 37 36 35 34 35 38 33 36 39 34 33 40 K

17 17 17 17 17 17 17 17 15 15 Value 6.78 6.61 7.56 7.53 7.38 7.37 7.52 7.49 7.59

7. 56 Margin 0.815 0.811 0.782 0.778 0.777 0.775 0.771 0.767 0.766 0.764 LHGR Exp.

FT 49.0 22 50.5 22 35.9 26 35.8 26 37.6 26 37.5 26 35.1 28 34.9 28 46.8 25 46.9 25 IR 35 33 37 21 37 35 39 33 21 19 JR K

36 17 34 17 22 17 38 17 36 17 38 17 34 17 40 17 20 17 22 17 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.36 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 13,750.0 MWd/MTU AREVA NP Inc.

Gontrolled Uocumenlt ANP-3215(NP)

Revision 0 Page A-40 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Nilb/hr 28 14000.0 (1186.60 250.0 (

21.19 2004.0 (100.00 0) 1024.6

-22.92 59.25 (102.86 %)

Core Average Exposure:

MWd/MTU 31056.8 1

3 5

1 3

5 7

9 13 --

15 --

17 19 2123 25 TR.

7 9 11 13 12 10 15 10 17 19 21 23 25 00 --

19 --

6 10 14 18 22 51 47 43 39 35 31 12 27

-~23 19 15 11 7

3 38 42 46 50 N(P]

Top JR Bottom Axial Profile RA) Power Exposure 24 0.292 4.646 23 0.659 10.893 22 1.074 20.123 21 1.227 24.988 20 1.317 28.516 19 1.330 30.863 18 1.316 32.410 17 1.308 33.720 16 1.278 33.966 15 1.277 35.144 14 1.327 34.744 13 1.332" 34.372 12 1.307 35.618 11 1.260 36.621 10 1.208 37.302 9

1.148 38.061 9

1.060 38.839 7

0.950 39.374 6

0.841 40.022 5

0.731 40.206' 4

0.632 39.052 3

0.553 35.432

? 0.441 27.366 1

0.133 8.046 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Rad.

Avg.

0.229 0.178 0.170 0.400 0.620 0.823 0.569 1.041 1.091 1.203 1.126 1.413 1.443 1.188 Lal Power Max.

IR 0.237 39 0.188 21 0.171 51 0.543 33 1.161 19 1.094 35 0.910 41 1.258 31 1.300 31 1.287 33 1.286 33 1.463 37 1.511 31 1.348 43 JR 48 2

32 48 34 42 28 34 38 36 40 30 36 32 10 12 30 34 26 30 34 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (1):

Total Water Rod Flow

(%9:

Source Convergence 5.10 0.99888 0.347 22.505 18.072 544.2

% AXIAL TILT 14.466 -12.449 AVG SOT 8ft/12ft 0.9674 1.1151 52.04 Active Channel Flow: Mlb/hr 50.15 12.2 3.2 0.00050 (of total core flow)

(of total core flow)

Top Ten Thermal Limits Summary -

Sorted by Margin Power Value 1.511 1.506 1.502 1.500 1.492 1.491 1.467 1.463 1. 462 1.451 FT 30 30 30 30 30 30 30 29 29 30 IR 31 35 33 37 39 31 21 37 29 35 JR 36 32 38 34 32 40 32 30 38 4U Value 1.769 1.770 1.773 1.779 1.784 1.784 1.787 1.790 1.795 1.796 MCPR Margin FT 0.899 26 0.893 26 0.897 30 0.894 27 0.891 30 0.891 27 0.890 30 0.888 30 0.886 30 0.895 30 APLHGR IR 37 31 21 19 35 35 39 31 37 19 JR 32 38 36 36 22 20 32 40 0O 38 Value

6. 62 6.57 7.01

6. 98 7.40 7.02 7.37 7.18

7. (l 7.14 Margin 0.812 0.807 0.798 0.795 0.785 0.781 0.780 0.780 0.780 0.777 Exp.

51.0 51.0 44.1 44.1 38.7 41.8 38.6 40.9 41.8 40.9 FT 22 22 22 22 26 22 26 24 2224 IR JR 35 36 33 34 33 28 27 34 37 32 25 42 31 38 19 28 11 28 25 34 K

17 17 20 20 17 20 17 20 20 20 Value 6.37 6.71 7.71 7.46 7.24 7.71 7.67 7.42 7.21 7.48 LHGR Margin Exp.

FT 0.831 49.4 22 0.828 51.0 22 0.802 36.4 26 0.799 39.1 22 0.799 41.8 22 0.799 36.1 24 0.797 36.3 26 0.796 39.3 22 0.796 41.8 22 0.792 38.1 26 IR 35 33 37 11 33 41 21 25 27 37 JR 36 34 22 28 28 26 38 42 34 36 K

17 17 17 20 20 20 17 20 20 17 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.37 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 14,000.0 MWd/MTU AREVA NP Inc.

uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-41 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 14220.0 (1205.30 220.0

(

18.65 2004.0 (100.00 6) 1024.6

-22.98 59.12 (102.64 %)

Core Average Exposure:

MWd/MTU 31276.8 1

3 5

7 9

13 -

15 -

17 19 21 23 25 IR:

1 3

5 7

9 11 0 --

13 0

0 15 17 1 9 21 23 25 0

51 47 43 39 35 31

- 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.224 4.702 23 0.513 11.033 22 0.848 20.355 21 0.989 25.257 20 1.099 28.809

JR 19 1.171 31.167 18 1.226 32.719 17 1.268 34.032 16 1.278 34.276 15 1.304 35.457 14 1.375 35.037 13 1.395* 34.655 12 1.376 35.895 11 1.333 36.890 10 1.280 37.559 9

