Text

Attachment 11 - ANP-3293NP, Revision 1, Applicability of Areva BWR Methods to the Dresden and Quad Cities Reactors Operating at Extended Power Uprate. (Non-Proprietary)
	ML15251A386
Person / Time
Site:	Dresden, Quad Cities
Issue date:	08/31/2015
From:	Simpson P; Exelon Generation Co
To:	; Document Control Desk, Office of Nuclear Reactor Regulation
Shared Package
ML15251A394	List: ML15251A383; ML15251A384; ML15251A385; ML15251A386; ML15251A387; ML15251A406; RS-15-237, /Quad Cities Nuclear Power Station, Units 1 and 2 - Supplemental Information in Support of Request for License Amendment Regarding Transition to Areva Fuel; RS-15-237, Dresden Nuclear Power Station, Units 2 and 3/Quad Cities Nuclear Power Station, Units 1 and 2 - Supplemental Information in Support of Request for License Amendment Regarding Transition to Areva Fuel;
References
	RS-15-237 ANP-3293NP, Rev 1
	Download: ML15251A386 (93)
	v • d • e

Attachment 11 Fuel Cycle Design Report (Non-Proprietary Version)

Controlled Document A

ARE VA Quad Cities Unit 2 Cycle 24 ANP-3293NP Revision I Representative Fuel Cycle Design August 2015 AREVA Inc.

Controlled Docum~ernt AREVA Inc.

Controlled Document AN P-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Pagei Nature of Changes Item Page Description and Justification

1. iv Revised ACE description

2. 3-8, 3-9, 3-10, and 3-1 1 Reset proprietary markings

3. 4-1 Updated Reference 2 AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page ii Contents 1.0 Introduction ................................................................................... 1-1 2.0 Summary ...................................................................................... 2-I 3.0 Representative Cycle 24 Fuel Cycle Design................................................ 3-I 3.1 General Description .................................................................. 3-I 3.2 Control Rod Patterns and Thermal Limits.......................................... 3-I 3.3 Hot Excess Reactivity and Cold Shutdown Margin................................ 3-2 4.0 References.................................................................................... 4-1 Appendix A Quad Cities Unit 2 Representative Cycle 24 Step-Through Depletion Summary, Control Rod Patterns and Core Average Axial Power and Exposure Distributions ......................................... A-I Appendix B Elevation Views of the Quad Cities Unit 2 Representative Cycle 24 Fresh Reload Batch Fuel Assemblies......................................... B-I Appendix C Quad Cities Unit 2 Representative Cycle 24 Fresh Fuel -

Locations ........................................................................... C-I Appendix D Quad Cities Unit 2 Representative Cycle 24 Radial Exposure and Power Distributions ........................................................... D-I Tables 2.1 Quad Cities Unit 2 Representative Cycle 24 Energy and Key Results Summary ...................................................................................... 2-2 2.2 Quad Cities Unit 2 Representative Cycle 24 Fuel Cycle Design Assembly ID Range by Nuclear Fuel Type ............................................................. 2-3 3.1 Representative Cycle 24 Core Composition and Design Parameters .................... 3-3 3.2 Hot Operating Target k-eff versus Cycle Exposure ........................................ 3-4 3.3 Cold Critical Target k-eff versus Cycle Exposure........................................... 3-4 3.4 Quad Cities Unit 2 Representative Cycle 24 Reactivity Margin Summary ............... 3-5 AREVA Inc.

Controlted Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page iii Figures 2.1 Quad Cities Unit 2 Representative Cycle 24 Design Step-Through k-eff versus Cycle Exposure ...................................................................... 2-4 2.2 Quad Cities Unit 2 Representative Cycle 24 Design Margin to Thermal Limits versus Cycle Exposure ............................................................... 2-4 3.1 Quad Cities Unit 2 Representative Cycle 24 Reference Loading Pattern ................ 3-6 3.2 Quad Cities Unit 2 Representative Cycle 24 Upper Left Quarter Core Layout by Fuel Type.......................................................................... 3-8 3.3 Quad Cities Unit 2 Representative Cycle 24 Upper Right Quarter Core Layout by Fuel Type.......................................................................... 3-9 3.4 Quad Cities Unit 2 Representative Cycle 24 Lower Left Quarter Core Layout by Fuel Type ........................................................................ 3-10 3.5 Quad Cities Unit 2 Representative Cycle 24 Lower Right Quarter Core Layout by Fuel Type ........................................................................ 3-11 AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page iv Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Nomenclature ACE ARE VA's advanced critical power correlation BOC beginning of cycle BOL beginning of life BWR boiling water reactor 0SDM cold shutdown margin EOC end of cycle end of full power capability FFTR final feedwater temperature reduction GWd/MTU gigawatt days per metric ton of initial uranium HEXR hot excess reactivity ICE increased core flow LAR license amendment request LHGR linear heat generation rate MCPR minimum critical power ratio MICROBURN-B2 AREVA Inc. advanced BWR core simulator methodology with PPR capability MWdIMTU megawatt days per metric ton of initial uranium NRC Nuclear Regulatory Commission, U. S.

PLFR part-length fuel rod Pin Power Reconstruction. The PPR methodology accounts for variation PPR 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.

R Value the larger of zero or the shutdown margin at BOC minus the minimum calculated shutdown margin in the cycle SLC standby liquid control SPCB ARE VA (formerly Siemens Power Corporation) critical power correlation AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 1-1 1.0 Introduction ARE VA Inc. (AREVA) has performed a representative fuel cycle design and fuel management calculations based on expected Cycle 24 operation of the Quad Cities Unit 2 BWR as defined in References 3 and 4. The core design presented within is the basis for the safety analyses supporting the License Amendment Request (LAR) for the inclusion of AREVA's methodology in the Tech Specs for both Dresden and Quad Cities. This methodology addition supports the introduction of the ATRIUMTM* 10XM fuel design.

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 applicable critical power correlations, was used to model the core. The MICROBURN-B2 pin power reconstruction (PPR) model was used to determine the thermal margins presented in this report. The ACE critical power correlation (Reference 5) was utilized for the ATRIUM I0XM fuel assemblies while the co-resident Westinghouse OPTIMA-2 fuel assemblies will utilize the SPCB critical power correlation (Reference 6) with appropriate additive constants developed consistent with the NRC approved co-resident fuel topical report (Reference 7). The following MICROBURN-B2 modeling features are included in this analysis:

Version 2 of MICROBURN-B2

Explicit control blade modeling

Control blade '°B depletion

Explicit neutronic treatment of the spacer grids

Explicit thermal-hydraulic modeling of the water rod flow

Explicit modeling of the plenum/spring region above the PLFRs Design results for the representative Cycle 24 reactor core loading including projected control rod patterns and evaluations of thermal and reactivity margins are presented. The representative Cycle 24 results are based on Cycle 22 and 23 core operational history and/or projections as summarized in Table 2.1.

ATRIUM is a trademark of AREVA Inc.

AREVA Inc,

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 2-1 2.0 Summary The representative Cycle 24 fresh batch size (248 assemblies) and batch average enrichment

[ ] were determined to meet the energy requirements provided by Exelon (Reference 4). For a complete description of the fresh reload assemblies, see Reference 2. The loading of the representative Cycle 24 fuel as described in this report results in a projected full power energy capability (including ICF out to 102% of rated) of 1,948+/-38 GWd (15,485+/-300 MWd/MTU). Beyond the full power capability, the cycle has been designed to achieve 110 GWd of additional energy via Constant Pressure Power Coastdown operation.

In order to obtain optimum operating flexibility, the projected control rod patterns were developed to be consistent with a conservative margin to thermal limits. 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 24 design. Figure 2.1 and Figure 2.2 provide a summary of the cycle design step-through projection.

AREVA Inc,

Controtld Documen~t ANP-3293N P Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 2-2 Table 2.1 Quad Cities Unit 2 Representative Cycle 24 Energy and Key Results Summary Summary Table 2.1 Quad Cities Unit 2 Representative Cycle 24 Energy and Key Results Cycle Energy, GWd (Cycle Exposure, MWd/MTU)

Cycle 22

Core follow through October 8, 2013 1,570 (12,590)

Best estimate depletion to Nominal EOC 22 2,082 (16,690)

Cycle 23

Best estimate depletion to Nominal EOC 23 2,013 (16,132)

Short window EOC 23 1,959 (15,700)

Cycle 24

EOFP Energy 1,948+/-38 (15,485+/-300)

Constant Pressure Power Coastdown Energy 110 (878)

EOC Energy 2,058+/-38 (16,362+/--300)

Key Results BOC CSDM, %Ak/k (based on short EOC 23) 1.60 Minimum CSDM, %Ak/k (based on short EOC 23) 1.60 Cycle Exposure of Minimum CSDM, MWd/MTU (short basis) 0 Moderator Temperature of Minimum CSDM, 0F (short basis) 68 Cycle R Value, %Ak/k (short basis) 0.00 Minimum SLC SDM, %Ak/k (based on short EOC 23) 6.54 Cycle Exposure of Minimum SLC SDM, MWd/MTU (short basis) 0 BOC HEXR, %Akdk (based on nominal EOC 23) 1.23 Maximum HEXR, %A~k/k (based on nominal EOC 23) 1.39 Cycle Exposure of Maximum HEXR, MWd/MTU (nominal basis) 11,950.0 Minimum MAPLHGR Margin, % 13.0 Exposure of Minimum MAPLHGR Margin, MWd/MTU 9,351.0 Minimum LHGR Margin, % 14.1 Exposure of Minimum LHGR Margin, MWd/MTU 250.0 Minimum CPR Margin, % 13.6 Exposure of Minimum CPR Margin, MWd/MTU 15,250.0 Minimum Pellet Exposure Ratio Margin, % 3.31 Minimum Rod (including PLFRs) Average Exposure Ratio Margin, % 3.11 Minimum Assembly Average Exposure Ratio Margin, % 11.75 EOC Core Average Exposure (CAVEX), MWd/MTU 37,064.4 AREVA Inc.

Controlted Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 2-3 Table 2.2 Quad Cities Unit 2 Representative Cycle 24 Fuel Cycle Design Assembly ID Range by Nuclear Fuel Type Nuclear Number of Assembly ID Fuel Type Assemblies Range 19 84 QBD001-QBD088 20 8 QBDO89-QBD096 21 96 QBD097-QBD200 22 48 QBD201-QBD248 23 104 QBE001-QBE104 24 80 QBE105-QBEI184 25 56 QBE185-QBE240 26 96 XRA001I-XRA096 27 64 XRA097-XRA160 28 *88 XRA161-XRA248 ARE VA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 2-4 1.010 1.005

-Target 0,995 A Cycle 24 0.990 0 2 4 6 8 I0 12 1416 18 Cycle Exposure (GWdlMTU)

Figure 2.1 Quad Cities Unit 2 Representative Cycle 24 Design Step-Through k-eft versus Cycle Exposure 1,0 E 0.9 I.I f"0.

.2 01.6 246 8 I0 12 14 16 18 Cycle Expos ure (GWdIMTU)

Figure 2.2 Quad Cities Unit 2 Representative Cycle 24 Design Margin to Thermal Limits versus Cycle Exposure AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-1 3.0 Representative Cycle 24 Fuel Cycle Design 3.1 General Description The assembly design for the representative Quad Cities Unit 2 Cycle 24 fresh reload fuel is described in detail in Reference 2. 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 octant symmetry (with the exception of a limited number of locations near the core periphery to maintain exposure limit margin and S1L320 compliance) within a Single Rod Sequence (SRS) 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 operation. The analyses supporting this fuel cycle design were based on the core parameters shown in Table 3.1. Figure 3.1 through Figure 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 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 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 to provide adequate margin to the thermal limits. The limits used to calculate thermal margins are representative and based on best-estimates from the thermal-mechanical, LOCA and safety analyses. 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-eft versus cycle exposure which was determined to be appropriate for the representative Cycle 24 is shown in Table 3.2 (Reference 8). The k-eff and margin to limits

results from the design cycle depletion are presented graphically in Figure 2.1 and Figure 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.

AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-2 3.3 Hot Excess Reactivity and Cold Shutdown Margin The cycle design calculations demonstrate adequate hot excess reactivity, SLC shutdown margin, and cold shutdown margin throughout the cycle. Key shutdown margin and R-Value results are presented in Table 2.1. The shutdown margin is in conformance with the Technical Specification limit of 0.38 + R %Ak/k at BOC. The cold target k-eff versus exposure determined to be appropriate for calculation of cold shutdown margin is shown in Table 3.3 (Reference 8).

Calculations have been performed for a range of increased temperatures from 100 0 F to 220 0 F (in addition to 68 0F) to verify the most limiting shutdown margin was calculated. The core hot excess reactivity was calculated at full power with all rods out, 98.0 Mlb/hr core flow, with equilibrium xenon. Table 3.4 summarizes reactivity margins versus cycle exposure, including the SLC shutdown margin for the representative cycle.

AREVA Inc.

Controlled Documnte ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-3 Table 3.1 Representative Cycle 24 Core Composition and Design Parameters Fuel Description Cycle Loaded Nuclear Fuel Type Number of Assemblies OPTIMA-2 [ ]22 19 84 OPTIMA-2 [ 22 208 OPTIMA-2 [ ]22 21 96 OPTIMA-2 [ ]22 22 48 OPTIMA-2 [ ] 23 23 104 OPTIMA-2 [ ] 23 24 80 OPTIMA-2 [ ] 23 25 56 ATRIUM 10XM [ 3 24 26 96 ATRIUM10XM [ ] 24 27 64 ATRIUM 10XM [ 1 24 28 88 Number of Fuel Assemblies in Core 724 Total Number of Fresh Assemblies 248 Total Core Mass, MTU 125.81 Rated Thermal Power Level, MWt 2,957 Rated Core Flow, MIb/hr 98.0 Reference Pressure, psia 1,015*

Reference Inlet Subcooling, Btu/Ibm 2.1

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

t Value shown is from the 100% Power, 100% Flow condition and is 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.

AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-4 Table 3.2 Hot Operating Target k-eff versus Cycle Exposure Cycle Exposure Hot Operating (MWdIMTU) k-eft*

0.0 1.0000 7,000.0 0.9975 20,000.0 0.9975 Table 3.3 Cold Critical Target k-eft versus Cycle Exposure Cycle Exposure Cold Critical (MWd/MTU) k-eft*

0.0 0.9970 6,000.0 0.9950 20,000.0 0.9950

Values are linearly interpolated between cycle exposure points.

AREVA Inc.

Controi!ed Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-5 Table 3.4 Quad Cities Unit 2 Representative Cycle 24 Reactivity Margin Summary Cold Shutdown SLC Cold Shutdown Hot Excess Cycle Exposure Margin* Margint Reactivity*

(MWd/MTU) (% Ak/k) (% Ak/k) (% Ak/k) 0 1.60 6.54 1.23 250 1.66 6.83 1.14 1,200 1.93 7.16 1.05 2,500 2.49 7.42 1.08 3,825 2.93 7.66 1.07 5,000 3.26 7.81 1.08 6,000 3.34 7.97 1.12 7,000 3.32 8.05 1.17 8,000 3.29 8.16 1.19 9,000 3.22 8.22 1.24 10,000 3.13 8.26 1.28 11,000 2.98 8.28 1.34 11,950 2.72 8.31 1.39 13,000 2.39 8.38 1.31 14,000 2.24 8.72 0.98 15,000 2.27 9.33 0.37 15,405 2.38 9.65 0.06 15,485 2.40 9.71 --

16,362 2.74 10.51 -

NOTE: Values shown for cold shutdown margin are shown in BOLD ifthe most reactive temperature is greater than 68 0F.

Based on short window EOC 23.

tBased on short window EOC 23, calculated at 358.3 0F ARO conditions which correspond to the saturation temperature for the RHR suction low pressure permissive (Reference 9).

Based on nominal EOC 23.

AREVA Inc.

~c O a.

2 1 3 5 7 9 11 13 15 17 10 21 23 25 27 29 60 QBD017 QBD0O9 QBD049 QBDO25 QBD153 58 QBDO89 QBDO33 QBD137 09D081 QBDOS9 Q5D073 56 QBD161 QBD185 QBDO65 QBD121 QBDOO1 QBD233 QBD217 QBD097 QBD209 54 QBD177 0BD057 QEDl05 Q8E193 QBD145 QB6187 XRA218 XRA210 XRA194 XBA186 C 52 QBDO41 QBD129 QBD113 QBD227 QBE219 XRA242 QBE233 XR4A202 QBE097 XRA178 QBE201 50 QBD179 QBD131 QBD1Y3 Q8D201 QBE225 XBA234 XRA154 XRA146 XRA122 XRA170 XRA082 XRA074w 48 QBDI63 QBD195 QBD011 QBD203 QBD243 X9A226 Q9E209 XRA138 QBEO17 QBE057 XRA114 096033 096025 C 46 090187 09D107 090225 096227 XRA225 QBE139 XRA13O X9A090 096065 QB6041 XRA106 XRAO5O096B081 44 090067 Q96195 Q96217 XRA233 096211 XRA129 096123 XRA162 Q86049 XRA066 096113 XRA042 QBE089 42 090091 090123 QBD147 XRA241 XRA153 XRA137 XRA089 XRA161 096121 XRAO58 QBE129 XRA034 QBEI05 XRA026 C 40 090019 090035 Q90003 Q96185 Q96235 XRA145 096019 Q96067 096051 XRAO57 Q96153 Q96169 Q96009 XPAO18 096073 C 38 090099 Q00139 090115 6RA217 X9A201 XRA121 096059 096043 XRA065 096131 096171 096155 XRA098 096001 QBE616 36 090051 090083 Q90235 XRA209 096099 XRA169 XRA113 XRA105 096115 XRA033 09E011 X9A097 09E137 XRAO1O0961E77 CD 34 Q90027 090241 Q90219 XRA193 XRA177 XRA081 Q96035 XRA049 XRA041 096107 XRA017 Q96003 XRA009 Q96147 XRA002 o 32 090155 090075 Q90211 X9A185 Q96203 X9A073 Q96027 Q96083 Q96091 XR4A025 QBE075 QB6163 096179 XRAOO1 096145 ,

30 Q90157 Q9D077 Q90213 X9A192 Q96205 XRA080 Q96029 QBE085 QBE093 XRA032 096077 Q96165 096181 XRA008 Q96151 0 28 090029 09D247 090221 XRA200 XRA184 XRA088 09E037 XRA056 6RA048 096109 XRA024 Q96005 XRAO16 Q96149 XRA007 C 26 090053 090085 090101 X9A216 096101 XRA176 XRA12O XRA112 Q96117 XRAO4O096B013 XRA104 Q96143 XRAO15 QBE183 24 Q90013 090141 QBD117 6RA224 XRA208 XRA128 096061 QBE045 XRA072 QBE133 Q96173 QB6157 XRA103 QBE007 QBEI67 c 22 Q90021 090037 090005 Q96191 Q96237 XRA152 QBE021 096069 096053 XRA064 Q96159 QBEI75 096015 XRA023 Q96079

20 090093 Q90125 090149 XRA248 XRA160 XRA144 X9A096 XRA168 096127 XRA063 096135 XRA039 096111 XRA031 18 090069 Q96197 0BE223 XRA240 096213 XRA136 096125 XRA167 096055 XRAO71 096119 XRA047 096095 16 090189 090109 090231 Q96229 XRA232 096141 XRA135 XRA095 Q96071 096047 XRA111 XRAO5S 096087 14 090165 090197 090015 QBD205 090245 XRA231 QBE215 XRA143 096023 096063 XRA119 096039 Q96031 12 Q90181 090133 QBD9090 90207 096231 XRA239 XPA1S9 XRA151 XRA127 XRA175 XRA087 XRA079 10 090047 090135 09D239 090220 096221 XRA247 09E239 XRA207 096103 X9A183 096207 8 Q90183 090063 Q90111 Q96199 090151 Q96189 XRA223 XRA215 XRA199 XRA191 6 090167 Q9BD191 090071 090127 090007 090119 0BD237 090223 090215 4 090095 090039 090143 090087 Q90061 Q9D079 2 Q90023 Q90103 Q90055 Q90031 Q90159 Figure 3.1 Quad Cities Unit 2 Representative Cycle 24 Reference Loading Pattern z

U, o)Lt

C) 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 60 QBDI54 QBD026 QBDO50 QBD01O QBD018 0_

58 QBD074 QBDO6O QBDO82 QBDI38 QBD034 QBD090 C 56 QBD21O QBD098 QBD218 QBD1I4 QBD002 QBDI22 QBD066 QBDI86 QBDI62 r'3 54 XRAI87 XRAI95 XRA211 XRA219 QBEI88 QBDI46 QBEI94 QBD106 QBD058 QBDI78 4 52 QBE202 XRAI79 QBEO98 XRA203 QBE234 XRA243 QBE220 QBD228 QBD234 QBDI30 QBD042 CD 50 XRA075 XRA083 XRA171 XR~AI23 XRAI47 XRAI55 XRA235 QBE226 QBD202 QBDI94 QBDI32 QBDI80 V*

48 0BE026 QBE034 XPA1I5 QBEO58 QBEO18 X8AI39 QBE210 XRA227 QBD244 QBD2O4 QBDII6 QBDI96 0BDI64 C 46 QBE082 XRA051 XRAI07 QBE042 QBE066 XRA091 XRAI31 QBEI40 XRA228 QBE228 QBD226 QBDI08 QBDI88 C 44 QBE090 XRA043 QBEII4 XRA067 QBE050 XRAI63 QBEI24 XRAI32 QBE212 XRA236 QBE218 QBEI96 QBD068 42 XRA027 QBEI06 XRA035 QBE130 XRA059 QBEI22 XRAI64 XRA092 XRAI40 XRA156 XRA244 QBD148 QBDI24 QBD092 ,

40 QBE074 XRA019 QBE010 QBE170 QBEI54 XRA060 QBE052 QBE068 QBE020 XRAI48 QBE236 QBE186 QBD004 QBD036 QBD020 O

38 QBEI62 QBE002 XPA099 QBE156 QBEI72 QBEI32 XRA068 QBE044 QBE060 XRAI24 XRA204 XRA220 QBD236 QBDI40 QBD012 C 36 QBEI78 XRA011 QBEI38 XRA100 QBE012 XRA036 QBEII6 XRA108 XRAII6 XRAI72 QBEI00 XRA212 QBD22O QBD084 QBD052 -

34 XRA003 QBEI48 XRA012 QBE004 XRA020 QBE108 XRA044 XRA052 QBE036 XRA084 XRAI80 XRAI96 QBD100 QBD242 QBD028 32 QBEI46 XRA004 QBEI80 QBEI64 QBE076 XRA028 QBE092 QBE084 QBE028 XRA076 QBE204 XRAI88 QBD212 QBD076 QBDI56 CD 30 QBEI52 XRA005 QBEI82 QBEI66 QBE078 XRA029 QBE094 QBE086 QBE030 XRA077 QBE206 XRAI89 QBD214 QBD078 QBDI58 C) 28 XRA006 QBE150 XRA013 QBE006 X8A021 QBE1I0 X8A045 XRA053 QBE038 XRA085 XRAISI XRAI97 QBD222 QBD248 QBD030 26 QBEI84 XRA014 QBEI44 XRAI01 QBE014 XRA037 QBEII8 XRAI09 XRAII7 XRAI73 QBEI02 XRA213 QBDI02 QBD086 QBD054 24 QBE168 QBE008 XRAI02 QBEI58 QBEI74 QBE134 XRA069 QBE046 QBE062 XRAI25 XRA205 XRA221 QBDI2O QBD142 QBD014 o*

22 QBE08O XRAO22 QBE016 QBEI76 QBE160 XRA061 QBEO54 QBEO70 QBE022 XRAI49 QBE238 QBEI92 QBD006 QBD038 QBD022 C 20 XRA030 QBEII2 XRA038 QBEI36 XRA062 QBEI28 XRAI65 XRA093 XRA141 XRAI57 XRA245 QBDI50 QBD126 QBD094 C 18 QBEO96 XRAO46 QBE120 XRA07Q QBE056 XRAI66 QBE126 XRA133 QB6214 XRA237 QB8224 QBEI98 QBD070 16 QBE088 XBA054 XRAII0 Q6E048 QBE072 XRA094 XRAI34 QBE142 XRA229 QBE230 QBD232 QBDII0 QBD190 14 0BE032 QBEO4O XRA118 QBE064 QBE024 XRA142 QBE216 XRA230 QBD246 QBD206 QBDII8 QBDI98 QBD166 12 XRA078 XBA086 XRAI74 XRAI26 XRAI50 XRA158 XRA238 QBE232 QBD208 QBD200 QBDI34 QBDI182 10 QBE208 XRAI82 QBEI04 XRA206 QBE240 XRA246 QBE222 QBD230 QBDO16 QBDI36 QBD048 8 XRA1g0 XRA198 X6A214 XRA222 QBE190 QBDI52 QBE200 QBD1I2 QBD064 QBDI84 6 QBD216 QBD224 QBD238 QBD240 QBD008 QBDI28 QBD072 QBDI92 QBDI68 4 QBD080 QBD062 QBD088 QBDI144 QBD04O0QBD096 2 QBD16O0QBD032 QBDO56 QBD1O4 QBD024 Figure 3.1 Quad Cities Unit 2 Representative Cycle 24 Reference Loading Pattern (Continued) z CD

Controlged Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-8 1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 60 19 19 19 19 21 44.5 41.8 43.5 43.4 43.7 58 Nuclear Fuel Type 20 19 21 19 19 19 SOC Exposure (GWd/NTUI) 41.6 43.2 42.8 42.8 41.7 43.8 56 21 21 19 21 19 22 22 21 22 44.9 44.2 44.1 42.1 41.8 41.8 40.8 40.7 40.1 54 21 19 21 25 21 25 28 28 28 28 44.6 43.4 42.6 19.5 39.2 18.6 0.0 0.0 0.0 0.0 52 19 21 21 22 25 28 25 28 23 28 25 44.6 43.6 41.6 36.1 19.5 0.0 20.3 0.0 22.2 0.0 19.9 50 21 21 21 22 25 28 27 27 27 28 26 26 44.5 43.6 43.1 36.6 17.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 48 21 21 19 22 22 28 25 27 23 23 27 23 23 44.9 43.1 41.7 36.5 35.7 0.0 20.0 0.0 22.4 23.6 0.0 22.9 22.9 46 21 21 22 25 28 24 27 26 23 23 27 26 23 44.1 42.5 36.2 17.5 0.0 20.9 0.0 0.0 23.0 23.2 0.0 0.0 22.9 44 19 25 25 28 25 27 24 28 23 26 24 26 23 44.1 19.5 19.5 0.0 20.0 0.0 21.6 0.0 22.6 0.0 21.3 0.0 22.0 42 20 21 21 28 27 27 26 28 24 26 24 26 24 26 34.3 42.0 39.1 0.0 0.0 0.0 0.0 0.0 21.6 0.0 22.5 0.0 20.0 0.0 40 19 19 19 25 25 27 23 23 23 26 24 24 23 26 23 44.4 43.1 41.8 18.6 20.3 0.0 22.5 23.0 22.6 0.0 23.3 23.6 21.9 0.0 22.9 38 21 21 21 28 28 27 23 23 26 24 24 24 27 23 24 40.6 42.7 41.5 0.0 0.0 0.0 23.6 23.2 0.0 22.6 23.6 23.4 0.0 20.8 23.5 36 19 19 22 28 23 28 27 27 24 26 23 27 24 26 24 43.7 42.7 39.8 0.0 22.2 0.0 0.0 0.0 21.3 0.0 22.0 0.0 21.0 0.0 22.9 34 19 22 22 28 28 26 23 26 26 24 26 23 26 24 26 43.3 42.8 40.7 0.0 0.0 0.0 23.0 0.0 0.0 20.0 0.0 20.8 0.0 22.1 0.0 32 21 19 22 28 25 26 23 23 23 26 23 24 24 26 24 43.7 43.8 40.0 0.0 20.0 0.0 22.9 22.9 22.0 0.0 22.9 23.5 23.0 0.0 22.1 No. Per Fuel Type Description Cycle Loaded Quarter core 19 [ ] 22 21 20 [ ] 22 2 21 [ ] 22 24 22 [ ] 22 12 23 [] 23 26 24 [ ] 23 20 25 [ ] 23 14 26 [ ] 24 24 27 [ ] 24 16 28 [ ] 24 22 Figure 3.2 Quad Cities Unit 2 Representative Cycle 24 Upper Left Quarter Core Layout by Fuel Type AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-9 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 60 21 19 19 19 19 43.7 43.3 43.5 41.8 44.5 58 19 19 19 21 19 20 Nuclear Fuel Type 43 .7 41.8 42 .8 42 .9 43 .1 41.5 BOC Exposure (GWd/MTU) 56 22 21 22 21 19 21 19 21 21 40.2 40.7 40.9 41.6 41.9 42.2 44.0 44.1 44.9 54 28 28 28 28 25 21 25 21 19 21 0.0 0.0 0.0 0.0 18.6 39.2 19.5 42.7 43.4 44.6 52 25 28 23 28 25 28 25 22 22 21 19 20.0 0.0 22.2 0.0 20.3 0.0 19.4 36.1 41.7 43.7 44.4 50 26 26 28 27 27 27 28 25 22 21 21 21 0.0 0.0 0.0 0.0 0.0 0.0 0.0 17.5 36.6 43.0 43.7 44.6 48 23 23 27 23 23 27 25 28 22 22 21 21 21 22.5 22.9 0.0 23.6 22.4 0.0 20.0 0.0 35.7 36.5 41.5 43.0 44.9 46 23 26 27 23 23 26 27 24 28 25 22 21 21 22.8 0.0 0.0 23.2 23.0 0.0 0.0 20.9 0.0 17.5 36.1 42.6 44.1 44 23 26 24 26 23 28 24 27 25 28 25 25 19 22.0 0.0 21.3 0.0 22.6 0.0 21.5 0.0 20.0 0.0 19.5 19.5 44.0 42 26 24 26 24 26 24 28 26 27 27 28 21 21 20 0.0 20.0 0.0 22.5 0.0 21.6 0.0 0.0 0.0 0.0 0.0 39.2 42.1 34.4 40 23 26 23 24 24 26 23 23 23 27 25 25 19 19 19 22.9 0.0 21.9 23.6 23.3 0.0 22.6 23.0 22.4 0.0 20.3 18.6 41.9 43.1 44.4 38 24 23 27 24 24 24 26 23 23 27 28 28 22 21 19 23.5 20.8 0.0 23.3 23.6 22.5 0.0 23.2 23.6 0.0 0.0 0.0 39.8 42.7 41.7 36 24 26 24 , 27 23 26 24 27 27 28 23 28 22 19 19 22.9 0.0 21.0 0.0 21.9 0.0 21.3 0.0 0.0 0.0 22.2 0.0 40.8 42.7 43.7 34 26 24 26 23 26 24 26 26 23 26 28 28 21 22 19 0.0 22.0 0.0 20.8 0.0 20.0 0.0 0.0 22.9 0.0 0.0 0.0 40.6 42.7 43.3 32 24 26 24 24 23 26 23 23 23 26 25 28 22 19 21 22.1 0.0 22.9 23.5 22.9 0.0 22.0 22.8 22.9 0.0 20.0 0.0 40.1 43.7 43.7 No. Per Fuel Type Description Cycle Loaded Quarter core 19 [ ] 22 21 20 [ ] 22 2 21 [ ] 22 24 22 [ ] 22 12 23 [ ] 23 26 24 [ 1 23 20 25 [ ] 23 14 26 [ ] 24 24 27 [ ] 24 16 28 [ ] 24 22 Figure 3.3 Quad Cities Unit 2 Representative Cycle 24 Upper Right Quarter Core Layout by Fuel Type ARE VA Inc.

Controlled Document AN P-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-10 1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 30 21 19 22 28 25 26 23 23 23 26 23 24 24 26 24 43.7 43.8 40.0 0.0 20.0 0.0 22.9 22.9 22.1 0.0 22.9 23.5 22.9 0.0 22.1 28 19 22 22 29 28 26 23 26 26 24 26 23 26 24 26 43.3 42.7 40.8 0.0 0.0 0.0 23.0 0.0 0.0 20.0 0.0 20.8 0.0 22.0 0.0 26 19 19 21 28 23 28 27 27 24 26 23 27 24 26 24 43.7 42.7 40.6 0.0 22.2 0.0 0.0 0.0 21.3 0.0 21.9 0.0 21.0 0.0 22.9 24 19 21 21 28 28 27 23 23 26 24 24 24 27 23 24 41.7 42.7 41.5 0.0 0.0 0.0 23.6 23.2 0.0 22.5 23.6 23.3 0.0 20.8 23.5 22 19 19 19 25 25 27 23 23 23 26 24 24 23 26 23 44.4 43.1 41.9 18.6 20.3 0.0 22.5 23.0 22.6 0.0 23.3 23.6 22.0 0.0 22.9 20 20 21 21 28 27 27 26 28 24 26 24 26 24 26 34.4 42.1 39.1 0.0 0.0 0.0 0.0 0.0 21.6 0.0 22.6 0.0 20.0 0.0 18 19 25 25 28 25 27 24 28 23 26 24 26 23 44.1 19.5 19.5 0.0 20.0 0.0 21.5 0.0 22.6 0.0 21.3 0.0 22.1 16 21 21 22 25 28 24 27 26 23 23 27 26 23 44.2 42.5 36.1 17.5 0.0 20.9 0.0 0.0 23.0 23.2 0.0 0.0 22.9 14 21 21 10 22 22 28 25 27 23 23 27 23 23 44.9 43.0 41.9 36.5 35.8 0.0 20.0 0.0 22.5 23.6 0.0 23.0 22.9 12 21 21 21 22 25 28 27 27 27 28 26 26 44.5 43.7 43.0 36.6 17.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 10 19 21 22 22 25 28 25 28 23 28 25 44.6 43.7 41.7 36.1 19.4 0.0 20.4 0.0 22.2 0.0 20.0 8 21 19 21 25 21 25 28 28 28 28 44.6 43.4 42.7 19.5 39.2 18.6 0.0 0.0 0.0 0.0 6 21 21 19 21 19 21 22 22 22 44.9 44.1 44.1 42.1 42.0 41.6 39.8 40.8 40.2 4 Nuclear Fuel Type 20 19 21 19 19 19 BOG Exposure (GWd/MTU) 41.5 43.1 42.8 42.8 41.7 43.8 2 19 21 19 19 21 44.5 40.7 43.5 43.4 43.7 NO. Per Fuel Type Description Cycle Loaded Quarter core 19 [ ] 22 21 20 [ ] 22 2 21 [ J 22 24 22 [ ] 22 12 23 [ ] 23 26 24 [ ] 23 20 25 C 3 23 14 26 C ] 24 24 27 [ 3 24 16 28 [ 3 24 22 Figure 3.4 Quad Cities Unit 2 Representative Cycle 24 Lower Left Quarter Core Layout by Fuel Type ARE VA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 3-11 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 30 24 26 24 24 23 26 23 23 23 26 25 28 22 19 21 22.1 0.0 22.9 23.5 22.9 0.0 22.0 22.8 22.9 0.0 20.0 0.0 40.1 43.8 43.7 28 26 24 26 23 26 24 26 26 23 26 28 28 22 22 19 0.0 22.1 0.0 20.8 0.0 20.0 0.0 0.0 23.0 0.0 0.0 0.0 40.7 42.8 43.3 26 24 26 24 27 23 26 24 27 27 28 23 28 21 19 19 22.9 0.0 21.0 0.0 22.0 0.0 21.3 0.0 0.0 0.0 22.2 0.0 40.6 42.7 43.8 24 24 23 27 24 24 24 26 23 23 27 28 28 21 21 19 23.5 20.8 0.0 23.3 23.6 22.6 0.0 23.2 23.6 0.0 0.0 0.0 41.6 42.7 41.7 22 23 26 23 24 24 26 23 23 23 27 25 25 18 19 19 22.9 0.0 22.0 23.6 23.3 0.0 22.6 23.0 22.5 0.0 20.4 18.6 41.9 43.1 44.4 20 26 24 26 24 26 24 28 26 27 27 28 21 21 20 0.0 20.0 0.0 22.6 0.0 21.6 0.0 0.0 0.0 0.0 0.0 39.2 42.0 34.4 18 23 26 24 26 23 28 24 27 25 28 25 25 19 22.0 0.0 21.3 0.0 22.6 0.0 21.6 0.0 20.0 0.0 19.5 19.5 44.1 16 23 26 27 23 23 26 27 24 28 25 22 21 21 22.8 0.0 0.0 23.3 23.0 0.0 0.0 21.0 0.0 17.5 36.2 42.5 44.1 14 23 23 27 23 23 27 25 28 22 22 21 21 21 22.9 23.0 0.0 23.6 22.5 0.0 20.0 0.0 35.8 36.5 41.5 43.0 44.9 12 26 26 28 27 27 27 28 25 22 21 21 21 0.0 0.0 0.0 0.0 0.0 0.0 0.0 17.5 36.6 43.1 43.6 44.6 10 25 28 23 28 25 28 25 22 19 21 19 20.0 0.0 22.2 0.0 20.4 0.0 19.5 36.1 41.8 43.7 44.6 8 28 28 28 28 25 21 25 21 19 21 0.0 0.0 0.0 0.0 18.6 39.3 19.5 42.7 43.4 44.6 6 22 22 22 22 19 21 19 21 21 40.2 40.8 39.8 41.7 42.0 42.2 44.1 44.2 44.8 4 19 19 19 21 19 20 Nuclear Fuel Type 43.8 41.8 42.8 42.8 43.2 41.6 BOC Exposure (GWd/MTUJ) 2 21 19 19 21 19 43.7 43.4 43.5 40.7 44.5 NO. Per Fuel Type Description Cycle Loaded Quarter core 19 3 22 21 20 [ ] 22 2 21 [ ] 22 24 22 [ 1 22 12 23 [ ] 23 26 24 ( ] 23 20 25 [ 22 14 26 C ] 24 24 27 [ ] 24 16 28 C ] 24 22 Figure 3.5 Quad Cities Unit 2 Representative Cycle 24 Lower Right Quarter Core Layout by Fuel Type AREVA Inc.

Controlled Document ANP-3293N P Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 4-1 4.0 References

1. EMF-21 58(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. AN P-3294P Revision 1, Nuclear Fuel Design Report Quad Cities Unit 2 Cycle 24 Representative Cycle ATRIUM IOXM Fuel, AREVA Inc., August 2015.

3. 38-2201197-000, TODI NF1 300233, ARE VA Representative Cycle - Cycle Design Inputs and Requirements (CDIR), January 2014.

4. 38-2201177-000, TODl NF 1300232, ARE VA Representative Cycle - Energy Utilization Plan (EUP), October 2013.

5. ANP-10298P-A Revision 1, ACE/A TRIUM IOXM Critical Power Correlation, AREVA Inc.,

March 2014.

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

7. EMF-2245(P)(A) Revision 0, Application of Siemens Power Corporation'sCriticalPower Correlationsto Co-Resident Fuel, Siemens Power Corporation, August 2000.