1.220 38.306 8

1.136 39.067 7

1.034 39.580 6

0.938 40.206 5

0.842 40.369*

4 0.754 39.196 3

0.680 35.560 2

0.550 27.469 Bottom 1

0.167 8.077 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.230 0.235 39 0.194 0.203 21 0.185 0.186 51 0.414 0.567 33 0.630 1.186 25 0.787 1.089 35 0.602 1.217 41 0.993 1.157 31 1.072 1.269 39 1.218 1.259 43 1.066 1.277 41 1.341 1.504 39 1.416 1.509 41 1.295 1.483 43 JR 48 2

32_

48 42 42 28 34 30 30 32 29 30 28 2

6 10 14 18 22 0------------------

26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

(%):

Total Water Rod Flow (%):

Source Convergence 4.13 0.99878

0. 369

22. 698 18.269 544. 6 51.86 12.3 3.3 0.00031

% AXIAL TILT 5.755 -12.244 AVG BOT 8ft/12ft 1.0413 1.1141 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.94 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT IR 1.509 30 41 1.505 30 29 1.504 29 39 1.500 30 39 1.499 30 31 1.491 29 27 1.483 31 43 1.480 31 27 1.461 30 33 1.460 30 37 JR 30 42 28 32 40 40 28 44 38 34 Value 1.831 1.839 1.842 1.851 1.852 1.859 1.867 1.875 1.877 1.880 MCPR Margin FT 0.868 30 0.865 30 0.863 30 0.359 31 0.859 30 0.855 29 0.852 31 0.848 29 0.847 30 0.846 30 43 21 13 43 21 13 25 27 37 19 JR 30 12 2'

28 14 28 44 14 20

?C)

Value 6.43 6.56 6.34 6.43 6.91 6.13

6. 95 6.82

6. 98 6.94 Margin 0.792 0.79]

0.782 0.774 0.77]

0.770 0.760 0.75]

0.75]

0.756 APLHGR n Ex p.

2 51.3 0 49.5 51.4 49.4 1 43.1 52.9 41.4 9 43.1 9 40.9 41.0 FT 22 24 24 26 2 2 28 26 28 26 IR JR 11 28 41 26 25 42 27 42 39 30 35 36 41 32 29 40 39 34 37 32 K

15 15 15 15 15 15 15 15 15 15 Value 6.72 6.81 6.57 6.34

6. 67

7. 18 7.26 7.08 7.23 7.54 Margin 0.812 0.906 0.799 0.788 0.785 0.785 0.775 0.774 0.773 0.771 LHGR Exp.

FT 49.4 22 47.7 24 49.9 22 51.6 22 47.3 24 41.0 26 38.9 26 41.0 26 39.0 28 47.8 28 IR 11 41 25 35 27 13 37 29 11 13 JR 28 26 42 336 42 302 2 14 22 20 K

15 15 15 15 15 15 15 15 15 15 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.38 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 14,220.0 MWd/MTU AREVA NP Inc.

tJontrolled Uocument ANP-3215(NP)

Revision 0 Design (EPU/MELLLA)

Page A-42 Monticello Fuel Transition Cycle 28 Fuel Cycle Cycle:

Exposure:

MWd/MTU (GWd)

Della E:

MWd/MTU, (GWd)

Power: MWI Core Pressure: psia Inlet Subcooling: Btu/Ibm Flow: Mlb/hr 28 14500.0 (1229.00 280.0 (

23.73 2004.0 (100.00 %)

1024.6

-23.29 58.41 (i01.41 0)

Core Average Exposure:

MWd/MTU 31556.8 1

3 5

7 9 11 13 15 17 19 21 23 25 1

35 7

9 13 -

15 17 19 21 23 25 IR: 2 0

0 0

6 10 14 18 22 26 0

30 34 38 42 46 50 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA) Power Exposure Top 24 0.237 4.766 23 0.541 11.193 22 0.891 20.624 21 1.036 25.570 20 1.147 29.156

JR 19 1.215 31.535 18 1.263 33.103 17 1.297 34.428 16 1.299 34.674 15 1.317 35.862 14 1.383 35.418 13 1.398* 35.023 12 1.373 36.258 11 1.324 37.240 10 1.264 37.895 9

1.198 38.625 8

1.107 39.363 7

0.999 39.848 6

0.897 40.449 5

0.798 40.586*

4 0.709 39.389 3

0.636 35.734 2

0.515 27.609 Bottom 1 0.157 8.119 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.227 0.232 39 0.191 0.201 21 0.182 0.183 51 0.409 0.559 33 0.626 1.171 25 0.821 1.075 35 0.598 1.201 41 1.001 1.166 31 1.063 1.254 39 1.206 1.243 29 1.079 1.260 41 1.364 1.489 39 1.410 1.489 41 1.281 1.464 43 JR 48 2

32 48 42 42 28 34 30 44 32 28 30 28 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

(%):

Total Water Rod Flow (%):

Source Convergence 3.31 0.99881 0.364 22.204 17.778 544. 5 51.22 12.3 3.2 0.00030

% AXIAL TILT 8.532 -12.014 AVG BOT 8ft/12ft 1.0233 1.1130 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 49.33 Top Ten Thermal Limits Summary -

Sorted by Margin Valu1 1 489 1.489

1. 486 1. 4 :

1. 481 1.475 1.464 1.462 1.447 1.44 Power e FT 9 30 9 29 6 3O 3 30 1 30 5 29 31 2 31 7 30 6 30 IR 41 39 29 39 31 27 43 27 33 37 JR 30 28 42 32 40 40 28 44 38 34 Value 1.840 1.947 1.84S 1.853 1.854 1.856 1.870 1.877 1.877 1.879 MCPR Margin FT 0.864 30 0.861 30 0.861 30 0.858 29 0.858 30 0.857 31 0.850 31 0.847 28 0.847 29 0.846 28 IR 11 29 39 13 31 43 27 39 27 33 JR 3o 12 32 28, 40 26 44 3414 40 Value 6.42 6.53 6.33 6.42 6.89 6.11 6.80 6.93 6.95 6.93 Margin 0.796 0.792 0.786 0.777 0.773 0.772 0.762 0.761 0.760 0.759 APLHGR Exp.