8. 12-9215611-000, Quad Cities Unit 2 Cycle 24 Transition Core Design Target K-Effective Selection, AREVA NP, December, 2013.

9. 38-2201170-003, TODl ES1300015, Quad Cities Unit 2 PlantParametersDocument for Transition, October 2014.

AREVA Inc.

Controfled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-I Appendix A Quad Cities Unit 2 Representative Cycle 24 Step-Through Depletion Summary, Control Rod Patterns and Core Average Axial Power and Exposure Distributions AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-2 Table A.1 Quad Cities Unit 2 Representative Cycle 24 Design Depletion Summary Total Total Inlet Core Core Cycle Control Core Core Ref. Sub- Core Maximum Maximum Exposure Calculated Rod Power Flow Pressure Cooling Void Minimum 1HCR APLHGR CGWd/MT) K-aft Density MWt (Mlb/hr) (psia) (Stu/ib) Fraction CPR CkW/ft) (kW/ft) 0.000 1.00000 4.28 2957.0 96.04 1015.00 24.74 0.407 1.793 12.33 9.10 0.250 0.99988 4.19 2957.0 96.04 1015.00 24.74 0.400 1.758 11. 63 8.57 0.500 0.99979 3.48 2957.0 96.04 1015.00 24.74 0.404 1.755 11.54 8.91 1.000 0.99969 3.46 2957.0 96.04 1015.00 24.74 0.401 1.752 11.37 8.84 1.200 0.99953 3.48 2957.0 96.04 1015.00 24.74 0.401 1.766 11.38 8.86 1.201 0.99952 4.05 2957.0 96.04 1015.00 24.74 0.389 1.765 11.16 8.40 1.500 0.99941 4.07 2957.0 96.04 1015.00 24.74 0.388 1.770 11.03 8.36 2.000 0.99922 4.10 2957.0 96.04 1015.00 24.74 0.387 1.792 10.82 8.31 2.500 0.99918 4.10 2957.0 96.04 1015.00 24.74 0.384 1.791 10.59 8.25 3.000 0.99907 4.10 2957.0 96.04 1015.00 24.74 0.382 1.788 10.40 8.26 3.500 0.99877 4.12 2957.0 96.04 1015.00 24.74 0.382 1.788 10.45 8.38 3.825 0.99872 4.12 2957.0 96.04 1015.00 24.74 0.381 1.788 10.45 8.44 3.826 0.99864 3.58 2957.0 96.04 1015.00 24.74 0.395 1.848 11.25 9.06 4 .000 0.99857 3.58 2957.0 96.04 1015.00 24.74 0.395 1.851 11.23 9.06 4.500 0.99851 3.58 2957.0 96.04 1015.00 24.74 0.393 1.859 11.16 9.08 5.000 0.99834 3.60 2957.0 96.04 1015.00 24.74 0.392 1.865 11.17 9.14 5.500 0.99792 3.72 2957.0 96.04 1015.00 24.74 0.393 1.873 11.27 9.30 6.000 0.99770 3.77 2957.0 96.04 1015.00 24.74 0.393 1.880 11.36 9.49 6.500 0.99760 3.81 2957.0 96.04 1015.00 24.74 0.393 1.888 11.46 9.70 6.750 0.99768 3.81 2957.0 96.04 1015.00 24.74 0.393 1.892 11.52 9.80 6.751 0.99765 4.47 2957.0 96.04 1015.00 24.74 0.378 1.811 10.92 9.36 7.000 0.99746 4.52 2957.0 96.04 1015.00 24.74 0.379 1.819 11.01 9.48 7.500 0.99759 4.52 2957.0 96.04 1015.00 24.74 0.379 1.828 11.08 9.64 8.000 0.99751 4.57 2957.0 96.04 1015.00 24.74 0.379 1.834 11.07 9.70 8.500 0.99755 4.61 2957.0 96.04 1015.00 24.74 0.378 1.841 11.02 9.67 9.000 0.99761 4.66 2957.0 96.04 1015.00 24.74 0.376 1.835 10.95 9.72 9.350 0.99763 4.71 2957.0 96.04 1015.00 24.74 0.374 1.832 10.82 9.67 9.351 0. 99746 4.73 2957.0 96.04 1015.00 24.74 0.383 1.877 11.51 10.18 9.500 0.99741 4.76 2957.0 96.04 1015.00 24.74 0.383 1.871 11.46 10.14 i0.000 0. 99746 4.80 2957.0 96.04 1015.00 24.74 0.378 1.857 10.95 9.76 10.500 0.99743 4.90 2957.0 96.04 1015.00 24.74 0.373 1.833 10.37 9.30 11.000 0.99740 5.18 2957.0 96.04 1015.00 24.74 0.368 1.807 9.71 8.75 11.500 0.99759 5.23 2957.0 96.04 1015.00 24.74 0.361 1.780 9.12 8.22 11.950 0.99760 5.27 2957.0 96.04 1015.00 24.74 0.355 1.761 9.16 8.09 11.951 0. 997 61 5.11 2957.0 96.04 1015.00 24.74 0.345 1.768 9.45 8.38 12.000 0.99757 5.13 2957.0 96.04 1015.00 24.74 0.344 1.764 9.47 8.40 12.500 0.99758 5.13 2957.0 96.04 1015.00 24.74 0.337 1.755 9.60 8.53

13. 000 0.99753 5.06 2957.0 96.04 1015.00 24.74 0.329 1.722 9.60 8.60 13.500 0.99750 4.94 2957.0 96.04 1015.00 24.74 0.320 1.719 9.66 8.69 13.600 0.99753 4.92 2957.0 96.04 1015.00 24.74 0.319 1.722 9.68 8.71

13. 601 0.99751 4.17 2957.0 96.04 1015.00 24.74 0.333 1.719 9.41 8.47 14 .000 0.99748 3.91 2957.0 96.04 1015.00 24.74 0.324 1.721 9.52 8.55 14.500 0. 99746 2.38 2957.0 96.04 1015.00 24.74 0.323 1.721 9.56 8.71 15.000 0.99736 1.93 2957.0 96.04 1015.00 24.74 0.310 1.725 9.57 8.65 15.250 0. 99768 0.49 2957.0 96.04 1015.00 24.74 0.316 1.701 9.79 8.79

15. 405 0.99807 0.00 2957.0 98.00 1015.00 24.21 0.312 1.732 9.74 8.74 15.4 85 0.99794 0.00 2957.0 99.96 1015.00 23.70 0.308 1.741 9.78 8.78 15.963 0.99731 0.00 2735.9 99.96 1015.00 22.15 0.289 1 .862 9.23 8.28

16. 362 0.99733 0.00 2513.4 99.96 1015.00 20.61 0.270 1.996 8. 64 7.74 AREVA Inc.

Controlled Document AN P-3293N P Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-3 Table A.2 Quad Cities Unit 2 Representative Cycle 24 Design Depletion Thermal Margin Summary Fraction Core Fraction Core Fraction Cycle Control Core of Limiting of Limiting of Exposure Calculated Rod Limiting Limiting LHiGP Limiting APLHGP. Limiting (G0~d/MT) K-eff Density CPR CPR (kW/ft) LHGR (kW/ft) APLHGR 0.000 1.00000 4.284 1.793 0.814 10.48 0.905 9.10 0.903 0.250 0.99986 4.190 1 .758 0.831 9.58 0.859 8 .57 0.854 0.500 0.99979 3.484 1 .755 0.832 9.32 0.841 8.05 0.838 1.000 0.99969 3. 460 1.752 0.833 9.01 0.822 7.86 0.818 1.200 0.99953 3.464 1.766 0.827 8.94 0.819 7.84 0.815 1.201 0.99952 4.049 1.765 0.827 8.78 0.804 7 .92 0.809 1.500 0. 99941 4 .073 1.770 0.825 8.65 0.798 7 .80 0.801 2.000 0.99922 4.096 1.792 0.815 8.64 0.790 7 .62 0.785 2.500 0.99918 4.096 1.804 0.809 8.46 0.782 7 .45 0.768 3.000 0.99907 4.096 1.788 0.805 8.32 0.777 7 .34 0.759 3.500 0.99877 4.120 1.788 0.805 8.22 0.776 7.28 0.754 3.825 0.99872 4 .120 1.788 0.805 8.13 0.773 7.23 0.750

3. 826 0.99864 3.578 1.848 0.790 8.73 0.817 7.63 0.809 4 .000 0.99857 3.57 8 1.851 0.789 8 .67 0.815 7.79 0.806 4.500 0.99851 3.578 1.869 0.781 8.49 0.807 7. 67 0.795 5.000 0.99834 3.602 1.865 0.772 8.37 0.805 7.59 0.789 5.500 0.99792 3.719 1 .873 0.769 8.30 0.812 9.30 0.794 6.000 0.99770 3.766 1.880 0.766 8.31 0.822 9.49 0.811 6.500 0.99760 3.814 1.888 0.763 8.33 0.834 9.70 0.829 6.750 0.99768 3.814 1.892 0.761 8.34 0.839 9.80 0.837 6.751 0.99765 4.473 1.811 0.795 8.06 0.807 9.36 0.800 7.000 0. 99746 4.520 1.819 0.791 7.85 0.811 9.48 0.810 7.500 0.99759 4 .520 1.828 0.788 7.82 0.817 9.64 0.824 8.000 0.99751 4.567 1.834 0.785 7.80 0.820 9.70 0.829 8.500 0.99755 4.614 1.841 0.782 7.78 0.827 9.67 0.627 9.000 0.99761 4.661 1.835 0.785 7.67 0.825 9 .72 0.831 9.350 0.99763 4.708 1.832 0.786 7.55 0.818 9.67 0.826 9.351 0. 99746 4.732 1.877 0.7 67 8.09 0.858 10 .18 0.870 9.500 0. 99741 4.755 1.871 0.770 8.03 0.855 10.14 0.8 68

10. 000 0.99746 4.802 1.857 0.775 7.66 0.824 9.76 0.846 10.500 0. 997 43 4.896 1.833 0.785 7.14 0.789 9.30 0.815 11.000 0.99740 5.179 1.807 0.797 6.80 0.759 8.75 0.775 11.500 0.99759 5.226 1.780 0,809 6.53 0.733 8.22 0.733 11.950 0. 997 60 5.273 1.761 0.818 6.91 0.747 8.09 0.715 11.951 0.99761 5.108 1.768 0.814 7.33 0.765 8.35 0.739 12.000 0.99757 5.132 1.764 0.817 7.34 0.7 67 8.37 0.741 12.500 0.99756 5.132 1.755 0.820 7.37 0.778 8.53 0.758 13.000 0.99753 5.061 1.722 0.836 7.33 0.782 8.58 0.770

13. 500 0.99750 4.944 1.719 0.855 7.51 0.801 8.66 0.7 85 13.600 0.99753 4.920 1.722 0.854 7.52 0.803 8 .68 0.786

13. 601 0.99751 4.167 1.719 0.855 6.80 0.7 63 8.47 0.771 14 .000 0.99748 3.908 1.721 0.854 7 .97 0.804 8.55 0.785 14.500 0.9974 6 2.378 1.721 0.854 7.14 0.802 8.71 0.807 15.000 0.99736 1.930 1.725 0.852 7.58 0.819 8.65 0.810 15.250 0.99768 0.4 94 1.701 0.864 7.36 0.823 8.78 0.814 15.405 0.99807 0.000 1 .732 0.849 7.29 0.818 8.71 0.811 15.485 0.99794 0.000 1.74 1 0.844 7.30 0.820 8.74 0.814 15.963 0.99731 0.000 1.862 0.789 6.76 0.768 8.19 0.771 16.362 0.99733 0.000 1.996 0.737 6.41 0.721 7.61 0.723 AREVA Inc.

Controfled Documn&t ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-4 Cycle: 24 Core Average Exposure: MWd/O4TU 20701.2 Exposure: MWd/MTU (G~d) 0.0 C 0.00 Delta E: M~d/MTU, (O~d) 0.0 ( 0.00) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 9) N(PRA) Power Exposure Zone Avg. Max. 1K JR Core Pressure: psia 1015.0 Top 24 0.141 3.641 19 0.376 0.643 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.259 8.406 20 0.333 0.348 3 42 Flow: Nib/hr 96.04 ( 98.00 %) 22 0.547 16.276 21 0.455 0.801 53 42 21 0.658 19.868 22 0.712 0.864 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.739 21.758 23 1.319 1.504 27 38 58 59 19 0.794 22.672 24 1.324 1.548 29 38 55 55 18 0.831 22.587 25 1.118 1.305 13 44 51 51 17 0.884 22.593 26 1.301 1.428 27 36 47 ....- 34----------20 . 34 --. .. -.. 16 0.920 22.785 27 1.281 1.378 23 36 43 43 15 0.954 23.190 28 1.129 1.394 17 42 39-----------8 ... -- 8------- -- 39 14 0.984 23.788 35-------------- -- 35 13 1.079 23.089 31----------20----------12 . 20 -.. .. -- 31 -.. 12 1.137 23.463 27-------------- -- 27 11 1.193 24.076 23-----------8 ... -- 8------- -- 23 10 1.248 24.479 19 18 9 1.302 24.620 15 ... 34----------20 . 34 -. 15 -.. 8 1.364 25.091 11 11 7 1.408 25.438 7 7 6 1.475 25.487 3 3 5 1.542 25.554*

2 6 10 14 18 22 26 30 34 38 42 46 510 54 58 4 1.558* 24.637 3 1.488 22.197 Control Rod Density: % 4.28 2 1.169 18.960 Bottom 1 0.328 5.075 k-effective: 1.00000 Void Fraction: 0.407 9 AXIAL TILT -26.752 -7.822 Core Delta-P: psia 21.961 AVG SOT 8ft/12ft 1.1967 1.0860 Core Plate Delta-P: psia 17. 528 Coolant Temp: Deg-F 543.9 In Channel Flow: Nib/hr 85.42 Active Channel Flow: Nib/hr 81.53 Total Bypass Flow (%): 11.1 (of total core flow)

Total Mater Rod Flow (%): 4.1 (of total core flow)

Source Convergence 0.00042 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLOIGR LHGR Value FT IR JR Value Margin FT IS JR Value Margin Exp. FT IS JR K Value Margin Exp. FT IR JR K 1.548 24 29 38 1.793 0.814 23 23 34 9.10 0.903 24.9 24 31 24 3 10.49 0.905 29.6 24 31 26 3 1.547 24 23 32 1.794 0.814 24 25 32 9.08 0.902 24.8 24 37 30 3 10.27 0.904 31.7 24 31 24 3 1.516 24 29 36 1.795 0.813 24 31 26 8.80 0.883 22.2 23 31 22 3 10.43 0.903 29.8 24 25 32 3 1.514 24 25 32 1.797 0.813 23 33 24 8.78 0.881 22.3 23 39 30 3 10.24 0.902 31.7 24 23 32 3 1.504 23 27 38 1.803 0.810 24 23 32 8.82 0.871 23.0 24 31 26 3 10.04 0.890 32.5 23 33 24 4 1.504 23 23 34 1.804 0.809 24 31 24 8.79 0.869 23.1 24 35 30 3 10.03 0.889 32.5 23 23 34 4 1.501 23 29 40 1.862 0.784 23 31 40 8.47 0.860 26.9 23 27 24 4 12.33 0.875 0.0 26 39 34 4 1.500 23 21 32 1.838 0.783 28 27 36 8.48 0.860 26.8 23 37 28 4 12.33 0.875 0.0 26 33 40 4 1.458 24 25 38 1.864 0.783 23 39 32 8.25 0.833 25.9 23 21 16 9.84 0.861 31.0 23 31 22 4 4

1.449 24 27 34 1.842 0.782 26 35 28 8.22 0.831 26.0 23 45 22 9.69 0.861 32.8 23 39 32 4 tHGR calculated with CPR calculated with pin-power pin-power reconstruction reconstruction 6 CPR limit type 3 Figure A.1 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 0.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-5 Cycle: 24 Core Average Exposure: M~d/MTUJ 20951.2 Exposure: MWd/84TU (GWd) 250.0 ( 31.45 Delta E: MWcI/MTU, (GWd) 250.0 ( 31.45)

Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 9) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.153 3.672 19 0.377 0.642 55 40 Inlet Subcooling: Btu/lb)m -24.74 23 0.280 8.476 20 0.334 0.349 3 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.592 16.425 21 0.456 0.798 53 42 21 0.713 20.048 22 0.711 0.866 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.802 21.960 23 1.322 1.514 27 38 59 59 18 0.850 22.889 24 1.337 1.554 29 38 55 55 18 0.881 22.814 25 1.114 1.300 13 44 51 51 17 0.829 22.826 26 1.301 1.431 27 36 47 ....- 34--------- 20----------34 ....- 47 16 0.960 23.022 27 1.273 1.386 23 36 43 43 15 0.987 23.435 28 1.119 1.387 17 42 39-----------0 -- ....- 10--------- 39 14 1.011 24.041 35------------ 35 13 1.098 23.353 31----------20--------- 12----------20--------- 31 12 1.148 23.742 27------------ 27 11 1.195 24.368 23-----------0 -- ....- 10--------- 23 10 1.239 24.784 19 19 9 1.285 24.935 15 -..-. 34--------- 20----------34 -.... 15 8 1.337 25.416 11 11 7 1.369 25.773 7 7 6 1.423 25.838 3 3 5 1.474 25.921k 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.475* 25.008 3 1.397 22.552 Control Rod Density: % 4 .19 2 1.096 17.239 Bottom 1 0.307 5.154 k-effective: 0.99988 Void Fraction: 0.400 8 AXIAL TILT -22.879 -8.002 Core Delta-P: psia 21.857 AVG HOT 8ft/l2ft 1.1751 1.0869 Core Plate Delta-P: psia 17.424 Coolant Temp: Deg-F 543.8 In Channel Flow: Mlb/hr 85.48 Active Channel Flow: Mlb/hr 81.62 Total Bypass Flow (%): 11.0 (of total core flow)

Total Water Rod Flow (%): 4.0 (of total core flow)

Source Convergence 0.00048 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR C? Value Margin Exp. FT IR C? K Value Margin Exp. FT IR JR K 1.554 24 29 38 1.758 0.831 23 23 34 8.57 0.854 25.5 24 31 24 3 9.58 0.858 33.8 24 31 26 4 1.553 24 23 32 1.761 0.829 23 33 24 8.56 0.853 25.5 24 37 30 3 9.55 0.857 33.9 24 25 32 4 1.523 24 29 36 1.767 0.826 24 25 32 8.25 0.834 26.1 23 31 22 4 9.36 0.857 36.1 24 31 24 4 1.521 24 25 32 1.767 0.826 24 31 26 8.23 0.833 26.2 23 39 30 4 9.34 0.855 36.1 24 23 32 4 1.514 23 27 38 1.799 0.811 24 23 30 8.24 0.828 26.8 24 31 26 4 9.51 0.848 33.2 23 33 24 4 1.514 23 23 34 1.799 0.811 24 29 38 8.22 0.826 26.9 24 35 30 4 9.50 0.847 33.2 23 23 34 4 1.506 23 31 40 1.830 0.798 23 31 40 8.05 0.819 27.5 23 27 24 4 11.63 0.825 0.8 26 39 34 4 1.506 23 21 32 1.832 0.797 23 39 32 8.05 0.818 27.4 23 37 28 4 11.63 0.825 0.8 26 33 40 4 1.470 24 25 36 1.838 0.794 24 28 30 7.83 0.793 26.5 23 21 16 4 9.20 0.821 33.4 23 31 40 4 1.457 24 27 34 1.857 0.786 24 19 34 7.81 0.781 26.6 23 45 22 4 9.19 0.821 33.5 23 39 32