51.8 50.0 6 51.9 49.9 43.6 53.3 43.6 41.9 41.4 41.5 FT 22 24 22 24 26 22 26 28 28 26 IR JR 11 28 41 26 25 42 27 42 39 30 35 36 29 40 41 32 39 34 37 32 K

15 15 15 15 15 15 15 15 15 15 Vailue 6.71 6.78 6.56 6.33

6. 66 7.16 7.24 7.08 7.22 6.21 Margin 0.816 0.808 0.802 0.791 0.789 0.789 0.779 0.779 0.777 0.774 LHGR Exp.

FT 49.9 22 48.2 24 50.4 22 52.1 22 47.8 24 41.6 26 39.5 26 41.6 26 39.6 28 51.9 22 IR 11 41 25 35 27 13 37 29 01 33 JR 28 42 36 42 30 22 14 22 34 K

15 15 15 15 15 15 15 15 15 17

LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.39 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 14,500.0 MWd/MTU AREVA NP Inc.

Uontroile: uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-43 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 14750.0 (1250.20 250.0

(

21.19 2004.0 (100.00 %

1024.6

-22.41 60.48 (105.00 %

Core Average Exposure: MWd/MTU 31806.8 1

3 1

3 5

7 5

7 9

11 --

13 15 17 19 21 23 25 IR: 2 9

11 13 0

0--

6 10 14 1.9 22 0

26 15 17 19 0

30 34 38 3.31 0.99853 0.355 23.351 IS.924 544.5 21 23 25 51 47 43 39 35 31 27 23 19 15 11 7

3 42 46 50 N (P Top JR Bottom Axial Profile RA) Power Exposure 24 0.246 4.826 23 0.562 11.342 22 0.925 20.873 21 1.073 25.861 20 1.182 29.477 19 1.246 31.875 18 1.289 33.455 17 1.318 34.789 16 1.313 35.034 15 1.327 36.226 14 1.390 35.760 13 1.403-35.352 12 1.374 36.531 1i 1.321 37.551 10 1.256 38.191 9

1.184 38.906 8

1.087 39.621 7

0.973 40.081 6

0.866 40.656 5

0.762 40.769*

4 0.671 39.552 3

0.599 35.879 2

0.486 27.727 1

0.148 8.155 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.227 0.232 39 0.191 0.201 21 0.182 0.183 51 0.409 0.559 33 0.625 1.173 25 0.821 1.077 35 0.598 1.202 41 0.998 1.160 31 1.062 1.254 39 1.206 1.247 29 1.077 1.262 31 1.361 1.490 39 1.409 1.491 41 1.287 1.469 43 JR 48 2

32 48 42 42 28 34 30 44 42 28 30 28 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

(%)

Source Convergence

% AXIAL TILT 10.608 -11.793 AVG BOT Sft/12ft 1.0100 1.1120 53.09 Active Channel Flow: Mlb/hr 51.15 12.2 0.00048 (of total core flow)

(of total core flow)

Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.491 1.490 1.488 1.482 1.481 1.476 1.469 1.468 1.445 1.443 FT 30 29 30 30 30 29 31 31 30 30 IR 41 39 29 39 31 27 43 27 19 37 JR 30 28 42 32 40 40 28 44 38 20 Value 1.858 1.862 1.864 1.865 1.866 1.869 1.880 1.859 1.889 1.890 Margin 0.856 0.854 0.853 0.853 0.852 0.851 0.646 0.642 0.842 0.841 FT 30 30 30 29 31 30 31 30 28 22 IR 11 39 29 13 43 31 27 37 39 13 JR 30 32 12 28 26 40 44 20 34 40 Value 6.47 6.58 6.38 6.47 6.29 6.92 6.97 6.84 6.98 7.10 Margin 0.807 0.802 0.797 0.787 0.783 0.780 0.771 0.770 0.757 0.765 Exp.

52.2 50.4

52. 3 50. 3 52.2 44.1

42. 3 44.0 41.9 40.1 FT 22 24 22 24 22 26 28 26 28 26 41 25 27 35 39 41 29 39 37 JR K

28 15 26 15 42 15 42 15 36 17 30 15 32 15 40 15 34 15 32 17 Value 6.76 6.83

6. 61 6.71 6.50 7.20 7.12 7.25 7.44 6.24 Margin 0.982 0.818 0.814 0.800 0.799 0.797 0.788 0.788 0.787 0.782 LHGR Exp.

FT 50.4 22 48.7 24 50.8 22 48.3 24 50.8 22 42.1 26 42.1 26 40.1 28 38.0 26 52.3 22 I R 11 41 25 27 35 13 29 11 37 33 JR 28 26 42 42 36 30 14 22 22 34 K

15 15 15 15 17 15 15 15 17 17 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.40 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 14,750.0 MWd/MTU AREVA NP Inc.

uontrolled uocument ANP-3215(NP)

Revision 0 Design (EPU/MELLLA)

Page A-44 Monticello Fuel Transition Cycle 28 Fuel Cycle Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr 28 15000.0 (1271.40 250.0 (

21.19 2004.0 (100.00 %)

1024.6

-22.62 59.97 (104.11 %)

Core Average Exposure: MWd/MTU 32056.8 1

3 5

7 9

13 13 1

3 5

7 9 11 8 --

13 8

15 17 19 21 23 25 51 47 43 39 35 31 8-

-27 23 19 15 11 7

3 N (PRA)

Top 24 23 22 21 20 JR 19 18 17 16 15 14 13 12 11 10 9

8 7

6 5

4 Bottom 1

Axial Profile Power Exposure 0.286 4.892 0.645 11.506 1.044 21.144 1.188 26.172 1.270 29.815 1.308 32.227 1.327 33.816 1.336 35.155 1.313 35.396 1.314 36.591 1.367 36.100 1.373' 35.679 1.339 36.900 1.280 37.857 1.212 38.481 1.137 39.179 1.038 39.871 0.923 40.304 0.816 40.854 0.713 40.943' 0.625 39.704 0.557 36.016 0.452 27.838 0.138 8.189 Edit Zone 16 18 20 21 2223 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.224 0.229 39 0.189 0.199 21 0.180 0.180 51 0.404 0.552 33 0.625 1.168 11 0.817 1.066 35 0.604 1.196 41 1.002 1.171 21 1.061 1.251 39 1.198 1.236 29 1.092 1.251 31 1.374 1.491 39 1.407 1.480 41 1.276 1.457 27 JR 48 2

32 48 28 42 28 34 30 44 42 28 30 44 15 17 19 21 23 25 IR: 2 6

10 14 8

4 18 22 26 30 34 38 42 46 50 Control Rod Density:

8 k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Ml/hr Total Bypass Flow (l):

Total Water Rod Flow

(%)

Source Convergence 2.75 0.99879 0.347 22.795

18. 370 544.3 52.70 12.1 3.2 0.00041

% AXIAL TILT 14.746 -11.550 AVG BOT Sft/12ft 0.9749 1.1107 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 50.80 Top Ten Thermal Limits Summary -

Sorted by Margin Power MC PR APLHGR Value 1.491 1.480 1.478 1.476 1.474 1.473 1.457 1.456 1.437 1.435 FT 29 30 30 29 30 30 31 31 30 30 IR 39 41 29 27 39 21 27 43 19 15 JR 28 30 42 40 32 40 44 28 38 34 Value 1.831 1.832 1.832 1.838 1.839 1.840 1.845 1.851 1.854 1.956 Margin 0.869 0.868 0.868 0.865 0.865 0.864 0.862 0.859 0.858 0.856 FT 29 30 30 30 29 30 31 26 26 30 IR 39 13 11 21 27 29 43 37 21 37 JR 28 22 30 14 14 12 26

,2 38 20 Value

6. 60 6.75 6.50 6.35 7.12 6.62 7.01 7.18 6.20 7.17 Margin 0.807 0.803 0.797 0.795 0.791 0.787 0.779 0. 778 0.777 0.774 Exp.

50.6 48.5

50. 9

52. 6 42.8 48.5 42.9 40.6

52. 6 40.3 FT 22 24 22 22 26 24 26 26 2228 ZR 41 25 35 39 27 29 37 33 39 JR 28 26 42 36 30 42 40 32 34 34 K

17 17 17 17 17 17 17 17 17 17 Value 6.92 7.03 6.77 6.56 7.42 6.89

7. 53 7.31 6.30 7.48 LHGR Margin Exp.

FT 0.830 48.7 22 0.822 46.7 24 0.816 49.3 22 0.811 51.3 22 0.809 40.7 26 0.802 46.4 24 0.801 38.5 26 0.798 40.9 26 0.795 52.8 22 0.795 38.4 26 IR 11 41 25 35 13 27 37 29 33 21 JR 28 26 42 36 30 42 22 14 34 38 K

17 17 17 17 17 17 17 17 17 17 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.41 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 15,000.0 MWdlMTU AREVA NP Inc.

(Jontrolled uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-45 Cycle:

Exposure:

MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr Core Average Exposure:

MWd/MTU 32306.8 15250.0 (1292.60 250.0 (

21.19 2004.0 (100.00

%)

1024.6

-22.57 60.10 (104.33 %)

1 3

5 7

9 11 13 11 17 1

3 5

7 9 11 13 15 17 19 21 23

-1i0 6 10 14 18 22 10 10 10 25 51 47 43 39 35 31 27 23 19 15 11 7

N (P Top

JR Bottom Axial Profile RA) Power Exposure 24 0.301 4.965 23 0.681 11.685 22 1.102 21.440 21 1.257 26.510 20 1.346 30.176 19 1.363 32.595 18 1.364' 34.187 17 1.357 35.526 16 1.322 35.760 15 1.314 36.953 14 1.360 36.436 13 1.361 36.000 12 1.323 37.213 11 1.261 38.156 10 1.190 38.764 9

1.110 39.444 8

1.006 40.112 7

0.887 40.517 6

0.776 41.042 5

0.671 41.106*

4 0.583 39.847 3

0.517 36.142 2

0.419 27.940 1

0.128 8.220 Edit Zone 16 18 20 21 22 23 24 25 26 27 25 29 30 31 Radial Power Avg.

Max.

IR 0.223 0.228 39 0.188 0.198 21 0.179 0.179 51 0.402 0.549 33 0.625 1.166 11 0.814 1.060 35 0.607 1.194 41 1.002 1.174 21 1.060 1.249 39 1.194 1.232 29 1.099 1.247 31 1.379 1.492 39 1.406 1.476 11 1.273 1.454 27 JR 48 2

32 48 28 42 28 34 30 44 42 28 24 44 19 21 23 25 IR:

2 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow (%)

Source Convergence 26 30 34 38 42 46 50 2.62 0.99878 0.338 22.922 18.497 544.2 52.82 Active 12.1 (of toi 3.2 (of toi 0.00050 I

% AXIAL TILT 17.743 -11.284 AVG BOT 8ft/12ft 0.9518 1.1093 Channel Flow: Mlb/hr tal core flow) tal core flow) 50.92 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.492 1.477 1.476 1.474 1.470 1.469 1.454 1.451 1.437 1.435 FT 29 29 30 30 30 30 31 31 30 29 IR 39 27 11 13 21 27 43 21 37 JR 28 40 24 42 22 14 44 28 36 24 Value Margin 1.795 0.886 1.805 0.881 1.811 0.878 1.813 0.977 1.817 0.875 1.818 0.875 1.827 0.870 1.829 0.869 1.833 0.868 1.836 0.866 FT 29 29 30 30 30 30 26 26 31 29 IR 13 27 11 13 29 21 37 21 43 37 JR 281 14 30 12 14 22 38 26 3O Value 6.70 6.84

6. 60 7.01 6.98 6.41 7.22 6.72

6. 59 7.11 Margin 0.824 0.819 0.814 0.911 0.808 0.807 0.806 0.801 0.800 0.795 Exp.