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.2 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 250.0 MWd/IMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-6 Cycle: 24 Core Average Exposure: MWd/MTU 21201.2 Exposure: MWd/MTU (GWd) 500.0 C 62.90)

Delta F: MWd/MTU, (GdM) 250.0 ( 31.45) Axial Profile Edit Radial Power Power: MO~t 2957.0 (100.00 8) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.153 3.706 19 0.372 0.632 55 40 Inlet Subcooling: Btullbm -24 .74 23 0.279 8.551 20 0.328 0.342 3 42 Flow: Mlb/hr 96.04 ( 96.00 8) 22 0.589 16.586 21 0.453 0.790 53 42 21 0.707 20.242 22 0.719 0.960 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.794 22.179 23 1.315 1.513 27 38 59 59 29 0.842 23.122 24 1.346 1.551 29 38 55 55 18 0.874 23.055 25 1.117 1.330 13 44 51 51 17 0.918 23.071 26 1.300 1.437 27 36 47--------------20 47 16 0.942 23.269 27 1.275 1.383 23 36 43 43 15 0.963 23.690 28 1.123 1.391 17 42 39----------10 ... -- 10----------39 14 0.979 24.301 35-------------- 13-~351.059 23.622 31----------20----------16 ... .20----------31 12 1.104 24.023 27-------------- 11-~271.149 24.661 23-----------0 ... -- 10----------23 10 1.194 25.087 19 19 9 1.248 25.247 15--------------20 15 8 1.316 25.735 11 ii 7 1.378 26.099 7 7 6 1.455 26.177 3 3 5 1.526 26.272*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.543" 25.360 3 1.478 22.885 Control Rod Density: % 3.48 2 1.176 17.500 Bottom 1 0.334 5.228 k-effective: 0.99979 Void Fraction: 0.404 8 AXIAL TILT -24.173 -8.131 Core Delta-P: psia 21. 899 AVG BDT Sft/l2ft 1.1777 1.0876 Core Plate Delta-P: psia 17.469 Coolant Temp: Deg-F 543.9 In Channel Flow: Mlb/hr 85.46 Active Channel Flow: Mlb/hr 81.58 Total Bypass Flow (8): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00030 Top Tan Thermal Limits Summary - Sorted hy Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR Value Margin Exp. FT IR JR K K 1.551 24 29 38 1.755 0.832 24 25 32 8.05 0.838 25.9 25 17 14 4 9.32 0.841 34.5 24 31 26 4 1.551 24 23 32 1.755 0.832 24 31 26 8.05 0.837 26.0 25 47 44 9.29 0.839 34.6 24 25 32 4 1.529 24 29 36 1.760 0.830 23 23 34 8.18 0.836 29.3 24 31 24 9.11 0.839 36.7 24 31 24 4 1.527 24 25 32 1.763 0.828 23 33 24 8.17 0.835 29.2 24 37 30 4 9.09 0.837 36.8 24 23 32 4 1.513 23 27 38 1.780 0.820 24 29 30 8.09 0.821 27.0 23 21 16 4 9.28 0.833 33.9 23 33 24 4 1.513 23 23 34 1.790 0.815 24 29 38 8.09 0.820 26.7 23 31 22 9.27 0.832 33.9 23 23 34 4 4

1.501 23 31 40 1.791 0.815 24 23 30 8.06 0.819 27.1 23 45 22 9.10 0.821 34.5 23 39 18 4 4

1.500 23 21 32 1.809 0.796 26 27 36 8.07 0.819 26.8 23 39 30 11.54 0.819 1.5 28 41 18 4 1.472 24 27 34 1.836 0.795 23 31 40 8.04 0.817 28.4 24 17 18 9.06 0.818 34.7 23 17 40 4 1.472 24 25 36 1.838 0.794 23 39 32 8.00 0.812 26.9 23 21 18 11.54 0.818 1.4 28 17 20 4 LHGR calculated with CPR calculated with pin-power pin-power reconstruction reconstruction & CPR limit typa 3 Figure A.3 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 500.0 MWd/MTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-7 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 21701.2 Exposure: M4Wd/MTU (GWd) 1000.0 ( 125.81 Delta E: MWd/MTrJ, (G~d) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: MWt )957.0 (100.00 6) N(PRA) Power Exposure Zone Avg. Max. 1R JR Core Pressure: psia .015.0 Top 24 0.158 3.774 19 0.366 0.623 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.288 8.701 20 0.322 0.336 3 42 Flow: Mlh/hr 96.04 C 98.00 6) 22 0.603 16.906 21 0.446 0.783 7 20 21 0.722 20.627 22 0.711 0.952 13 14 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.809 22.613 23 1.315 1.520 23 28 59 59 19 0.858 23.582 24 1.348 1.549 23 30 55 55 18 0.889 23.534 25 1.110 1.329 13 18 51 51 17 0.933 23.555 26 1.312 1.454 27 26 47--------------20 47 16 Q.956 23.754 27 1.282 1.406 23 26 43 43 15 6.974 24.185 28 1.124 1.408 17 20 39-----------0--------- 10--------- 39 14 0.988 24.805 35---------------- 35 13 1.063 24.141 31----------20----------16 -- ....- 20--------- 31 12 1.104 24.564 27---------------- 27 11 1.145 25.224 23----------12--------- 10--- - 23 10 1.188 25.673 19 19 9 1.240 25.852 15--------------20 15 8 1.305 26.362 ii i1 7 1.365 26.756 7 7 6 1.439 26.870 3 3 5 1.506 26.999k 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.518* 26.095 3 1.453 23.589 control Rod Density: % 3.46 2 1.162 18.060 Bottom 1 0.334 5.388 k-effective: 0. .99969 Void Fraction: 0.401 6 AXIAL TILT -22.992 -8.412 Core Delta-P: psia 21.878 AVG BOT 8ft/l2ft 1.1712 1.0890 Core Plate Delta-P: psia .7.448 Coolant Tamp: Deg-F 543.9 In Channel Flow: Mlb/hr 85.47 Active Channel Flow: Mlb/hr 81.60 Total Bypass Flow (6): 11.0 (of total core flow)

Total Water Rod Flow (6): 4.0 (of total core flow)

Source Convergence 0..00039 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGOR LGHG Value FT 1K JR Value Margin FT IR JR Value Margin Exp. FT 1R JR K Value Margin Exp. FT IR JR K 1.549 24 23 30 1.752 0.833 24 25 32 7.86 0.818 27.0 25 17 14 4 9.01 0.822 35.8 24 31 26 4

1.548 24 29 24 1.7 53 0.833 24 31 26 7.86 0.817 27.1 25 47 44 4 8 .98 0.820 35.9 24 25 32 4

1.528 24 29 26 1.759 0.830 23 23 28 7.94 0.816 30.4 24 31 24 4 8.80 0.819 38.0 24 31 24 4

1.527 24 25 30 1.762 0.829 23 27 24 7.93 0.815 30.4 24 37 30 4 8.78 0.818 38.0 24 23 32 4

1.520 23 23 28 1.773 0.823 24 29 30 7.91 0.807 28.2 23 39 16 4 9.00 0.816 35.2 23 33 24 4

1.519 23 27 24 1.784 0.818 24 23 30 7.89 0.807 29.5 24 43 18 4 8.99 0.615 35.2 23 23 34 1.502 23 21 30 1.786 0.818 24 29 24 7.89 0.805 28.3 23 45 22 4 8.87 0.809 35.8 23 39 18 4

1.501 23 29 22 1.778 0.810 26 27 26 7.89 0.804 27.9 23 31 22 4 8.83 0.807 36.0 23 17 40 4

1.482 24 25 26 1.779 0.810 26 25 28 7.88 0.803 27.9 23 39 30 4 11.37 0.807 2.9 28 19 18 1.477 24 27 28 1.817 0.792 26 21 28 7.83 0.799 28.1 23 39 18 4 11.37 0.806 2.9 28 17 20 LHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.4 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 1,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-8 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 21901.2 Exposure: MWd/MTU (GdM) 1200.0 ( 150.97)

Delts E: MWd/MTU, (GdM) 200.0 ( 25.16) Axial Profile Edit Radial Power Power: M06t 2957.0 (100.00 8) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.158 3.602 19 0.365 0.622 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.289 8.763 20 0.320 0.334 3 42 Flow: Mlb/hr 96.04 ( 96.00 8) 22 0.603 17.037 21 0.444 0.780 53 42 21 0.719 20.784 22 0.709 0.947 13 48 2 6 10 14 18 22 26 30 34 36 42 46 50 54 58 20 0.605 22.790 23 1.314 1.508 27 38 59 59 19 0.852 23.770 24 1.344 1.539 29 38 55 55 16 0.666 23.728 25 1.109 1.324 13 44 51 51 17 0.932 23.752 26 1.316 1.451 27 36 47--------------20 47 16 0.957 23.951 27 1.286 1.394 23 36 43 43 15 0.976 24.386 28 1.127 1.402 17 42 39-----------0 ... 10--------- 39 14 0.990 25.009 35-------------- 35 13 1.064 24.349 31----------20----------16 ....- 20--------- 31 12 1.105 24.761 27-------------- 27 11 1.146 25.449 23----------10 ... 10--------- 23 10 1.188 25.905 19 19 9 1.240 26.092 15--------------20 15 8 1.306 26.611 1i 11 7 1.365 27.016 7 7 6 1.440 27.144 3 3 5 1.507 27.286*

2 6 10 14 18 22 26 30 34 36 42 46 50 54 58 4 1.518* 26.384 3 1.453 23.8666 Control Rod Density: 8 3.48 2 1.166 18.282 Bottom 1 0.336 5.452 k-effective: 0. 99953 Void Fraction: 0.401 8 AXIAL TILT -23.085 -8.510 Core Delta-P: psia 21.884 Avg HOT Sft/l2ft 1.1723 1.0895 Core Plate Delta-P: psia 17.454 Coolant Temp: Deg-F 543.9 In Channel Flow: Mlb/hr 85.47 Active Channel Flow: Nib/hr 81.60 Total Bypass Flow (8): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00039 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGF LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT Value Margin Exp. FT IR JR IR JR K K 1.539 24 29 38 1.766 0.827 24 25 32 7.84 0.815 27.5 25 17 14 4 8.94 0.819 36.3 24 31 26 4 1.539 24 23 32 1.767 0.826 24 31 26 7.83 0.814 27.6 25 47 44 4 8.91 0.817 36.4 24 25 32 4 1.521 24 29 36 1.768 0.826 23 23 34 7.89 0,812 30.9 24 31 24 4 8.73 0.816 38.5 24 31 24 4 1.519 24 25 32 1.772 0,824 23 33 24 7.88 0.811 30.8 24 37 30 4 8.71 0.815 38.5 24 23 32 4 1.508 23 27 38 1.784 0.818 24 29 30 7.87 0.808 29.9 24 17 18 4 8.93 0.814 35.7 23 33 24 4 1,508 23 23 34 1.798 0.812 24 29 38 7.88 0.806 28.6 23 21 16 4 8.93 0.813 35.7 23 23 34 4 1.494 23 29 40 1.799 0.812 24 23 30 7.86 0.804 28.7 23 45 22 4 8.83 0.809 36.3 23 39 18 4 1.494 23 21 32 1.799 0.801 26 27 36 7.86 0.802 28.3 23 31 22 4 11.38 0.807 3.5 28 19 18 4 1.470 24 27 34 1.803 0.799 26 25 28 7.84 0.801 28.4 23 39 30 4 8.79 0.807 36.5 23 17 40 4 1.469 24 25 36 1.848 0.790 23 31 40 7.81 0.798 28.5 23 21 18 4 11.37 0.807 3.5 28 17 20 4 calculated with t HOR calculated with pin-power pin-power reconstruction reconstruction & CPR limit type 3

CPR Figure A.5 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 1,200.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-9 Cycle: 24 Core Average Exposure: M~d/MTU 21902.2 Exposure: MWd/MTU (GWd) 1201.0 ( 151.10)

Delta 5: MWd/MTU, (Gd6) 1.0 C 0.13 Axial Profile Edit Radial Power Power: MO~t 2957.0 (100.00 9) N(PRA) Power Exposure Zone Avg. Max. OR JR Core Pressure: psia 1015.0 Top 24 0.165 3.802 19 0.368 0.618 55 40 Inlet Subcling: Btu/lbm -24 .74 23 0.303 8.764 20 0.319 0.333 57 42 Flow: Mlb/hr 96.04 C 98.00 9) 22 0.633 17.038 21 0.444 0.768 53 42 21 0.759 20.785 22 0.713 0.935 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.852 22.791 23 1.273 1.490 39 36 59 59 19 0.908 23.770 24 1.416 1.541 39 38 55 55 18 0.950 23.729 25 1.096 1.282 47 44 51 51 17 1.009 23.753 26 1.337 1.422 31 28 47----------24--------- 24------- 47 16 1.047 23.952 27 1.245 1.481 37 36 43 43 15 1.077 24.387 28 1.121 1.390 43 42 39----------24-----------0 -- ..... 24--------- 39 14 1.095 25.010 35---------------- 35 13 1.155 24.350 31-----------0--------- -------- 31 12 1.153 24.782 27---------------- 27 11 1.160 25.450 23-------24--------0 -- .....- 24--------- 23 10 1.175 25.907 19 19 9 1.205 26.093 15----------24--------- ------ 15 8 1.251 26.812 11 Ii 7 1.294 27.018 7 7 6 1.353 27.145 3 3 5 1.401* 27.287*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.393 26.386 3 1.317 23.867 Control Rod Density: 9 2 1.044 18.283 4.05 Bottom 1 0.300 5.452 k-effective:0 3.99952 Void Fraction: 0.389 9AXIAL TILT -17.055 -8.510 Core Delta-P: psia 21. 743 AVG BDT 8ft/l2ft 1.1513 1.0895 Core Plate Delta-P: psia 17.311 Coolant Temp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.56 Active Channel Flow: Mlb/hr 81.72 Total Bypass Flow (%): 10. 9 (of total core flow)

Total Water Rod Flow (%): 4.0 (of total core flow)

Source Convergence0 3.00038 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT OR JR K Value Margin Exp. FT OR JR K 1.541 24 39 38 1.765 0.827 23 25 40 7.92 0.809 29.3 24 37 22 4 8.78 0.804 38.3 23 39 26 4 1.540 24 37 40 1.766 0.827 23 39 26 7.91 0.809 29.4 24 39 24 4 8.74 0.802 36.5 24 39 24 4 1.539 24 37 38 1.799 0.812 24 25 36 7.89 0.806 29.3 24 37 24 4 8.75 0.801 36.2 23 25 40 4 1.523 24 39 40 1.811 0.806 24 41 38 7.75 0.792 29.2 24 39 22 8.92 0.801 34.1 23 31 18 4 1.513 24 29 30 1.812 0.806 24 23 24 7.75 0.787 27.0 23 31 16 4 8.70 0.799 36.5 24 23 40 4 1.493 24 35 36 1.814 0.805 24 37 42 7.74 0.786 27.1 23 45 30 8.87 0.798 34.1 23 17 32 4 1.490 23 39 36 1.814 0.805 24 37 30 7.71 0.788 29.0 24 31 30 8.87 0.794 33.6 23 31 16 4 1.489 23 35 40 1.816 0.804 24 29 24 7.54 0.774 29.4 23 35 22 11.16 0.792 3.1 27 25 24 4 1.481 27 37 36 1.817 0.804 24 23 40 7.53 0.773 29.4 23 39 26 8.95 0.791 32.2 24 37 24 3 1.480 24 41 38 1.818 0.803 24 39 24 7.62 0.773 27.0 23 31 18 11.15 0.791 3.1 27 23 26 4

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.6 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 1,201.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-10 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTUT 22201.2 Exposure: MWd/MTU (SWd) 1500.0 (188.71 Delta F: MWd/MTU, (SWd) 299.0 ( 37.62) Axial Profile Edit Radial Power Bower: MWL 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.166 3.846 19 0.365 0.614 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.305 8.861 20 0.317 0.331 3 42 Flow: 14lb/hr 96.04 ( 98.00 8) 22 0.635 27,244 21 0.441 0.766 7 42 21 0.758 21.032 22 0.711 0.933 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.849 23.069 23 1.272 1.487 21 28 59 59 19 0.907 24.067 24 1.411 1.535 23 40

$5 55 18 0.951 24.040 25 1.095 1.282 13 44 51 51 17 1.013 24.071 26 1.342 1.427 19 40 47 ....--24 -- 24------- 47 16 1.053 24.274 27 1.251 1.484 23 36 43 43 15 1.082 24.718 28 1.125 1.397 17 42 39 .. . .24-----------0 .24--------- 39 -.. 14 1.099 25.347 35 35 13 1.158 24.688 01 ....--10 -- 8--------- 31 12 1.154 25.120 27 27 11 1.159 25.790 23 .. . .24----------10 .24--------- 23 -.. 10 1.174 26.251 19 19 9 1.203 26.442 15 ....--24 -- 24------- 15 8 1.249 26.989 1i 11 7 1.292 27.386 7 7 6 1.351 27.530 3 3 5 1.398* 27.687*

2 8 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.388 26.783 3 1.312 24.243 4 .07 2 1.043 18.580 Control Rod Density: %

Bottom 1 0.301 5.538 k-effective: 0.99941 Void Fraction: 0.388 8 AXIAL TILT -16.877 -8.572 Core Delta-F: psia 21. 744 AVG SOT Sft/l2ft 1.1511 1.0899 Core Plate Delta-F: psia 17.312 Coolant Tamp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.56 Active Channel Flow: Mlb/hr 81.73 Total Bypass Flow (8): 10.9 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00032 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLMGR LMGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.535 24 23 40 1.770 0.825 23 25 40 7.80 0.801 30.0 24 37 22 4 8.65 0.798 37.0 23 39 26 4 1.535 24 21 38 1.783 0.819 23 21 26 7.79 0.800 30.0 24 39 24 4 8.81 0.797 34.8 23 31 18 4 1.533 24 23 38 1.801 0.811 24 25 38 7.77 0.798 30.0 24 37 24 4 8.61 0.794 37.0 23 25 40 4 1.518 24 21 40 1.820 0.802 24 23 24 7.65 0.784 29.8 24 39 22 4 8.59 0.794 37.2 24 39 24 4 1.507 24 29 30 1.820 0.802 24 19 38 7.63 0.782 29.7 24 31 30 4 8.77 0.793 34.9 23 17 32 4 1.490 24 25 36 1.795 0.802 26 19 40 7.68 0.782 27.7 23 31 16 4 8.55 0.790 37.2 24 23 40 4 1.487 23 21 26 1.822 0.802 24 23 40 7.866 0.781 27.7 23 45 30 4 8.75 0.789 34.4 23 31 18 4 1.486 23 25 40 1.797 0.801 26 21 42 7.55 0.789 27.8 23 31 18 4 8.71 0.785 34.5 23 15 32 4 1.484 27 23 36 1.822 0.801 24 37 42 7.55 0.768 27.6 23 43 30 4 11.03 0.782 3.9 27 25 24 4 1.483 27 25 24 1.822 0.801 24 23 30 7.46 0.767 30.0 23 35 22 4 11.02 0.782 3.9 27 23 26 4 LHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.7 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 1,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-11 Cycle: 24 Core Average Exposure: MWd/MTU 22701.2 Exposure: MWd/MTU (GWd) 2000.0 ( 251.62)

Delta E: MWd/MTU, (G~d) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 8) NCPRA) Power Exposure Zone Avg. Max. TR JR Core Pressure: psia 1015.0 Top 24 0.168 3.919 19 0.361 0.609 55 40 Inlet Subcooling: Btu/lbms -24 .74 23 0.308 9.025 20 0.312 0.325 57 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.639 17.569 21 0.435 0.760 53 42 21 0.759 21.445 22 0.705 0.925 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.946 23.533 23 1.271 1.477 35 40 59 59 19 0.907 24.563 24 1.404 1.522 37 40 55 55 18 0.954 24.561 25 1.091 1.280 47 44 51 51 17 1.018 24.605 26 1.352 1.434 39 42 47----------24 ... -- 24------- 47 16 1.060 24.816 27 1.261 1.484 35 38 43 43 15 1.089 25.276 28 1.131 1.405 43 42 39-------24--------0 .24--------- 39 -.. 14 1.105 25.913 35-------------- 35 13 1.160 25.256 31-----------8 -.. -- 8--------- 31 12 1.154 25.685 27-------------- 27 11 1.158 26.358 23-------24--------0 .24--------- 23 -.. 10 1.172 26.828 19 19 9 1.200 27.025 15----------24 ... -- 24------- 15 8 1.246 27.564 1i ii 7 1.269 28.002 7 7 6 1.348 28.174 3 3 5 1.394k 28.353*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.380 27.444 3 1.302 24.868 Control Rod Density: % 4 .10 2 1.038 19.078 Bottom 1 0.302 5.683 k-effective: 0. 99922 Void Fraction: 0.387 8 AXTAL TILT -16.520 -8.669 Core Delta-P: psia 21.744 AVG SOT 8ft/l2ft 1.1498 1.0906 Core Plate Delta-P: psia 17.312 Coolant Tamp: Deg-F 543.6 In Channel Flow: Mlb/hr 85.56 Active Channel Flow: Mlb/hr 81.73 Total Bypass Flow (%): 10.9 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00047 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLBGR LEGR Value FT Value Margin FT IR JR Value Margin Exp. FT Value Margin Exp. FT K TR JR IR JR K TR JR 1.522 24 37 40 1.792 0.815 23 25 40 7 .62 0.785 31.1 24 37 22 4 8.64 0.790 36.0 23 31 18 4 1.520 24 39 38 1.803 0.810 23 39 26 7 .62 0.784 31.1 24 39 24 4 8.44 0.787 38.2 23 39 26 4 1.518 24 37 38 1.818 0.803 24 25 36 7.59 0.782 31.1 24 37 24 4 8.60 0.786 36.1 23 17 32 4 1.506 24 39 40 1.797 0.801 26 21 42 7.54 0.775 30.7 24 31 30 4 8.41 0.784 38.2 23 25 40 4 1.498 24 29 30 1.800 0.800 26 19 40 7.56 0.773 28.8 23 31 16 4 8 .37 0.782 38.4 24 39 24 4 1.484 27 35 38 1.828 0.799 24 37 42 7.55 0.772 28.8 23 45 30 4 8.58 0.781 35.6 23 31 16 4 1.481 27 37 36 1.834 0.796 24 41 38 7.49 0.771 30.9 24 39 22 4 8.34 0.779 38.4 24 23 40 4 1.478 24 35 36 1.844 0.792 24 23 40 7.46 0.763 28.7 23 31 18 4 8.53 0.778 35.7 23 15 32 4 1.477 23 35 40 1.845 0.791 24 29 24 7.45 0.762 28.7 23 43 30 4 8.28 0.771 38.1 24 41 24 4 1.473 23 39 36 1.846 0.791 24 39 24 7.33 0.756 31.1 23 35 22 4 8.41 0.768 36.0 24 37 24 4

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.8 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 2,000.0 MWdIMTU AREVA Inc.

Con trolled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-12 Cycle: 24 Core Average Exposure: Mt~d/MTU 23201.6 Exposure: M88d/MTU (G~d) 2500.0 ( 314.52)

Delta E: M~d/MTU, CG~d) 500.0 C 62.90) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 9) MCPRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.172 3.995 19 0.355 0.602 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.315 9.192 20 0.306 0.320 57 42 Flow: Mlb/hr 96.04 ( 98.00 9) 22 0.650 17.939 21 0.429 0.753 53 42 21 0.769 21.861 22 0.698 0.918 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.857 23.999 23 1.270 1.471 35 40 59 59 19 0.916 25.061 24 1.400 1.511 37 40 55 55 18 0.963 25.086 25 1.086 1.277 47 44 51 51 17 1.027 25.144 26 1.364 1.443 31 28 47 -- ...-~24 24----- -- 47 16 1.070 25.364 27 1.270 1.489 35 38 43 43 15 1.098 25.839 28 1.135 1.413 43 42 39 ....- 24--------- 10-------24-- - -- 39 14 1.1i0 26.483 35 -- 35 13 1.161 25.824 31 -- 31 12 1.151 26.250 27 -- 27 11 1.153 26.924 23 ....- 24--------- 10------ - -- 23 10 1.165 27.399 19 19 9 1.193 27.605 15 -- -~24 24----

....- --- 15 8 1.239 28.156 ii ii 7 1.282 28.615 7 6 1.341 28.814 3 3 5 1.386* 29.014*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.368 28.099 3 1.288 25.485 Control Rod Density: 9 4 .10 2 1.028 19.570 Bottom 1 0.300 5.827 k-effective: 0.99918 Void Fraction: 0.384 9 AXIAL TILT -15.777 -8.745 Core Delta-P: psia 21.734 AVO BOT Sft/l2ft 1.1457 1.0912 Core Plate Delta-P: psia 17.302 Coolant Temp: Deg-F 543.6 In Channel Flow: Mlb/hr 85.57 Active Channel Flow: Mlb/hr 81.75 Total Bypass Flow (9): 10.9 (of total core flow)

Total Water Rod Flow (9): 4.0 (of total core flow)

Source Convergence 0.00044 Top Ten Thermal Limits Summary - Sorted by Margin Power M4CPR APLMGR LHRR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.511 24 37 40 1.804 0.809 23 25 40 7.45 0.768 32.2 24 37 22 4 8.46 0.782 37.2 23 31 18 4 1.510 24 39 38 1.815 0.805 23 39 26 7.44 0.768 32.2 24 39 24 8.42 0.778 37.3 23 17 32 4 4

1.507 24 37 38 1.791 0.804 26 21 42 7:44 0.767 31.8 24 31 30 8.22 0.776 39.4 23 39 26 4 4

1.497 24 39 40 1.794 0.803 26 19 40 7.42 0.765 32.2 24 37 24 8.40 0.773 36.8 23 31 16 4 1.494 24 31 32 1.825 0.800 24 25 36 7.43 0.764 29.8 23 31 16 4 8.20 0.773 39.3 23 25 40 4 1,489 27 35 38 1.836 0.795 24 37 42 7.42 0.763 29.8 23 45 30 4 8.16 0.770 39.5 24 39 24 4 1.486 27 37 36 1.842 0.793 24 41 38 7.34 0.757 32.0 24 39 22 4 8.35 0.769 36.8 23 15 32 4 1.472 24 35 36 1.856 0.786 24 29 24 7.35 0.756 29.8 23 31 18 8.12 0.767 39.6 24 23 40 4 4

1.471 23 35 40 1.857 0.786 24 23 40 7.35 0.755 29.7 23 43 30 8.07 0.760 39.2 24 41 24 4 1.467 23 39 36 1.860 0.785 24 39 24 7.20 0.744 32.1 23 35 22 8.32 0.758 35.7 24 31 30 4

IHOR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.9 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 2,500.0 MWd/MTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-13 Cycle: 24 Core Average Exposure: M~d/MTU 23701.7 Exposure: M~d/MTU (G~d) 3000.0 ( 377.42)

Delta E: M~d/MTU, (GWd) 500.0 ( 62.90 Axial Prof ile Edit Radial Power Power: MWC 2957.0 (100.00 %) NM(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.175 4.072 19 0.350 0.595 55 40 Inlet Subcooling: Btuflbm -24 .74 23 0.320 9.363 20 0.301 0.314 57 42 Flow: Mlb/hr 96.04 C 98.00 8) 22 0.659 18.295 21 0.423 0.747 53 42 21 0.777 22.283 22 0.692 0.910 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.883 24.469 23 1.269 1.465 35 40 59 59 19 0.921 25.563 24 1.395 1.500 37 40 55 55 18 0.969 25.614 25 1.081 1.274 47 44 51 51 17 1.034 25.688 26 1.375 1.453 31 28 47 24 ....- -- 24------- 47 16 1.077 25.917 27 1.279 1.493 35 38 43 43 15 1.104 28.405 28 1.140 1.420 43 42 39 -- ....- 24 -- ....- 10 .24--------- 39 -.. 14 1.113 27.055 35 - 35 13 1.161 28.393 31 - 8 ....- -- 8--------- 31 12 1.149 26.813 27 - 27 11 1.149 27.488 23 -- ....- 24 -- ....- 10 .24--------- 23 -.. 10 1.160 27.969 19 19 9 1.187 28.182 15 24 ....- -- 24------- 15 8 1.233 28.745 ii ii 7 1.276 29.224 7 7 8 1.338 29.452 3 3 5 1.381* 29.673*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.360 28.749 3 1.277 26.096 4 .10 2 1.019 20.057 Control Rod Density: 9 Bottom 1 0.299 5.971 k-effective: 0.99907 Void Fraction: 0.382 9AXIAL TILT -15.231 -8.805 Core Delta-P: psia 21.729 AVG SOT 8ft/l2ft 1.1426 1.0918 Core Plate Delta-P: psia 17.297 Coolant Tamp: Deg-F 543.6 In Channel Flow: Mlb/hr 85.58 Active Channel Flow: Mlb/hr 81.76 Total Bypass Flow (%): 10.9 (of total core flow)

Total Water Rod Flow (%): 4.0 (of total core flow)

Source Convergence 0.00047 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value Margin Exp. Value Margin Exp. FT IR JR K Value FT IR JR Value Margin FT IR 3JR FT IR JR K 1 .500 24 37 40 1.788 0.805 26 21 42 7.34 0.759 32.8 24 31 30 8.32 0.777 38.4 23 31 18 4 1.499 24 39 38 1.791 0.804 26 19 40 7.34 0.757 30.9 23 31 16 8.27 0.773 38.4 23 17 32 4 4

1.496 24 37 38 1.818 0.803 23 25 40 7.33 0.756 30.9 23 45 30 8.25 0.787 37.9 23 31 16 4 1.493 27 35 38 1.828 0.798 23 39 26 7.28 0.753 33.2 24 37 22 4 8.02 0.765 40.5 23 39 26 4 1.490 27 37 36 1.834 0.796 24 25 36 7.28 0.752 33.2 24 39 24 4 8.21 0.764 38.0 23 15 32 4

1. 488 24 31 32 1.84 6 0.791 24 37 42 7.28 0.750 30.8 23 31 18 8.00 0.762 40.5 23 25 40 4 4

1.488 24 39 40 1.852 0.788 24 41 38 7.25 0.750 33.2 24 37 24 7.95 0.758 40.6 24 39 24 4 4

1.466 24 35 36 1.838 0.783 26 27 36 7.27 0.750 30.8 23 43 30 7.92 0.755 40.7 24 23 40 4

1. 465 23 35 40 1.839 0.783 26 35 28 7.19 0.743 33.0 24 39 22 8.18 0.753 36.8 24 31 30 4 1.460 23 39 36 1.840 0.783 26 35 20 7.11 0.735 32.5 23 31 14 7.88 0.750 40.4 24 41 24 4

LHGR calculated with pin-power reconstruction & CPR

CPR calculated with pin-power reconstruction limit type 3 Figure A.1O Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 3,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-14 Cycle: 24 Core Average Exposure: M~d/MTU 24201.2 Exposure: M~d/MTUT CGWd) 3500.0 C 440.33 Delta E: MWd/MTU, (OP~d) 500.0 C 62.80) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 6) M)PRA) Power Exposure Zone Avg. Max. OR JR Core Pressure: psia 1015.0 Top 24 0.176 4.150 19 0.346 0.590 55 40 Inlet Subcooling: Etu/ibm -24 .74 23 0.321 9.535 20 0.297 0.310 57 42 Flow: Mlb/hr 86.04 C 98.00 8) 22 0.660 19.654 21 0.417 0.742 53 42 21 0.775 22.706 22 0.687 0.903 13 14 2 6 10 14 19 22 26 30 34 39 42 46 50 54 59 20 0.858 24.940 23 1.267 1.458 35 22 59 59 19 0.919 26.067 24 1.397 1.489 37 22 55 55 19 0.967 26.144 25 1.077 1.272 47 44 51 51 17 1.035 26.233 26 1.396 1.462 31 29 47 -~24--------- 24 47 16 1.090 26.472 27 1.299 1.498 25 24 43 43 15 1.109 26.974 29 1.147 1.428 43 20 39 .. . .24------------ -- -- 24--------- 39 14 1.115 27.629 35 35 13 1.160 26.962 31 9--------- 8 31 12 1.147 27.376 27 27 11 1.147 29.051 23 .. . .24-------10 -- 24--------- 23 10 1.158 29.537 19 19 9 1.196 29.757 15 -~24-------- 24 15 9 1.232 29.332 11 11 7 1.277 29.932 7 7 6 1.341 30.0899 3 3 5 1.395k 30.331*

2 6 10 14 19 22 26 30 34 38 42 46 50 54 59 4 1.361 29.397 3 1.276 26.704 4 .12 2 1.017 20.543 Control Rod Density: %

Bottom 1 0.300 6.114 k-effective: 0.99977 Void Fraction: 0.382 9 AXIAL TILT -15.213 -8.956 Core Delta-P: psia 21.738 AVG SOT 8ft/l2ft 1.: 1431 1.0922 Core Plate Delta-P: psia 17.306 Coolant Temp: Deg-F 543.5 In Channel Flow: Mlb/hr 85.59 Active Channel Flow: Mlb/hr 91.76 Total Bypass Flow (9): 10.9 (of total core flow)

Total Water Rod Flow (9): 4.0 (of total core flow)

Source Convergence 0.00041 Top Ten Thermal Limits Summary - Sorted by Margin Power O4CPR APLHGR LHGR Value FT OR JR Value Margin FT OR JR Value Margin Exp. FT OR JR Value Margin Exp. FT OR JR K K 1.498 27 25 24 1.798 0.805 26 39 20 7.28 0.754 33.9 24 31 30 9.22 0.776 39.6 23 31 18 1.494 27 23 26 1.790 0.804 26 41 22 7.29 0.753 31.9 23 31 16 4

9.19 0.772 39.6 23 17 32 1.499 24 37 22 1.944 0.792 23 39 26 7.28 0.752 31.9 23 45 30 4 4 9.15 0.766 39.1 23 31 16 1.497 24 39 24 1.949 0.790 23 25 22 7.24 0.749 31.8 23 31 19 4

4 8.11 0.763 39.1 23 15 32 1.494 24 37 24 1.952 0.788 24 35 26 7.24 0.748 31.9 23 43 30 4

7.86 0.757 41.6 23 39 26 1.490 24 29 30 1.833 0.786 26 35 20 7.15 0.741 34.2 24 37 22 0.755 41.6 23 25 4

4 7.94 40 1.478 24 39 22 1.963 0.794 24 37 20 7.15 0.741 34.2 24 39 24 7.95 0.753 41.2 24 31 32 5 1.462 26 31 29 1.839 0.793 26 35 28 7.12 0.738 34.2 24 37 24 7.78 0.750 41.7 24 39 24 1.461 26 39 20 1.842 0.782 26 27 26 7.09 0.734 33.5 23 31 14 7.75 0.748 41.8 24 23 40 1.460 26 41 22 1.867 0.782 24 41 38 7.08 0.733 34.0 24 39 22 7.77 0.744 41.1 23 47 34

~ tHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.11 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 3,500.0 MWd/MTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-15 Cycle: 24 Core Average Exposure: M~d/MTU 24526.7 Exposure: MWd/MTU (O~d) 3825.0 ( 481.22)

Delta E: MWd/MTU, (G~d) 325.0 ( 40.89) Axial Profile Edit Radial Power Power: M{Wt 2957.0 (100.00 %) M(PPA) Power Exposure Zone Avg. Max. ZR JR Core Pressure: psia 1015.0 Top 24 0.178 4.201 19 0.343 0.586 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.324 9.648 20 0.293 0.306 57 42 Flow: Mlb/hr 96.04 ( 98.00 6) 22 0.664 18.888 21 0.413 0.737 53 42 21 0.778 22.981 22 0.683 0.898 13 14 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.860 25.245 23 1.266 1.453 35 22 59 59 19 0.920 26.393 24 1.384 1.482 37 22 55 55 18 0.969 26.489 25 1.074 1.270 47 44 51 51 17 1.037 26.588 26 1.393 1.468 31 28 47 -~24 .24------ - -.. 47 16 1.084 26.834 27 1.295 1.500 25 24 43 43 15 1.110 27.345 28 1.150 1.433 43 20 39 . 24 .. ..--.. -- 8----------24--------- 39 14 1.117 28.002 35 35 13 1.160 27.331 31 8 .. . 8--------- 31 12 1.145 27.741 27 27 11 1.144 28.416 23 . 24 .. ..--.. -- 10----------24--------- 23 10 1.155 28.906 19 19 9 1.182 29.130 15 -~24 .24------ - -.. 15 8 1.229 29.714 ii 11 7 1.275 30.228 7 7 6 1.341 30.505 3 3 5 1.385" 30.760*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.359 29.819 3 1.272 27.099 Control Rod Density: 6 4.12 2 1.012 20.857 Bottom 1 0.299 6.208 k-effective: 0.99872 Void Fraction: 0.381 6 AXIAL TILT -14.993 -8.887 Core Oelta-P: psia 21.738 AVG BOT eft/l2ft 1.1419 1.0925 Core Plate Delta-P: psia 17.306 Coolant Tamp: Deg-F 543.5 In Channel Flow: Mlb/hr 85.58 Active Channel Flow: Mlb/hr 81.77 Total Bypass Flow (%): 10.9 (of total core flow)

Total Water Rod Flow (6): 4.0 (of total core flow)

Source Convergence 0.00042 Top Ten Thermal Limits Summnary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR OR Value Margin FT IR JR Value Margin Exp. FT ZR OR K Value Margin Exp. FT ZR OR K 1.500 27 25 24 1.788 0.805 26 39 20 7.23 0.750 34.5 24 31 30 4 8.13 0.773 40.3 23 31 18 1.496 27 23 26 1.791 0.804 26 41 22 7.23 0.748 32.6 23 31 16 4 8.09 0.769 40.3 23 17 32 4

1.482 24 37 22 1.855 0.787 23 39 26 7.22 0.747 32.6 23 45 30 4 8.06 0.763 39.8 23 31 16 5

1.480 24 39 24 1.830 0.787 26 35 20 7.20 0.745 32.5 23 31 18 4 8.02 0.760 39.8 23 15 32 4

1.477 24 37 24 1.859 0.785 23 25 22 7.19 0.744 32.5 23 43 30 4 7.81 0.754 41.9 24 31 32 1.476 24 29 30 7.75 4

1.860 0.785 24 35 26 7.06 0.732 34.9 24 37 22 4 0.751 42.3 23 39 26 5

1.471 24 39 22 1.838 0.783 26 35 28 7.05 0.732 34.9 24 39 24 4 7.72 0.748 42.3 23 25 40 7.61 0.745 43.4 23 47 34 4

1.468 26 31 28 1.841 0.782 26 27 26 7.04 0.731 34.1 23 31 14 4 4

1.466 26 39 20 1.842 0.782 26 31 28 7.03 0.730 34.8 24 37 24 4 7.67 0.744 42.4 24 39 24 1.465 26 41 22 1.842 0.782 26 19 26 7 .02 0.729 34.2 23 47 30 4 7.60 0.743 43.3 23 33 48

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.12 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 3,825.0 MWd/MTU AREVA Inc.