51.1 49.0 51.3 45.6 45.6 53.0 43.3 48.9 50.0 43.4 FT 22 24 22 22 22 22 26 24 22 26 SR 41 25 33 27 35 39 27 33 29 j.R 28 26 42 28 34 36 30 42 34 40 K

17 17 17 20 20 17 17 17 19 17 Value 7.03 7.12 6.86 7.53 6.62 6.99 7.63 7.24 7.42

6. 63 Margin 0.847 0.838 0.833 0.126 0.824 0.818 0.817 0.815 0.815 0.814 LHGR Exp.

FT 49.2 22 47.2 24 49.7 22 41.2 26 51.7 22 46.9 24 39.1 26 43.5 22 41.4 26 50.6 22 IR 11 41 25 13 35 27 37 33 29 33 JR K

28 17 26 17 42 17 30 17 36 17 42 17 22 17 28 20 14 17 34 19

LHGR calculated with pin-power reconstruction "CPR calculated with pin-power reconstruction & CPR limit type 0

" Thermal limit file:

Figure A.42 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 15,250.0 MWd/MTU AREVA NP Inc.

uontroiieo Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-46 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr Core Average Exposure:

MWd/MTU 32556.7 15500.0 (1313.80 250.0 (

21.19 2004.0 (100.00

%)

1024.6

-22.77 59.61 (103.49

%)

3 5

7 9

13 15 17 19 21 23 25 IR: 2 3

5 7

9 11 13 15 17 19 6

10 14 18 22 26 8 38 30 34 33 21 23 25 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.293 5.039 23 0.662 11.867 22 1.069 21.739 21 1.220 26.851 20 1.309 30.542

JP 19 1.345 32.968 18 1.358 34.562 17 1.359 35.901 16 1.329 36.125 15 1.322 37.316 14 1.371 36.773 13 1.373* 36.322 12 1.334 37.526 11 1.270 38.454 10 1.196 39.045 9

1.115 39.706 8

1.011 40.350 7

0.894 40.727 v 0.785 41.226 5

0.683 41.266*

4 0.598 39.986 0.534 36.266 0.435 28.041 Bottom 1

0.134 8.251 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.218 0.224 39 0.186 0.196 21 0.172 0.173 51 0.395 0.544 33 0.626 1.180 25 0.806 1.051 17 0.615 1.191 27 1.006 1.210 21 1.057 1.276 23 1.180 1.233 29 1.123 1.292 27 1.399 1.528 27 1.405 1.487 29 1.256 1.459 27 JR 48 2

32 48 42 12 42 34 36 44 38 40 12 44 42 46 50 Control Rod Density: %

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

(%):

Source Convergence

1. 31 0.99883 0.341 22.680 18.260 544.2 52.37 12.1 0.00032

% AXIAL TILT 16.756 -11.013 AVG BOT Sft/12ft 0.9615 1.1079 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 50.48 Top Ten Thermal Limits Summary -

Sorted by Margin Power Value 1.528 1.504 1.487 1.486 1.485 1.466 1.459 1.447 1.438 1.436 FT 29 29 30 30 30 30 31 29 30 30 IR 27 23 29 21 21 23 27 39 19 11 JR 40 16 12 14 18 20 44 28 16 24 Value 1.735 1.759 1.785 1.785 1.792 1.795 1.802 1.811 1.817 1.818 MCPR Margin FT 0.917 29 0.904 29 0.891 28 0.891 30 0.887 30 0.886 30 0.382 26 0.878 26 0.875 30 0.875 26 APLHGR IR 27 29 27 21 29 21 21 29 29 29I JR 14 38 33 36 12 14 38 36 20 40 Value 6.69 6.80 7.26

6. 52

7. 36 7.39 6.51 6.32 6.63 6.63 Margin 0.829 0.818 0.816 0.809 0.805 0.804 0.804 0.800 0.795 0.797 Exp.

51.7 49.4 43.8 51.8 41.4 40.9 51.5 53.4 49.4 49.4 FT 22 24 26 22 26 28 222 2 24 14 IR JR 25 42 27 42 29 40 27 34 31 38 25 38 11 28 35 36 41 26 25 20 K

17 17 17 17 17 17 17 17 17 17 Value 6.94 7.58 7.07 7.73 6.75 6.82 7.75

6. 94 6.54

6. 90 LHGR Margin Exp.

FT 0.848 50.2 22 0.837 41.9 26 0.133 47.4 24 0.829 39.3 26 0.827 50.5 22 0.826 49.7 22 0.820 37.9 28 0.317 47.4 24 0.817 52.0 22 0.816 47.7 24 IR 25 29 27 21 27 11 27 27 35 41 JR 42 14 42 38 34 28 38 20 36 26 K

17 17 17 17 17 17 17 17 17 17

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.43 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 15,500.0 MWdIMTU AREVA NP Inc.