Cont'rofled Documernt ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-16 Cycle:' 24 Core Average Exposure: M~d/MTU 24527.2 Exposure: MWd/MTU (034d) 3826.0 3 481.34)

Delta E: M~d/MTU, (GWd) 1.0 ( 0.13 Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 9) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.168 4.201 19 0.340 0.590 55 40 Inlet Subcooling: Btu/ibm -24 .74 23 0.305 9.649 20 0.294 0.307 3 42 Flow: Mlb/hr 96.04 ( 98.00 9) 22 0.624 28.888 21 0.414 0.749 53 42 21 0.729 22.981 22 0.680 0.910 13 48 2 6 10 14 18 22 26 3( ) 34 38 42 46 50 54 58 20 0.803 25.246 23 1.311 1.476 21 32 59- 59 19 0.846 26.394 24 1.308 1.493 23 32 55-------------- 55 18 0.882 26.490 25 1.086 1.311 47 44 51 51 17 0.937 26.589 26 1.370 1.466 27 36 47 20 -- 47 16 0.974 26.835 27 1.336 1.408 23 36 43-------------- 43 15 0.994 27.346 28 1.157 1.449 17 42 39-----------0 ... - -- 10 -- 39 14 1.000 28.003 35-------------- -- 35 13 1.061 27.333 31----------20--------- 8 ....- 20 ....- -- 31 12 1.094 27.743 27-------------- -- 27 11 1.129 28.417 23----------10 ... - -- 10 -- 23 10 1.169 28.907 19 19 9 1.222 29.131 15 20 - 15 8 1.289 29.715 11 1i 7 1.356 30.229 7 7 6 1.441 30.506 3 3 5 l.510" 30.762*

2 6 10 14 18 22 26 3!0 34 38 42 48 50 54 58 4 1.509 29.820 3 1.442 27.100 control Rod Density: 9 2 1.167 20.856 3.58 Bottom 1 0.348 6.208 k-effective: 0.99864 Void Fraction: 0.395 % AXIAL TILT -22.299 -8.687 Core Delta-F: psia 21.909 AVG BOT 8ft/12ft 1.1691 1.0925 Core Plate Delta-F: psia 17.478 Coolant Tamp: Deg-F 543.8 In Channel Flow: Mlb/hr 65.48 Active Channel Flow: Mlb/hr 81.62 Total Bypass Flow (8): 22.0 (of total core flow)

Total Water Rod Flow (6): 4.0 (of total core flow)

Source Convergence 0.00028 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APIHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT XR JR K 1.493 24 23 32 1.848 0.790 23 23 34 7.83 0.809 31.8 23 21 16 4 8.73 0.817 38.7 23 39 16 4

1.492 24 29 38 1.655 0.787 23 33 24 7.81 0.807 31.9 23 45 22 4 8.69 0,815 38.8 23 15 40 1.476 23 21 32 1.873 0.780 24 19 34 7.68 0.795 31.8 23 31 22 8.48 0,812 40.9 23 39 18 4

1.476 23 29 40 1.881 0.776 24 33 20 7.68 0.793 31.9 23 39 30 8.45 0,809 41.1 23 17 40 4

1.466 26 27 36 1.6863 0.773 26 21 34 7.63 0.792 34.8 24 43 18 8.52 0.600 38.9 23 31 40 4

1.465 26 25 34 1.864 0.773 26 27 36 7.56 0.784 33.3 23 21 18 8.52 0.800 39.0 23 39 32 4

1.462 26 27 40 1.664 0.772 26 27 40 7.56 0.783 32.8 23 39 14 8.32 0.800 41.4 23 23 16 1.462 26 21 34 1.893 0.771 24 25 32 7.55 0.782 33.5 23 43 22 8.38 0,799 40.6 23 47 40 1.459 23 23 34 1.867 0.771 26 19 32 7.54 0.781 34.4 24 31 24 8.39 0.799 40.5 23 39 48 1.458 23 27 38 1.668 0.771 26 29 42 7.53 0.781 33.9 23 37 16 11.25 0.798 10.1 28 19 18

tHOR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.13 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 3,826.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-17 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 24701.7 Exposure: MWd/MTTU (G~d) 4000.0 ( 503.23)

Delta E: MWd/MTU, (G~d) 174.0 ( 21.89) Axial Profile Edit Radial Power Power: MWr 2957.0 (100.00 8) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.168 4.227 19 0.338 0.587 55 40 Inlet Subcooling: Btullbm -24.74 23 0.307 9.706 20 0.292 0.306 3 42 Flow: Mlb/hr 96.04 ( 98.00 8) 22 0.627 18.007 21 0.412 0.747 53 42 21 0.731 23.120 22 0.677 0.907 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.804 25.399 23 1.311 1.474 21 32 59 59 19 0.847 26.556 24 1.307 1.490 23 32 55 55 18 0.884 26.658 25 1.084 1.309 47 44 51 -- 51 17 0.939 26.761 26 1.375 1.469 27 36 47 20------- - -- 47 16 0.976 27.010 27 1.339 1.410 23 36 43 43 15 0.996 27.524 28 1.159 1.451 17 42 39 - 14 1.001 28.182

-39 35 - 2-.. . . -10 13 1.061 27.514

-35 31 -- 8----------20 . 31 12 1.093 27.929 27 - 11 1.128 28.610

-27 23 - -- -1i0 10 1.168 29.106

-23 19 - -- 19 9 1.220 29.337 15 20------- 15 8 1.288 29.928 ii -- i1 7 1.354 30.454 7 7 6 1.441 30.745 3 5 1.509* 31.012" 3

2 6 10 14 18 22 26 30 34 36 42 46 50 54 58 4 1.508 30.070 3 1.439 27.339 Control Rod Density: 8 3.58 2 1.164 21.051 Bottom 1 0.347 6.2866 k-effective: 0.99857 Void Fraction: 0.395 8 AXIATL TILT -22.166 -8.954 Core Delta-P: psia 21.909 AVG BOT 8ft/l2ft 1.1683 1.0928 Core Plate Delta-P: psia 17.478 Coolant Tamp: Deg-F 543.8 In Channel Flow: Mlb/hr 85.48 Active Channel Flow: Mlb/hr 81.62 Total Bypass Flow (8): 11.0 (of total core flow)

Total Water Rod Flow (%): 4.0 (of total core flow)

Source Convergence 0.00028 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLBGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.490 24 23 32 1.851 0.789 23 23 34 7.79 0.806 32.2 23 21 16 4 8.67 0.815 39.1 23 39 16 4 1.489 24 29 38 1.858 0.786 23 33 24 7.77 0.804 32.3 23 45 22 4 8.63 0.812 39.2 23 15 40 4 1.474 23 21 32 1.873 0.779 24 19 34 7.64 0.790 32.2 23 31 22 4 8.44 0.811 41.4 23 39 18 4 1.473 23 29 40 1.881 0.776 24 27 42 7.61 0.790 35.2 24 43 19 4 8.40 0.808 41.5 23 17 40 4 1.469 26 27 36 1.860 0.774 26 21 34 7 .63 0.789 32.3 23 39 30 4 8.47 0.798 39.4 23 31 40 4 1.468 26 25 34 1.862 0.773 26 27 40 7.53 0.781 33.7 23 21 18 4 8.46 0.798 39.4 23 39 32 4 1.466 26 27 40 1.862 0.773 26 27 36 7.53 0.781 33.2 23 39 14 4 8.33 0.798 41.0 23 47 40 4 1.466 26 21 34 1.865 0.772 26 19 32 7.52 0.780 33.8 23 43 22 4 8.34 0.798 40.9 23 39 48 4 1.456 23 23 34 1.865 0.772 26 29 42 7.49 0.778 34.3 23 37 16 4 8.27 0.798 41.8 23 23 16 4 1.456 23 27 38 1.868 0.771 26 35 34 7.51 0.778 33.3 23 47 22 4 11.23 0.797 10.7 28 19 18 4

LBGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.14 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 4,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-l8 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTUJ 25201.7 Exposure: MWd/MTU CG~qd) 4500.0 ( 566.14)

Delta E: MWd/MTU, (GWd) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 8) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.170 4.302 19 0.334 0.581 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.310 9.872 20 0.288 0.301 3 42 Flow: Mlb/hr 96.04 ( 98.00 8) 22 0.633 19.349 21 0.407 0.741 53 42 21 0.736 23.519 22 0.672 0.900 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.808 25.840 23 1.308 1.462 21 32 59 59 19 0.852 27.020 24 1.302 1.473 23 32 55 55 18 0.889 27.143 25 1.079 1.306 47 44 51 51 17 0.945 27.258 26 1.385 1.473 27 36 47 -~20 47 16 0.983 27.514 27 1.348 1.414 23 36 43 43 15 1.003 28.039 28 1.164 1.459 17 42 39 -10

-.... 10--------- 39 14 1.006 28.699 35 35 13 1.064 28.034 31 S20-------8 ....- 20--------- 31 12 1.093 28.465 27 27 11 1.126 29.162 23 -10

-.... 10--------- 23 10 1.165 29.678 19 19 9 1.216 29.927 15 -~20 15 8 1.284 30.541 11 11 7 1.351 31.098 7 7 6 1.439 31.431 3 3 5 1.507* 31.730*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.500 30.787 3 1.426 28.022 Control Rod Density: 8 3.58 2 1.150 21.603 Bottom 1 0.343 6.431 k-effective: 0.99851 Void Fraction: 0.393 8 AXIAL TILT -21.664 -9.134 Core Delta-F: psia 21. 904 AVG HOT Sft/12ft 1.1660 1.0937 Core Plate Delta-F: psia 17.474 Coolant Temp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.48 Active Channel Flow: Mlb/hr 81.63 Total Bypass Flow (8): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00029 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHG* LHGR Value FT IR JR Value Margin FT IL JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.473 24 23 32 1.869 0.781 23 23 34 7.67 0.795 33.3 23 21 16 8.49 0.807 40.3 23 39 16 4

1.473 26 27 36 1.876 0.778 23 33 24 7.65 0.793 33.4 23 45 22 8.46 0.805 40.4 23 15 40 4 4

1.473 26 25 34 1.881 0.776 24 19 34 7.54 0.785 36.3 24 43 18 8.29 0.805 42.5 23 39 18 4 4

1.473 24 29 38 1.859 0.775 26 21 34 9.08 0.776 9.5 28 41 18 8.25 0.802 42.6 23 17 40 4 4

1.472 26 27 40 1.860 0.774 26 27 40 9.07 0.775 9.5 28 43 20 8.31 0.796 41.0 24 17 18 4 4

1.472 26 21 34 1.889 0.773 24 27 42 7.47 0.774 33.2 23 31 22 8.20 0.794 42.2 23 47 40 4 4

1.462 26 29 42 1.863 0.773 26 19 32 7.43 0.773 34.8 23 21 18 8.21 0.794 42.0 23 39 48 4 4

1.462 26 19 32 1.864 0.773 26 29 42 7.46 0.773 33.3 23 39 30 11.16 0.791 12.1 28 19 18 4 4

1.462 23 21 32 1.865 0.772 26 27 36 7.42 0.772 34.9 23 43 22 8.11 0.791 43.0 23 23 16 4 4

1.461 23 29 40 1.870 0.770 26 35 28 7.43 0.771 34.2 23 39 14 11.16 0.791 12.1 28 17 20

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.15 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 4,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-19 Cycle: 24 Core Average Exposure: MWd/MTUJ 25701.2 Exposure: MWd/MTUJ (GWd) 5000.0 ( 629.04)

Delta F: M~d/MTU, (G~d) 500.0 ( 62.90 Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. ZR JR Core Pressure: psia 1015.0 Top 24 0.171 4.378 19 0.330 0.577 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.311 10.039 20 0.284 0.297 3 42 Flow: Mlb/hr 96.04 ( 98.00 9) 22 0.633 19.693 21 0.402 0.737 53 42 21 0.734 23.920 22 0.668 0.895 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.807 26.281 23 1.304 1.447 21 32 59 59 19 0.852 27.486 24 1.293 1.453 23 32 55 55 18 0.890 27.630 25 1.077 1.305 13 44 51 51 17 0.948 27.756 26 1.394 1.475 27 40 47--------------20 47 16 0.988 28.020 27 1.359 1.424 15 36 43 43 15 1.008 28.556 28 1.172 1.469 17 42 39-----------0 ... 10--------- 39 14 1.010 29.217 35-------------- 35 13 1.064 28.555 31-------20-------6 ....- 20--------- 31 12 1.092 29.000 27 27 11 1.123 29.714 23----------10 ... 10--------- 23 10 1.161 30.248 19 19 9 1.213 30.516 15--------------20 15 8 1.282 31.153 11 1i 7 1.351 31.742 7 7 6 1.442 32.116 3 3 5 1.510* 32.448*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.500 31.502 3 1.424 28.701 Control Rod Density: % 3.60 2 1.145 22.151 Bottom 1 0.343 6.596 k-effective: 0.99834 Void Fraction: 0.392 9 AXIAL TILT -21.542 -9.302 Core Delta-P: psia 21. 910 AVG BOT eft/l2ft 1.1659 1.0945 Core Plate Delta-P: psia 17.480 Coolant Temp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.48 Active Channel Flow: Mlb/hr 81.63 Total Bypass Flow (9): 11.0 (of total core flow)

Total Water Rod Flow (9): 4.0 (of total core flow)

Source Convergence 0.00041 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGI LHGR Value FT IR JR Value Margin FT OR JR Value Margin Exp. FT Value Margin Exp. FT IR JR IR JR K K 1.475 26 27 40 1.865 0.772 26 19 32 7.59 0.789 34.4 23 21 16 4 8.37 0.805 41.4 23 39 16 4 1.475 26 21 34 1.866 0.772 26 29 42 7.58 0.787 34.5 23 45 22 4 8.18 0.803 43.7 23 39 18 4 1.471 26 27 36 1.894 0.771 23 23 34 7.52 0.784 37.3 24 43 18 4 8.34 0.802 41.6 23 15 40 4 1.471 26 25 34 1.894 0.771 24 19 34 9.14 0.781 10.6 28 41 18 4 8.15 0.801 43.8 23 17 40 4 1.469 28 17 42 1.869 0.770 26 21 34 9.14 0.781 10.6 28 43 20 4 8.27 0.800 42.1 24 17 18 4 1.469 26 19 32 1.871 0.770 26 27 40 9.09 0.777 9.9 26 41 18 5 8.13 0.796 43.3 23 47 40 4 1.469 26 29 42 1.901 0.768 23 33 24 9.09 0.777 9.9 26 45 20 5 8.14 0.796 43.1 23 39 48 4 1.468 28 19 44 1.902 0.767 24 27 42 7.38 0.769 35.8 23 21 18 4 11.17 0.792 13.4 28 19 18 4 1.453 24 23 32 1.880 0.766 26 27 36 7.38 0.768 35.3 23 39 14 4 11.16 0.791 13.3 28 17 20 4 1.452 24 29 38 1.885 0.764 26 35 34 7.36 0.767 35.9 23 43 22 4 8.01 0.790 44.1 23 23 16 4

LHGR calculated calculated with with pin-power pin-power reconstruction reconstruction & CPR limit

CPR type 3 Figure A.16 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 5,000.0 MWd/MTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-20 Cycle: 24 Core Average Exposure: EP~d/ETU 26201.2 Exposure: M~d/MTU (G~d) 5500.0 C 691.94 Delta F: M~d/MTU, CG~d) 500.0 C 62.90) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 8) MCPRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.166 4.453 19 0.328 0.573 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.303 10.206 20 0.281 0.294 3 42 Flow: Mlb/hr 96.04 ( 98.00 8) 22 0.618 20.037 21 0.399 0.735 7 42 21 0.717 24.320 22 0.666 0.893 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.789 26.723 23 1.300 1.431 21 32 59 59 19 0.839 27.952 24 1.278 1.431 23 32 55 55 18 0.881 28.117 25 1.076 1.309 13 44 51 - 51 17 0.943 28.256 26 1.401 1.478 21 34 47--------------20 - - - 47 16 0.986 28.529 27 1.371 1.440 15 36 43 - - 43 15 1.009 29.075 28 1.183 1.483 17 42 39-----------0----------- - 14 1.012 29.737

-39 35------------------- 13 1.065 29.077

-35 31----------20-----------0 -... - 20 - 31 12 1.092 29.535 27------------------- 11 1.124 30.264

-27 23-----------8----------1 - 10 1.162 30.818

-23 19 - - 19 9 1.215 31.104 15--------------20 - - - 15 8 1.286 31.764 i1 - 1 7 1.359 32.386 7 7 6 1.455 32.803 3 3 5 1.526* 33.167*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.515 32.216 3 1.437 29.380 3.72 2 1.155 22.697 Control Rod Density: 8 Bottom 1 0.347 6.761 k-effective: 0. 99792 Void Fraction: 0.393 8 AXIAL TILT -22,265 -9.462 Core Delta-F: psia 21, 938 AVG DOT Sft/l2ft 1.1715 1.0954 Core Plate Delta-P: psia 17.507 Coolant Temp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.47 Active Channel Flow: Mlb/hr 81.62 Total Bypass Flow (8): 11.0 (of total core flow)

Total Water Rod Flow (6): 4.0 (of total core flow)

Source Convergence 0.00040 Top Ten Thermal Limits summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.483 28 17 42 1.873 0.769 26 19 32 9.30 0.794 11.0 26 19 16 5 8.30 0,812 43.3 24 17 18 1.482 28 19 44 1.874 0.768 26 29 42 9.29 0.794 11.1 26 45 42 5 8.29 0.810 43.2 23 39 16 1.478 26 21 34 1.912 0.763 24 19 34 9.29 0.794 11.8 28 19 18 4 8.15 0.809 44.8 23 39 18 1.478 26 27 40 1.887 0.763 26 21 34 9.28 0.793 11.8 28 43 20 4 8.25 0.808 43.3 23 15 40 1.475 26 19 32 1.887 0.763 26 27 40 7.59 0.791 35.4 23 21 16 4 8.12 0.807 44.9 23 17 40 1.475 26 29 42 1.920 0.760 24 27 42 7.56 0.790 38.4 24 43 18 4 8.14 0.805 44.4 23 47 40 1.468 26 27 36 1.923 0.759 23 23 34 7.57 0.788 35.6 23 45 22 4 8.15 0.805 44.3 23 39 48 1.467 26 25 34 1.897 0.759 26 27 36 9.11 0.779 11.2 27 17 16 4 11.27 0.799 14.8 28 19 18 1.446 26 17 38 1.903 0.757 26 35 28 9.11 0.779 11.3 27 45 18 4 11.27 0.799 14.8 28 17 20 1.446 26 23 44 1.929 0.757 23 33 24 7.41 0.773 36.3 23 21 14 4 7.98 0.795 45.2 23 23 16

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.17 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 5,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-21 Cycle: 24 Core Average Exposure: M~d/MTU 26701.2 Exposure: MWd/MTIY CG~d) 6000.0 ( 754.85 Delta E: M~d/MTUJ, (B~d) 500.0 ( 62.90 Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.165 4.527 19 0.324 0.570 55 40 Inlet Subcooling: Htu/ibm -24 .74 23 0.300 10.369 20 0.277 0.290 3 42 Flow: Mlh/hr 96.04 ( 98.00 9) 22 0.612 20.373 21 0.395 0.731 7 42 21 0.708 24.711 22 0.662 0.886 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.776 27.154 23 1.295 1.415 21 32 59 59 19 0.830 28.410 24 1.267 1.410 23 32 55 55 18 0.876 28.599 25 1.074 1.306 13 44 51 51 17 0.940 28.753 26 1.409 1.479 19 32 47 -~20 47 16 0.986 29.037 27 1.383 1.451 15 36 43 43 15 1.010 29.594 28 1.192 1.487 17 42 39 8 ....- -- 8--------- 39 14 1.013 30.258 35 35 13 1.064 29.599 31 .. . .20-----------0 .20--------- 31 -.. 12 1.090 30.070 27 27 11 1.121 30.815 23 8 ....- -- 8--------- 23 10 1.160 31.387 19 19 9 1.214 31.693 15 -~20 15 8 1.287 32.377 1i 1i 7 1.363 33.033 7 7 6 1.465 33.496 3 3 5 1.539" 33.894a 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.527 32.938 3 1.446 30.065 Control Rod Density: 8 3.77 2 1.160 23.247 Hottom 1 0.349 6.927 k-effective: 0. 99770 Void Fraction: 0.393 8 AXIAL TILT -22.659 -9.629 Core Delta-?: psia 21. 958 AVG HOT 8ft/l2ft 1.1745 1.0962 Core Plate Delta-?: psia 17. 527 Coolant Temp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.47 Active Channel Flow: Mlb/hr 81.61 Total Bypass Flow (8): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total cora flow)

Source Convergence 0. 00038 Top Ten Thermal Limits Summsary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.487 28 17 42 1.880 0.766 26 19 32 9.49 0.811 12.3 26 41 16 5 8.31 0.822 44.4 24 17 18 4 1.487 28 19 44 1.881 0.765 26 29 42 9.49 0.811 12.3 26 45 20 5 8.28 0.818 44.3 23 39 16 4 1.479 26 19 32 1.936 0.754 24 19 34 9.42 0.805 13.0 28 41 18 4 8.24 0.816 44.4 23 15 40 4 1.479 26 29 42 1.910 0.754 26 21 34 9.42 0.805 13.0 28 43 20 4 8.14 0.814 45.5 23 47 40 4 1.475 26 21 34 1.611 0.754 26 27 40 7.59 0.795 39.4 24 43 18 8.15 0.814 45.4 23 39 48 4 4

1.475 26 27 40 1.941 0.752 24 33 20 9.29 0.794 12.4 27 45 18 8.10 0.814 45.9 23 39 18 4 1.464 26 27 36 1.918 0.751 26 27 36 9.29 0.794 12.4 27 17 16 4 8.07 0.811 46.1 23 17 40 4 1.464 26 25 34 1.922 0.749 26 19 36 7.57 0.790 36.5 23 21 16 11.36 0.805 18.2 28 19 18 4 4

1.451 27 15 36 1.924 0.749 26 25 28 7.55 0.788 38.6 23 45 22 11.35 0.805 16.2 28 17 20 4 1.450 27 25 46 1.953 0.748 23 23 34 9.14 0.781 12.3 26 23 18 7.93 0.799 46.3 23 23 16 4

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.18 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 6,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-22 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 27201.2 Exposure: M~d/MTUJ (G~d) 6500.0 ( 617.75 Delta E: M~d/MTU, (GWd) 500.0 C 62.90 Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 6) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.163 4.600 19 0.321 0.567 55 40 Inlet Subcooling: Btullbm -24.74 23 0.297 10.530 20 0.274 0.287 57 42 Flow: Mlb/hr 96.04 C 98.00 9) 22 0.605 20.706 21 0.391 0.728 53 42 21 0.698 25.097 22 0.659 0.882 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.769 27.578 23 1.290 1.400 21 30 59 19 0.825 28.664 24 1.256 1.402 19 28 59 55 55 18 0.872 29.078 25 1.072 1.307 47 44 51 51 17 0.939 29.249 26 1.417 1.485 19 30 47--------------20 47 16 0.986 29.544 27 1.395 1.466 15 26 43 43 15 1.011 30.114 28 1.201 1.499 17 20 39-----------6 ... -- 8--------- 39 14 1.012 30.779 35-------------- 35 13 1.061 30.120 31----------20-----------0 .20--------- 31 -.. 12 1.084 30.604 27-------------- 27 11 1.115 31.364 23-----------8 ... -- 6--------- 23 10 1.154 31.955 19 19 9 1.209 32.281 15--------------20 15 8 1.288 32.990 11 11 7 1.366 33.683 7 7 6 1.475 34.194 3 3 5 1.554* 34.627*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.541 33.666 3 1.458 30.753 Control Rod Density: % 3.81 2 1.168 23.800 Bottom 1 0.352 7.094 k-effective: 0. 99760 Void Fraction: 0.393 6 AXIAL TILT -23.024 -9.797 Core Delta-F: psia 21.976 AVG BOT 8ft/12ft 1.1770 1.0971 Core Plate Delta-F: psia 17.545 Coolant Tamp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.46 Active Channel Flow: Mlb/hr 81.60 Total Bypass Flow (6): 11.0 (of total core flow)

Total Water Rod Flow (6): 4.0 (of total core flow)

Source Convergence 0. 00049 Top Ten Thermal Limits Summsary - Sorted by Margin Power MCPR APIBGR LHGCR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT ZR JR K 1.499 28 17 20 1.888 0.763 26 19 32 9.70 0.829 13.5 26 41 16 5 8.33 0.834 45.6 24 17 18 4 1.498 28 19 18 1.889 0.762 26 29 42 9.70 0.829 13.5 26 45 20 5 8.28 0.828 45.5 23 39 16 4 1.485 26 19 30 1.948 0.750 24 19 34 9.59 0.819 14.2 28 41 18 8.25 0.825 45.6 23 15 40 4 1.484 26 31 42 1.924 0.748 26 21 28 9.58 0.819 14.2 29 43 20 8.15 0.824 46.6 23 47 40 4 4

1.478 26 21 28 1.954 0.747 24 33 20 9.49 0.811 13.6 27 43 16 8.16 0.824 46.5 23 39 48 4 4

1.477 26 33 40 1.928 0.747 26 27 22 9.49 0.811 13.6 27 45 18 8.06 0.819 47.1 23 39 18 4 1.466 27 15 26 1.928 0.747 26 17 28 7.64 0.802 40.5 24 43 18 4 7.92 0.817 48.7 23 17 40 5 1.464 27 25 16 1.928 0.747 26 19 26 9.35 0.799 13.0 27 41 14 4 11.46 0.813 17.7 28 19 18 4 1.464 26 25 28 1.931 0.746 26 33 44 9.34 0.798 13.0 27 47 20 11.46 0.813 17.7 28 17 20 4 1.464 26 33 36 1.932 0.745 26 35 42 9.31 0.796 13.5 26 23 18 7.89 0.808 47.9 24 25 18 5

12HCR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.19 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 6,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-23 Cycle: 24 Core Average Exposure: MWd/MTU 27451.7 Exposure: M~d/MTU (SWd) 6750.0 ( 649.20 Delta E: M~d/MTUI, (O~d) 250.0 ( 31.45) Axial Profile Edit Radial Power Power: lMWt 2957.0 (100.00 9) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.163 4.636 19 0.319 0.564 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.297 10.610 20 0.272 0.284 57 42 Flow: Mlh/hr 96.04 ( 98.00 8) 22 0.605 20.871 21 0.388 0.725 53 42 21 0.698 25.287 22 0.657 0.879 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.768 27.788 23 1.288 1.393 21 30 59 59 19 0.824 29.089 24 1.253 1.399 19 28 55 55 18 0.872 29.317 25 1.070 1.307 47 44 51 51 17 0.938 29.496 26 1.421 1.488 19 30 47--------------20 47 16 0.986 29.798 27 1.401 1.472 15 26 43 43 15 1.010 30.374 28 1.205 1.504 17 20 39-----------6 .... -- 8--------- 39 14 1.010 31.040 35-------------- 35 13 1.058 30.380 31----------20-----------0 .20--------- 31 -.. 12 1.080 30.869 27-------------- 27 11 1.110 31.637 23-----------8 -.... -- 6--------- 23 10 1.150 32.238 19 19 9 1.206 32.573 15--------------20 15 8 1.283 33.296 II ii 7 1.366 34.008 7 7 6 1.479 34.545 3 3 5 1.560* 34.898*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.548 34.034 3 1.465 31.102 Control Rod Density: 8 2 1.172 24.079 3.81 Bottom 1 0.353 7.179 k-effective: 0.99768 Void Fraction: 0.393 % AXIAL TILT -23.099 -9.883 Core Delta-P: psia 21.983 AVG BOT 8ft/12ft 1.1772 1.0976 Core Plate Delta-P: psia 17.552 Coolant Tamp: Deg-F 543.7 In Channel Flow: Mlb/hr 85.46 Active Channel Flow: Rib/hr 81.60 Total Bypass Flow (6): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00043 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLH[GR LHGR Value FT IR JR Value Margin FT ZR JR Value Margin Exp. FT ZR JR Value Margin Exp. FT IR JR K 1.504 28 17 20 1.892 0.761 26 19 32 9.80 0.837 14.1 26 41 16 8.34 0.839 46.2 24 17 18 4 1.503 28 19 18 1.893 0.761 26 29 42 9.79 0.837 14.1 26 45 20 8.29 0.833 46.0 23 39 16 4 1.488 26 19 30 1.955 0.747 24 19 34 9.67 0.827 14.8 28 41 18 4 8.25 0.830 46.1 23 15 40 4 1.487 26 31 42 1.929 0.747 26 17 28 9 .67 0.826 14.8 28 43 20 4 8.16 0.830 47.2 23 47 40 4 1.480 26 21 28 1.930 0.746 26 21 28 9.60 0.820 14.2 27 43 16 8.17 0.829 47.1 23 39 48 4 4

1.478 26 33 40 1.931 0.746 26 19 26 9.60 0.820 14.2 27 45 18 7.92 0.821 49.2 23 39 16 5 4

1.472 27 15 26 1.932 0.746 26 33 44 9.46 0.809 13.6 27 41 14 7.90 0.820 49.3 23 17 40 5 4

1.471 27 25 16 1.933 0.745 26 27 22 9.45 0.808 13.6 27 47 20 11.52 0.817 18.4 26 19 18 4 4

1.466 26 17 24 1.961 0.745 24 27 42 9.42 0.805 13.8 27 35 14 11.51 0.817 18.4 28 17 20 4 4

1.465 26 15 20 1.934 0.745 26 35 42 7.66 0.805 41.1 24 43 18 7 .90 0.814 48.4 24 25 18 5

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.20 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 6,750.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-24 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MO~d/MTU 27452.2 Exposure: MWd/MTU (GWd) 6751.0 ( 849.33 Delta E: MWd/MTU, (G~d) 1.0 C 0.13 Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.191 4.636 19 0.318 0.553 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.346 10.610 20 0.267 0.279 57 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.705 20.872 21 0.383 0.704 53 42 21 0.814 25.288 22 0.653 0.857 47 48 2 8 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.891 27.789 23 1.241 1.417 35 40 59 59 19 0.943 29.090 24 1.361 1.483 31 32 55 55 18 0.984 29.318 25 1.046 1.288 31 10 51 51 17 1.043 29.497 26 1.458 1.529 31 34 47 -20

....- -- 20------- 47 16 1.078 29.799 27 1.347 1.534 35 38 43 43 15 1.075 30.375 28 1.185 1.470 43 42 39 .. . .20-----------0 .20--------- 39 -.. 14 1.041 31.041 35 35 13 1.062 30.381 31 8 -.... -- 8--------- 31 12 1.062 30.870 27 27 11 1.074 31.638 23 .. . .20-----------0 .20--------- 23 -.. 10 1.099 32.239 19 19 9 1.143 32.575 15 -20

....- -- 20------- 15 8 1.209 33.297 11 11 7 1.283 34.010 7 7 6 1.385 34.547 3 3 5 1.453* 34.999*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.425 34.035 3 1.330 31.103 Control Rod Density: % 4.47 2 1.051 24.080 Bottom 1 0.314 7.179 k-effective: 0. 99765 Void Fraction: 0.378 8 AXIAL TILT -15.233 -9.883 Core Delta-P: psia 21.788 AVG DOT 8ft/12ft 1.1302 1.0976 Core Plate Delta-P: psia 17. 355 Coolant Temp: Deag-F 543.4 In Channel Flow: Mlb/hr 85.57 Active Channel Flow: Mlb/hr 81.77 Total Bypass Flow (9): 10.9 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00037 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHG] LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.534 27 35 38 1.811 0.795 26 29 34 9.36 0.800 13.2 26 31 12 5 8.06 0.807 45.7 23 47 32 4 1.531 27 37 36 1.814 0.794 26 21 42 9.34 0.799 13.2 26 49 32 5 8.05 0.806 45.6 23 31 48 4 1.529 26 31 34 1.817 0.793 26 19 40 9.32 0.797 13.8 26 33 16 5 8.14 0.802 44.1 23 31 16 4 1.525 26 33 32 1.825 0.789 26 27 44 9.32 0.796 14.3 26 43 28 5 7.73 0.798 48.7 23 47 34 5 1.518 26 35 42 1.832 0.786 26 35 28 9.32 0.796 14.3 26 33 18 5 8.09 0.798 44.1 23 15 32 4 1.514 26 41 36 1.833 0.786 28 27 36 9.32 0.796 13.8 26 45 28 5 7.72 0.796 48.6 23 33 48 5 1.508 26 39 42 1.833 0.786 26 33 30 9.26 0.791 13.5 26 33 12 5 7.73 0.794 48.2 23 31 18 5 1.508 26 41 40 1.833 0.786 26 35 20 9.24 0.790 13.5 26 49 34 5 7.70 0.791 48.2 23 17 32 5 1.503 26 27 44 1.836 0.784 26 43 34 9.10 0.778 14.1 26 31 28 5 7.74 0.788 47.4 24 31 32 5 1.499 26 43 34 1.863 0.784 24 29 32 9.09 0.777 14.1 26 33 30 5 10.92 0.775 15.9 26 49 32 5

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.2l Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 6,751.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-25 Cycle: 24 Core Average Exposure: M~d/MTUJ 27701.2 Exposure: MWd/M4TU (G~d) 7000.0 C 880.66)

Delta E: M~d/MTUJ, (GWd) 249.0 ( 31.33) Axial Profile Edit Radial Power Power: MO~t 2957.0 (100.00 %) MCPRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.189 4.679 19 0.318 0.553 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.342 10.703 20 0.266 0.278 57 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.696 21.062 21 0.382 0.704 53 42 21 0.803 25.508 22 0.653 0.857 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.877 28.031 23 1.238 1.405 39 36 59 59 19 0.933 29.346 24 1.351 1.467 31 32 55 55 18 0.978 29.586 25 1.048 1.270 51 32 51 51 17 1.040 29.771 26 1.459 1.520 31 28 47 -20

-.... 20------- 47 16 1.075 30.075 27 1.354 1.528 37 36 43 43 15 1.075 30.651 28 1.192 1.477 43 42 39 .. . .20-----------8 ....- 20--------- 39 14 1.041 31.308 35 35 13 1.062 30.640 31 8 ....- 8--------- 31 12 1.062 31.130 27 27 11 1.073 31.900 23 .. . .20-----------8 ....- 20--------- 23 10 1.099 32.507 19 19 9 1.143 32.850 15 -20

....- 20------- 15 8 1.212 33.584 11 ii 7 1.288 34.314 7 7 6 1.393 34.875 3 3 5 1.463* 35.344*

2 8 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.438 34.374 3 1.342 31.419 4.52 2 1.060 24.329 Control Rod Density: %

Bottom 1 0.317 7.254 k-effective: 0. 99746 Void Fraction: 0.379 % AXIAL TILT -15.748 -9.896 Core Delta-P: psia 21.806 AVG BOT 8ft/l2ft 1.1339 1.0976 Core Plate Delta-P: psia 17.372 Coolant Temp: Deg-F 543.5 In Channel Flow: Mlb/hr 85.56 Active Channel Flow: Mlb/hr 81.76 Total Bypass Flow (8): 10.9 (of total core flow)

Total Water Rod Flow (%): 4.0 (of total core flow)

Source Convergence 0.00036 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT Value FT IR JR IR JR K 1.528 27 37 36 1.819 0.791 28 19 40 9.48 0.810 13.8 26 31 12 5. 7.85 0.811 48.8 23 47 32 5 1.527 27 35 38 1.821 0.791 26 21 42 9.46 0.809 13.8 26 49 32 5 7.84 0.810 48.8 23 31 48 5 1.520 26 31 28 1.836 0.784 26 43 34 9.42 0.805 14.4 26 33 16 5 8.12 0.805 44.7 23 31 16 4 1.519 26 33 32 1.839 0.783 26 27 44 9.41 0.805 14.4 26 45 28 5 7.74 0.804 49.2 23 47 34 5 1.517 26 41 36 1.850 0.779 26 19 36 9.40 0.803 14.9 28 33 18 5 7.73 0.802 49.2 23 33 48 5 1.515 26 25 42 1.853 0.777 26 35 20 9.40 0.803 14.9 26 43 28 5 8.07 0.801 44.7 23 15 32 4 1.511 26 41 40 1.857 0.776 26 31 28 9.39 0.803 14.1 26 33 12 5 7.73 0.798 48.7 23 31 18 5 1.510 26 39 42 1.858 0.775 26 33 30 9.37 0.801 14.1 26 49 34 5 7.70 0.795 48.7 23 17 32 5 1.505 26 43 34 1.862 0.774 26 27 36 9.15 0.782 14.7 26 31 28 5 7.70 0.788 47.9 24 31 32 5 1.502 26 27 44 1.862 0.773 26 35 28 9.14 0.781 14.6 26 33 30 5 11.01 0.781 16.6 26 49 32 5 LHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.22 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 7,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-26 Cycle: 24 Core Average Exposure: M~d/MTUD 28201.9 Exposure: MWd/MTU (G~d) 7500.0 ( 943.56)

Delta E: MWd/MTUJ, (G~d) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: M86t 2957.0 (100.00 %) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.189 4.762 19 0.314 0.549 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.343 10.887 20 0.262 0.274 57 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.697 21.442 21 0.377 0.700 53 42 21 0.803 25.946 22 0.649 0.852 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.876 28.510 23 1.234 1.392 39 36 59 S ~ 59 19 0.933 29.856 24 1.341 1.451 29 30 55 55 18 0.978 30.122 25 1.045 1.272 8 32 51 51 17 1.040 30.320 26 1.466 1.520 41 36 47 -~20--------- 20---------47 16 1.076 30.629 27 1.367 1.527 37 36 43 43 15 1.076 31.205 28 1.201 1.486 43 42 39 .. . .20-----------8 -- -.. 20---------39 14 1.040 31.843 35 13 -~35 1.057 31.159 31 8--------- 8---------31 12 1.054 31.648 27 11 -~27 1.065 32.424 23 .. . .20-----------8 -- -.. 20---------23 10 1.090 33.043 19 19 9 1.136 33.402 15 -~20--------- 20---------15 8 1.206 34.161 1i 1i 7 1.285 34.927 7 7 6 1.396 35.539 3 -- 3 5 1.470" 36.042*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.449 35.062 3 1.354 32.061 4.52 2 1.067 24.836 Control Rod Density: %

Bottom 1 0.320 7.407 k-effective: 0.99759 Void Fraction: 0.379 8 AXIAL TILT -15.777 -9.930 Core Delta-P: psia 21.816 AVG BOT eft/l2ft 1.1338 1.0977 Core Plate Delta-P: psia 17.382 Coolant Temp: Deg-F 543.5 In Channel Flow: Mlb/hr 85.56 Active Channel Flow: Mlb/hr 81.75 Total Bypass Flow (%): 10.9 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.00040 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT ZR JR Value Margin FT ZR JR Value Margin Exp. FT ZR JR Value Margin Exp. FT ZR JR K K