Uontroliea uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-47 Cycle:

Exposure: MWd/MTU (GWd)

Delta E:

MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 15775.0 (1337.10 275.0

(

23.31 2004.0 (100.00 %)

1024.6

-23.60 57.69 (100.16 9)

Core Average Exposure:

MWd/MTU 32831.8 1

3 5

7 9

11 13 15 17 19 21 2 3 1

3 5

7 9 11 13 15 30 17 19 21 23 25 51 47 43 39 35 31 27 23 19 15 11 7

34 38 42 46 50 Axial Profile N(PRA)

Power Exposure Top 24 0.294 5.119 23 0.662 12.065 22 1.067 22.062 21 1.221 27.221 20 1.320 30.941

JR 19 1.358 33.379 18 1.370- 34.976 17 1.367 36.314 16 1.334 36.529 15 1.323 37.718 14 1.369 37.145 13 1.369 36.677 12 1.327 37.870 11 1.260 38.781 10 1.185 39.353 9

1.103 39.993 8

1.001 40.610 7

0.986 40.958 6

0.781 41.429 5

0.683 41.443' 4

0.601 40.141 3

0.540 36.405 2

0.443 28.154 Bottom 1

0.137 a.28f Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.213 0.217 39 0.179 0.190 21 0.170 0.170 1

0.386 0.527 33 0.625 1.146 11 0.795 1.023 17 0.629 1.171 41 1.012 1.209 21 1.055 1.252 23 1.164 1.200 19 1.153 1.274 15 1.424 1.502 39 1.402 1.463 21 1.233 1.414 27 JR 48 2

32 48 28 12 28 20 18 36 26 28 18 10 25 IR:

2 6 10 14 18 22 26 Control Rod Density: ;

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow

():

Total Water Rod Flow (%)

Source Convergence 0. 00

0. 99892 0.344 21.589 17.173 544.0 50.65 12.2 3.2 0.00039

% AXIAL TILT 17.111 -10.724 AVG BOT Sft/12ft 0.9589 1.1063 Active Channel Flow: Mlb/hr (of total core flow)

(of total core flow) 45.81 Top Ten Thermal Limits Summary -

Sorted by Margin Valuu 1. 502 1.48:

1.47 1.466 1.46:

1.459

1. 457 1.454

1. 447 1.445 Power e FT 2 29 3 29 3 29 6 29 3 30 9 30 30 30 30 30 IR JR 39 28 27 14 15 24 23 16 21 18 17 22 23 20 19 24 13 22 11 24 Value 1.740 1.761 1.765 1.776 1.781 1.782 1.790 1.798 1.807 1.810 MCPR Margin FT 0.914 29 0.903 29 0.901 29 0.895 28 0.893 30 0.892 29 0.888 30 0.884 30 0.880 30 0.878 30 IR JR 13 28 27 14 37 30 37 28 35 22 29 38 21 36 19 30 29 20 11 30 Value

6. 62 6.74 6.53 7.18 6.51 7.41 6.44 6.31

6. 66

6. 62 Margin 0.823 0.815 0.812 0.812 0.811 0.804 0.804 0.803 0.801 0.801 APLHGR Exp.

52.0 49.9 52.1 244.3 152.2 40.7 52.3 53.9 49.4 1 49.8 FT 22 24 22 26 28 22 22 24

_24 IR 41 33 39 25 37 27 33 19 27 JR 28 26 28 30 42 23 34 34 28 42 K

17 17 17 17 17 17 17 17 17 17 Value 6.84 7.51 7.00 6.75 6.77 7.61 7.39 7.79

6. 95

6. 67 Margin 0.846 0.334 0.833 0.830 0.828 0.823 0.822 0.819 0.819 0.819 LHGR Exp.

FT 51.3 22 42.3 26 48.2 24 50.8 22 50.4 22 40.0 26 42.5 26 37.5 28 47.4 24 50.6 22 IR 11 13 41 25 33 37 29 37 19 27 JR 28 30 26 42 28 22 14 28 28 34 K

17 17 17 17 17 17 17 17 17 17 LHGR calculated with pin-power reconstruction CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.44 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 15,775.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocumenlt ANP-3215(NP)

Revision 0 Page A-48 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure:

MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/lbm Flow: Mlb/hr Core Average Exposure:

MWd/MTU 32956.8 15900.0 (1347.70 125.0 (

10.59 2004.0 (100.00 %)

1024.6

-22.76 59.64 (103.53

)

1 3

5 7

9 11 13 15 17 19 21 23 25 3

5 7

9 13 --

15 --

17 19 21 23 25 IR: 2 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.299 5.156 23 0.675 12.155 22 1.088 22.210 21 1.244 27.391 20 1.340 31.124

JR 19 1.375 33.567 18 1.382* 35.166 17 1.375 36.503 16 1.339 36.713 15 1.326 37.900 14 1.371 37.314 13 1.371 36.838 12 1.327 38.026 11 1.259 31.929 10 1.181 39.492 9

1.096 40.123 8

0.990 40.728 7

0.872 41.061 6

0.764 41.520 5

0.664 41.522*

4 0.582 40.211 3

0.521 36.468 2

0.427 28.206 Bottom 1 0.132 8.301 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.213 0.217 39 0.179 0.189 21 0.170 0.170 1

0.386 0.527 33 0.624 1.147 11 0.795 1.026 17 0.628 1.172 41 1.010 1.206 21 1.055 1.251 23 1.165 1.199 29 1.152 1.271 15 1.421 1.501 13 1.402 1.462 21 1.237 1.420 27 JR 48 2

32 48 28 12 28 20 18 10 26 26 18 10 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (0):

Total Water Pod Flow Source Convergence 0.00

0. 99884 0.337

22. 669 18.252 544.1 52.40 12.1 3.2 0.00032

% AXIAL TILT 18.204 -10.591 AVG BOT 8ft/12ft 0.9514 1.1056 Active Channel Flow:

llb/hr (of total core flow)

(of total core flow) 50.51 Top Ten Thermal Limits Summary -

Sorted by Margin Power MC PR APLHGOR Value 1.501 1.485 1.470 1.466 1.462 1.456 1.453 1.448 1.447 1.447 FT 29 29 29 29 30 30 30 30 30 30 IR 13 27 15 23 21 17 23 19 13 11 JR 26 14 24 16 18 22 20 24 22 24 Value 1.758 1.777 1.785 1.795 1.800 1.802 1.808 1.823 1.825 1.827 Margin 0.905 0.895 0.891 0.886 0.883 0.882 0.879 0.872 0.871 0.670 FT 29 29 29 28 29 30 30 30 30 30 I R 13 27 37 37 29 35 21 19 11 13 JR 28 14 30 28 38 22 36 30 30 22 Value 6.67 6.78 6.57 7.22

6. 66

6. 68 7.44

6. 60

6. 33 7.12 Margin Exp.

0.831 52.2 0.823 50.1 0.820 52.4 0.818 44.5 0.814 50.5 0.810 50.1 0.809 40.9 0.808 50.8 0.807 54.1 0.807 44.6 FT 22 24 22 26 22 24 28 22 22 26 IR 41 25 39 33 27 37 27 33 29 JR 28 26 42 30 28 42 28 34 34 4O K

17 17 17 17 18 17 17 18 17 17 Value 6.88 7.04 7.55 6.81 6.93 7.43

7. 64

6. 93 7.81 6.85 Margin 0.854 0.841 0.841 0.839 0.830 0.829 0.828 0.824 0.824 0.823 LHGR Exp.

FT 51.5 22 48.5 24 42.6 26 51.0 22 48.7 22 42.8 26 40.2 26 48.1 24 37.8 28 49.0 22 IR 11 41 13 25 33 29 37 27 37 27 JR 28 26 30 42 28 14 22 42 28 34 K

17 17 17 17 18 17 17 17 17 18 LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.45 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 15,900.0 MWd/MTU AREVA NP Inc.

Cuontroiied uocument ANP-3215(NP)

Revision 0 Page A-49 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 16000.0 (1356.10 100.0

(

8.48 2004.0 (100.00

%)

1024.6

-22.41 60.48 (105.00 5)

Core Average Exposure: MWd/MTU 33056.8 1

3 5

7 9

13 15 17 19 21 23 25 IR:

1 3

5 7

9 11 13 15 17 19 21 23 25 2

51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA)

Power Exposure Top 24 0.303 5.186 23 0.684 12.229 22 1.099 22.331 21 1.256 27.529 20 1.350 31.273

JR 19 1.382 33.719 18 1.386ý 35.318 17 1.377 36.655 16 1.338 36.861 15 1.325 38.047 14 1.370 37.449 13 1.370 36.967 12 1.326 38.151 11 1.258 39.048 10 1.179 39.603 9

1.094 40.226 8

0.987 40.821 7

0.867 41.143 6

0.758 41.591*

5 0.656 41.584 4

0.573 40.265 3

0.513 36.516 2

0.420 28.246 Bottom 1

0.130 8.314 Edit Radial Power Zone Avg.

Max.

IR 16 0.213 0.217 39 18 0.179 0.190 21 20 0.170 0.170 1

21 0.386 0.528 33 22 0.624 1.147 11 23 0.795 1.027 17 24 0.628 1.172 41 25 1.010 1.204 21 26 1.054 1.249 23 27 1.165 1.200 29 28 1.151 1.269 15 29 1.419 1.500 13 30 1.402 1.460 21 31 1.239 1.422 27 JR 48 2

32 48 28 12 28 20 18 10 26 26 18 10 6

10 14 18 22 26 30 34 38 42 46 50 Control Rod Density:

k-effective:

Void Fraction:

Core Delta-P: psia Core Plate Delta-P: psia Coolant Temp: Deg-F In Channel Flow: Mlb/hr Total Bypass Flow ():

Total Water Rod Flow

(%):

Source Convergence 0.00 0.99845

0. 334 23.147 18.730 544.1 53.16 12.1 3.2 0.00035

% AXIAL TILT 18.655 -10.483 AVG BOT 8ft/12ft 0.9478 1.1050 Active Channel Flow: Mlb/hr 51.25 (of total core flow)

(of total core flow)

Top Ten Thermal Limits Summary -

Sorted by Margin Power Value FT 1.500 29 1.484 29 1.469 29 1.465 29 1.460 30 1.454 30 1.451 30 1.447 30 1.447 30 1.447 30 IR JR 13 26 27 14 15 24 23 16 21 18 17 22 23 20 11 24 13 22 21 14 Value 1.765 1.784 1.793 1.804 1.808 1.811 1.816 1.830 1.832 1.834 MCPR Margin FT 0.901 29 0.891 29 0.887 29 0.881 28 0.879 29 0.878 30 0.876 30 0.869 30 0.868 30 0.867 30 IR JR 13 28 27 14 37 30 37 28 29 38 35 22 21 36 11 30 13 22 19 30 APLHGR Value Margin Exp.

FT 6.68 0.834 52.4 22 6.79 0.825 50.3 24 6.58 0.823 52.6 22 7.22 0.820 44.7 26 6.66 0.815 50.7 22 6.69 0.813 50.2 24 7.43 0.810 41.1 28 7.12 0.809 44.8 26 6.59 0.809 51.0 22 6.32 0.808 54.3 22 IR JR K

11 28 17 41 26 17 25 42 17 39 30 17 33 28 18 27 42 17 37 28 17 29 40 17 27 34 18 33 34 17 Value 6.88 7.04 7.55 6.82 7.44 6.92 7.64

6. 94 7.81 6.84 LHGR Margin Exp.

FT 0.857 51.7 22 0.843 48.7 24 0.843 42.8 26 0.843 51.2 22 0.832 43.0 26 0.831 48.9 22 0.830 40.4 26 0.828 48.3 24 0.826 38.0 28 0.825 49.2 22 IR JR K

11 28 17 41 26 17 13 30 17 25 42 17 29 14 17 33 28 18 37 22 17 27 42 17 37 28 17 27 34 18 LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 0 Thermal limit file:

Figure A.46 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 16,000.0 MWd/MTU AREVA NP Inc.

Uontrolled Uocument ANP-3215(NP)

Revision 0 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Page A-50 Cycle:

Exposure: MWd/MTU (GWd)

Delta E: MWd/MTU, (GWd)

Power: MWt Core Pressure: psia Inlet Subcooling: Btu/ibm Flow: Mlb/hr 28 16327.0 (1383.90 327.0 (

27.72 1863.7 C 93.00 %)

1011.8

-20.83 60.48 (105.00 %)

Core Average Exposure: Md/MTU 33383.8 3

5 7

9 13 15 17 19 21 23 25 iR; 2 3

5 7

9 11 13 15 17 19 21 23 25 51 47 43 39 35 31 27 23 19 15 11 7

3 Axial Profile N(PRA) Power Exposure Top 24 0.318 5.286 23 0.722 12.478 22 1.159 22.737 21 1.318 27.993 20 1.406 31.770

JR 19 1.425' 34.225 18 1.418 35.824 17 1.397 37.155 16 1.348 37.345 15 1.330 38.525 14 1.371 37.892 13 1.369 37.388 12 1.322 38.558 11 1.249 39.433 10 1.164 39.963 9

1.071 40.560 9

0.955 41.120 7

0.828 41.404 6

0.714 41.818" 5

0.611 41.780 4

0.529 40.435 3

0.472 36.668 2

0.387 28.370 Bottom 1

0.119 8.352 Edit Zone 16 18 20 21 22 23 24 25 26 27 28 29 30 31 Radial Power Avg.

Max.

IR 0.212 0.216 39 0.178 0.189 21 0.168 0.168 1

0.386 0.528 33 0.622 1.151 25 0.795 1.031 17 0.627 1.174 41 1.006 1.196 21 1.054 1.244 23 1.167 1.209 29 1.149 1.265 15 1.414 1.501 13 1.401 1.455 21 1.248 1.433 27 JR 48 2

32 48 12 12 26 20 18 10 26 26 18 10 6

10 14 1S 22 Control Rod Density: %

k-effective:

Void Fraction:

Core Oelta-P: psia Core Plate Delta-P: psia Coolant Temp:

Deg-F In Channel Flow: Mlb/hr Total Bypass Flow (%):

Total Water Rod Flow

(%)

Source Convergence 26 30 34 38 42 46 50 0.00 0.99882 0.317 22.832 18.412 542.7 53.28 Active 11.9 (of to1 3.1 (of to 0.00042

% AXIAL TILT 21.503 -10.118 AVG BOT 8ft/12ft 0.9273 1.1030 Channel Flow: Mlb/hr tal core flow) tal core flow) 51.42 Top Ten Thermal Limits Summary -

Sorted by Margin Power MCPR APLHGR Value 1.501 1.486 1.465 1.462 1.455 1.452 1.451 1.449 1.448 1.447 FT 29 29 29 29 30 30 30 30 30 30 IR 13 27 15 23 21 29 11 21 13 17 JR.

26 14 24 16 18 12 24 14 22 22 Value 1.838 1.910 1.924 1.933 1.939 1.946 1.949 1.951 S.954 1.955 Margin 0.842 0.833 0.826 0.823 0.820 0.817 0.816 0.815 0.814 0.813 FT 29 29 29 28 29 30 30 30 30 30 IP.

13 27 37 37 29 35 21 11 29 13 JR 28 14 30 28 38 22 36 30 12 22 Value 6.32 6.23 6.41 6.80

6. 33 6.36 6.72 7.13 6.31 6.18 Margin 0.794 0.785 0.785 0.779 0.775 0.772 0.769 0.768 0.767 0.767 Exp.

53.0 53.2 50.9 45.4 50.8 50.0 45.4 40.1 50.2 51.8 FT 2222 24 26 24 22 26 28 22 22 IR JR 11 28 25 42 41 26 13 24 27 42 33 28 29 40 37 28 27 34 33 34 K

17 17 17 17 17 19 17 18 19 19 Value 6.50 6.45

6. 65 7.11 7.02

6. 56 7.18

6. 60 7.49 6.55 Margin 0.816 0.803 0.803 0.801 0.791 0.789 0.786 0.786 0.782 0.782 LHGR Exp.

FT 52.4 22 51.8 22 49.3 24 43.5 26 43.7 26 49.0 24 41.1 26 48.2 22 36.9 28 48.4 22 IR 11 25 41 13 29 27 37 33 37 27 JR 28 42 26 30 14 42 22 28 28 34 K

17 17 17 17 17 17 17 19 18 19 CLHGR.

calculated with pin-power reconstruction CPR calculated with pin-power reconstruction I CPR limit type 0 Thermal limit file:

Figure A.47 Monticello Cycle 28 Control Rod Pattern and Axial Distributions at 16,327.0 MWdlMTU AREVA NP Inc.

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Appendix B Elevation Views of the Monticello Cycle 28 Fresh Reload Batch Fuel Assemblies AREVA NP Inc.

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Figure B.1 Elevation View for the Monticello Cycle 28 Fresh Fuel ATRIUM 1OXM [

] Fuel Assembly Design AREVA NP Inc.

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Figure B.2 Elevation View for the Monticello Cycle 28 Fresh Fuel ATRIUM 1OXM [

] Fuel Assembly Design AREVA NP Inc.

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I Figure B.3 Elevation View for the Monticello Cycle 28 Fresh Fuel ATRIUM 1OXM [

] Fuel Assembly Design AREVA NP Inc.

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Revision 0 Page C-1 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Appendix C Monticello Cycle 28 Fresh Fuel Locations AREVA NP Inc.

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Table C.1 Monticello Cycle 28 Reload Fuel Identification and Locations (Core Coordinates)

Assembly Type: ATRIUM 1OXM Bundle

Description:

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Table C.1 Monticello Cycle 28 Reload Fuel Identification and Locations (Core Coordinates) (Continued)

Assembly Type: ATRIUM 1OXM Bundle

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Table C.1 Monticello Cycle 28 Reload Fuel Identification and Locations (Core Coordinates) (Continued)

Assembly Type: ATRIUM 1OXM Bundle

Description:

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Revision 0 Page D-1 Monticello Fuel Transition Cycle 28 Fuel Cycle Design (EPU/MELLLA)

Appendix D Monticello Cycle 28 Radial Exposure and Power Distributions AREVA NP Inc.

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