1.527 27 37 36 1.828 0.788 26 19 40 9.64 0.824 15.0 26 31 12 5 7.82 0.817 49.9 23 47 32 5 1.526 27 35 38 1.829 0.787 26 21 42 9.62 0.822 15.0 26 49 32 5 7.82 0.816 49.8 23 31 48 5 1.520 26 41 36 1.839 0.783 26 43 34 9.57 0.818 15.3 26 33 12 5 7.66 0.810 51.1 23 47 34 5 1.520 26 31 34 1.841 0.782 26 27 44 9.55 0.816 15.3 26 49 34 5 7.65 0.808 51.0 23 33 48 5 1.519 26 33 32 1.856 0.776 26 41 36 9.51 0.813 15.6 26 33 16 5 8.05 0.806 45.8 23 31 16 4 1.518 26 25 42 1.859 0.775 26 35 20 9.51 0.813 15.6 26 45 28 5 7.86 0.802 47.6 23 15 32 5 1.515 26 41 40 1.866 0.772 26 31 28 9.44 0.807 16.1 26 33 18 5 7.65 0.798 49.8 23 31 18 5 1.513 26 39 42 1.867 0.771 26 33 30 9.44 0.806 16.1 26 43 28 5 7.63 0.796 49.8 23 17 32 5 1.513 26 43 34 1.869 0.771 28 17 42 9.10 0.778 15.8 26 31 28 5 7.99 0.786 43.8 25 31 10 4 1.510 26 27 44 1.871 0.770 26 27 36 9.09 0.777 15.8 26 33 30 5 11.08 0.786 18.0 26 49 32 5

LMGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.23 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 7,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-27 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/94TU 26701.2 Exposure: M66d/MTUJ (G~d) 8000.0 (1006.50 Delta E: MWd/MTU, (G~d) 500.0 ( 62.90 Axial Profile Edit Radial Power Power: M~t 2657.0 (100.00 6) MCPRA) Power Exposure Zone Avg. Max. TR JR Core Pressure: psia 1015.0 Top 24 0.167 4.646 19 0.312 0.547 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.339 11.071 20 0.260 0.272 57 42 Flow: Mlb/hr 96.04 ( 96.00 6) 22 0.691 21.821 21 0.375 0.699 53 42 21 0.794 26.363 22 0.647 0.649 13 46 2 6 10 14 18 22 26 30 34 38 42 46 50 54 56 20 0.671 28.969 23 1.226 1.365 45 32 59 59 19 0.930 30.366 24 1.327 1.426 31 32 55 55 16 0.979 30.657 25 1.045 1.277 9 32 51 51 17 1.044 30.866 26 1.470 1.523 41 36 47----------20 ... -- 20------- 47 16 1.061 31.162 27 1.361 1.524 37 36 43 43 15 1.061 31.759 26 1.213 1.497 43 42 39----------20-----------6 .20--------- 39 -.. 14 1.044 32.379 35-------------- 35 13 1.056 31.677 31-----------8 ... -- 8--------- 31 12 1.053 32.165 27-------------- 27 11 1.062 32.946 23----------20-----------6 .20--------- 23 -.. 10 1.087 33.577 19 19 9 1.132 33.953 15----------20 ... -- 20------- 15 6 1.203 34.735 11 1i 7 1.263 35.540 7 7 6 1.394 36.204 3 3 5 1.470* 36.743*

2 6 10 14 18 22 26 30 34 36 42 46 50 54 56 4 1.456 35.752 3 1.364 32.707 Control Rod Density: 9 2 1.074 25.345 4 .57 Bottom 1 0.321 7.560 k-effective: 0. 99751 Void Fraction: 0.379 6 AXIAL TILT -15.636 -9.964 Core Delta-P: psia 21.626 AVG DOT 8ft/l2ft 1..1353 1.0979 Core Plate Delta-P: psal 17.393 Coolant Tamp: Deg-F 543.4 In Channel Flow: Mlb/hr 65.56 Active Channel Flow: Mlb/hr 61.75 Total Bypass Flow (6): 10.9 (of total core flow)

Total Water Rod flow I): 4.0 (of total core flow)

Source Convergence 0.00036 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.524 27 37 36 1.834 0.765 26 19 40 9.70 0.629 16.3 26 31 12 5 7.60 0.820 50.5 23 47 34 4 1.523 26 41 36 1.636 0.764 26 21 42 9.69 0.626 16.2 26 49 32 5 7.76 0.620 51.0 23 47 32 5 1.521 26 43 34 1.640 0.763 26 43 34 9.66 0.625 16.6 26 33 12 5 7.75 0.616 50.9 23 31 48 5 1.520 27 35 36 1.649 0.779 26 27 44 9.64 0.624 16.5 26 49 34 5 7.80 0.618 50.4 23 33 46 4 1.516 26 41 40 1.659 0.774 26 17 42 9.50 0.612 16.6 26 33 16 5 7.94 0.804 46.9 23 31 16 4 1.516 26 25 42 1.660 0.774 26 19 36 9.49 0.611 16.6 26 45 26 5 7.76 0.600 46.6 23 15 32 5 1.516 26 39 42 1.663 0.773 26 41 16 9.37 0.600 17.3 26 33 16 5 6.03 0.798 44.9 25 31 10 4 1.512 26 27 44 1.870 0.770 26 35 20 9.36 0.600 17.3 26 43 26 5 7.96 0.793 45.0 25 9 32 4 1.511 26 45 34 1.666 0.763 26 45 34 9.23 0.769 16.6 26 35 12 4 7.51 0.792 50.6 23 31 16 5 1.511 26 33 32 1.669 0.762 26 43 36 9.20 0.766 16.5 26 49 36 4 7.49 0.790 50.6 23 17 32 5

LHOR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.24 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 8,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP, Revision I Page A-28 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 29201.2 Exposure: MWd/MTU (GWd) 8500.0 (1069.40)

Delta B: MWd/M4TU, )GWd) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: MWC 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. XE JR Core Pressure: psia 1015.0 Top 24 0.186 4.929 19 0.310 0.544 55 40 Inlet Bubcooling: Btu/ibm -24 .74 23 0.337 11.254 20 0.257 0.269 57 42 Flow: Mlb/hr 96.04 C 98.00 8) 22 0.696 22.197 21 0.372 0.697 53 42 21 0.788 26.815 22 0.646 0.846 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.869 29.464 23 1.223 1.372 45 32 59 59 19 0.932 30.875 24 1.313 1.406 31 32 55 55 18 0.984 31.193 25 1.046 1.279 9 32 51 51 17 1.052 31.419 26 1.473 1.521 43 34 47 - -20 -- 20 - 47 16 1.091 31.739 27 1.395 1.517 37 36 43 43 15 1.092 32.315 28 1.225 1.507 43 42 39 .20---------

-.. 6 20--------- 39 14 1.053 32.916 35 35 13 1.063 32.196 31 6 -- -- 6 - 31 12 1.055 32.681 27 27 11 1.062 33.466 23 .20---------

-.. 20--------- 23 10 1.085 34.110 19 19 9 1.130 34.502 15 ---~20 -- 20 - 15 8 1.199 35.309 11 1I 7 1.278 36.151 7 7 6 1.385 36.868 3 3 5 1.460* 37.443*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.453 36.446 3 1.365 33.357 Control Rod Density:% 4. 61 2 1.073 25.856 Bottom 1 0.321 7.714 h-effective: 0.99755 Void Fraction: 0.378 % AXIAL TILT -15.553 -9.997 Core Delta-P: psia 21.828 AVG DOT 8ft/12ft 1.1353 1.0980 Core Plate Delta-P: psia 17.394 Coolant Temp: Deg-F 543.4 In Channel Flow: Mlb/hr 85.56 Active Channel Flow: Mlb/hr 81.76 Total Bypass Flow (8): 10.9 (of total core flow)

Total Water Rod Flow (6): 4.0 (of total core flow)

Source Convergence 0.00041 Top Ten Thermal Limits Summnary - Sorted by Margin Power MCPR APLHGR tHGR Value FT XE JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT XE JR K 1.521 26 43 34 1.841 0.782 26 19 40 9 .67 0.827 17.3 26 33 12 4 7.78 0.827 51.5 23 47 34 4 1.520 26 41 40 1.842 0.782 26 21 42 9.66 0.825 17.5 26 31 12 5 7.77 0.825 51.4 23 33 48 4 1.519 26 41 36 1.945 0.780 26 43 34 9.65 0.824 17.5 26 49 32 5 7.64 0.816 52.0 23 47 32 5 1.519 26 27 44 1.64 8 0.779 26 27 44 9.64 0.824 17.3 26 49 34 4 7.63 0.815 52.0 23 31 48 5 1.518 26 39 42 1.848 0.77 9 28 17 42 9.41 0.805 17.7 28 35 12 8.02 0.806 46.0 25 31 10 4 4

1.518 26 25 42 1.852 0.778 28 41 18 9.38 0.802 17.7 28 49 36 7 .97 0.801 46.1 25 9 32 4 S

1 .517 26 45 34 1.870 0.770 26 19 36 9 .37 0.801 18.0 26 33 16 11.02 0.801 21.7 26 49 34 4 5

1 .517 27 37 36 1.873 0.769 26 35 20 9.37 0.801 18.0 26 45 28 11.00 0.799 21.7 26 33 50 4 5

1.516 27 35 38 1.884 0.764 26 45 34 9.18 0.785 18.5 26 33 18 10.99 0.799 21.7 28 35 12 4 5

1.515 26 27 46 1.6888 0.763 26 33 46 9.18 0.755 18.5 26 43 28 10.97 0.797 21.7 28 49 36

LHGR calculated with pin-power reconstruction & CPR limit type 3

CPR calculated with pin-power reconstruction Figure A.25 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 8,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-29 Cycle: 24 Core Average Exposure: MWd/MTU 29701.2 Exposure: MWd/MTU (GWd) 9000.0 (1132.30)

Delta E: MWd/MTU, (GWd( 500.0 C 62.90) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 6) M(PRA( Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.188 5.011 19 0.307 0.544 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.342 11.435 20 0.255 0.268 57 42 Flow: Mlb/hr 96.04 ( 98.00 6) 22 0.695 22.570 21 0.369 0.697 53 42 21 0.798 27.245 22 0.643 0.846 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.880 29.939 23 1.218 1.366 45 32 58 59 19 0.944 31.384 24 1.304 1.393 31 32 55 55 18 0.996 31.732 25 1.044 1.284 51 32 51 51 17 1.064 31.973 26 1.476 1.528 43 34 47----------18 ... 20------- 47 16 1.100 32.301 27 1.406 1.518 37 36 43 43 15 1.096 32.877 28 1.235 1.519 43 42 39----------20-----------6 ....- 20--------- 39 14 1.058 33.458 35-------------- 35 13 1.067 32.717 31-----------6 ... 6--------- 31 12 1.057 33.198 27-------------- 27 11 1.063 33.987 23----------20-----------6 ...-. 20--------- 23 10 1.085 34.641 19 19 9 1.128 35.049 15----------20 ... 18------- 15 8 1.195 35.880 1i 11 7 1.269 36.760 7 7 6 1.368 37.528 3 3 5 1.437* 38.138*

2 6 10 14 18 22 26 30 34 36 42 46 50 54 58 4 1.436 37.139 3 1.353 34.007 Control Rod Density: 9 4 .66 2 1.063 26.368 Bottom 1 0.318 7.868 k-effective: 0.99761 Void Fraction: 0 .376 % AXIAL TILT -14.763 -10.024 Core Delta-P: psia 21.811 AVG BOT 8ft/l2ft i.: 1308 1.0982 Core Plate Delta-P: psia 17.378 Coolant Temp: Deg-F 543.4 In Channel Flow: Mlb/hr 85.57 Active Channel Flow: Rlb/hr 81.77 Total Bypass Flow (6): 10.9 (of total core flow)

Total Water Rod Flow (9): 4.0 (of total core flow)

Source Convergence 0. 00044 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT 1R JR K 1.528 26 43 34 1.835 0.785 28 43 42 9.72 0.831 18.6 26 33 12 4 7.67 0.825 52.6 23 47 34 4 1.527 26 45 34 1.837 0.784 28 41 44 9.69 0.828 18.5 26 49 34 4 7.67 0.824 52.5 23 33 48 4 1.525 26 41 40 1.838 0.783 26 43 34 9.59 0.820 18.2 26 31 12 4 7.95 0.807 47.1 25 31 10 4 1.523 26 41 36 1.841 0.782 26 19 22 9.57 0.818 18.1 26 49 32 4 7.61 0.807 51.2 23 47 32 4 1.523 26 39 42 1.845 0.781 26 21 20 9.49 0.811 19.0 28 35 12 4 7.62 0.806 51.1 23 31 48 4 1.522 26 33 44 1.847 0.780 26 33 44 9.46 0.809 18.9 28 49 36 4 10.95 0.806 23.1 26 49 34 4 1.521 26 33 46 1.867 0.771 26 41 36 9.21 0.787 18.8 26 33 16 4 10.94 0.805 23.1 28 35 12 4 1.520 26 35 42 1.871 0.770 26 45 34 9.19 0.785 18.8 26 45 28 4 10.94 0.804 23.1 26 33 50 4 1.519 28 43 42 1.874 0.768 26 35 42 9.15 0.782 18.9 27 35 14 4 10.92 0.803 23.0 28 49 36 4 1.518 27 37 36 1.882 0.765 26 33 46 9.15 0.782 17.9 28 33 10 4 7.90 0.803 47.2 25 9 32 4

LMGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction 6 CPR limit type 3 Figure A.26 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 9,000.0 MWd/MTU ARE-VA Inc.

Controfled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-30 Cycle: 24 Core Average Exposure: MWd/MTtJ 30051.2 Exposure: MM6/MTU CG~d) 9350.0 (1176.30 I Delta E: MWd/MTU, (GD6) 350.0 ) 44.03) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 6) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.190 5.070 19 0.306 0.543 55 40 Inlet Subcooling: Btu/lb -24 .74 23 0.345 11.564 20 0.253 0.266 57 42 Flow: Mlb/hr 96.04 C 98.00 6) 22 0.702 22.835 21 0.367 0.697 53 42 21 0.807 27.549 22 0.642 0.840 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.889 30.276 23 1.214 1.362 45 32 59 -- 59 19 0.954 31.746 24 1.299 1.386 31 32 55 55 18 1.007 32.113 25 1.044 1.289 9 32 51 51 17 1.074 32.366 26 1.479 1.534 45 34 47----------18 -- ....- 18------- 47 16 1.108 32.697 27 1.413 1.518 37 36 43 43 15 i.i00 33.272 28 1.242 1.519 43 42 39----------20--------- 6----------20--------- 39 14 1.063 33.840 35------------- 35 13 1.072 33.083 31-----------6 -- ....- 6--------- 31 12 1.061 33.560 27------------- 27 11 1.067 34.352 23----------20--------- 6----------20--------- 23 10 1.088 35.014 19 19 9 1.130 35.431 15----------18 -- ....- 18------- 15 8 1.195 36.279 ii 11 7 1.264 37.184 7 7 6 1.355 37.984 3--- 3 5 1.416* 38.617*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.415 37.618 3 1.336 34.459 Control Rod Density: % 2 1.049 26.722 4 .71 Bottom 1 0.314 7.975 k-effective: 0.99763 Void Fraction: 0.374 6 AXIAL TILT -14.082 -10.034 Core Delta-P: psia 21. 795 AVG SOT 8ft/12ft 1.1270 1.0982 Core Plate Delta-P: psia 17. 362 Coolant Tamp: Deag-F 543.4 In Channel Flow: Mlb/hr 85.58 Active Channel Flow: Mlb/hr 81.79 Total Bypass Flow (9): 10.9 (of total core flow)

Total Water Rod Flow (6) 4.0 (of total core flow)

Source Convergence 0.00043 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT ID JR K Value Margin Exp. FT IR JR K

1.534 26 45 34 1.832 0.786 28 17 42 9.67 0.826 19.5 26 33 12 4 7.55 0.818 53.4 23 47 34 4 1.532 26 43 34 1.835 0.785 26 43 34 9.64 0.824 19.4 26 49 34 4 7.56 0.818 53.3 23 33 48 4 1.524 26 41 36 1.846 0.780 28 41 18 9.53 0.815 19.0 26 31 12 4 7.86 0.805 47.9 25 31 10 4 1.523 26 41 40 1.846 0.780 26 19 40 9.51 0.813 19.0 26 49 32 4 10.82 0.803 24.1 26 49 34 4 1.519 28 43 42 1.860 0.774 26 27 44 9.46 0.809 19.8 28 35 12 4 10.82 0.803 24.1 26 33 50 4 1.518 26 27 44 1.861 0.774 26 21 42 9.43 0.806 19.7 28 49 36 4 10.81 0.802 24.1 28 35 12 4 1.518 27 37 36 1.883 0.773 26 45 34 9.16 0.783 18.7 28 33 10 4 10.80 0.801 24.0 28 49 36 4 1.517 26 27 46 1.866 0.772 26 19 36 9.12 0.780 18.6 28 51 34 4 7.81 0.800 47.9 25 9 32 4 1.517 26 39 42 1.891 0.762 26 35 20 9.06 0.774 19.7 27 35 14 4 10.81 0.798 23.5 28 33 10 4 1.515 27 35 38 1.892 0.761 26 43 38 9.05 0.774 19.7 26 33 16 4 7.46 0.796 52.0 23 47 32 4

tHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.27 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 9,350.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-31 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: M~d/MTU 30052.2 Exposure: MWd/MTU (OWd( 9351.0 (1176.40)

Delta E: MWd/MTOJ, (GWd) 1.0 C 0.13) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 6) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.176 5.070 18 0.304 0.549 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.319 11.564 20 0.257 0.269 57 42 Flow: Mib/hr 96.04 ( 98.00 8) 22 0.651 22.635 21 0.367 0.713 53 42 21 0.747 27.550 22 0.626 0.775 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.815 30.277 23 1.262 1.371 21 46 59 59 19 0.657 31.747 24 1.226 1.374 17 44 55 55 18 0.891 32.114 25 1.053 1.289 47 44 51 51 17 0.953 32.367 26 1.454 1.527 15 42 47 ... 34----------12 . 34 .. ..- 47 -.. 16 1.002 32.698 27 1.466 1.533 25 46 43 43 15 1.032 33.274 26 1.243 1.558 17 42 39----------10 --. -- 10--------- 39 14 1.040 33.841 35-------------- 35 13 1.082 33.084 31----------12-----------0 31 ----12 1.100 33.562 27-------------- 27 11 1.126 34.353 23-----------8 .... -- 10--------- 23 10 1.161 35.015 19 19 9 1.210 35.433 15 ... 34----------12 . 34 .. ..- 15 -.. 8 1.272 36.280 11 11 7 1.329 37.185 7 7 6 1.413 37.985 3 3 5 1.476 38.618*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.482k 37.619 3 1.411 34.460 Control Rod Density: 8 4.73 2 1.118 26.723 Bottom 1 0.336 7.976 k-effective: 0.99746 Void Fraction: 0.383 8 AXTAL TILT -20.285 -10.034 Core Delta-P: psia 21.937 AVG BOT 8ft/l2ft 1.1619 1.0982 Core Plate Delta-P: psia 17.503 Coolant Temp: Deg-F 543.5 In Channel Flow: Mib/hr 85.51 Active Channel Flow: Mlb/hr 61.68 Total Bypass Flow (6): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow(

Source Convergence 0.00038 Top Ten Thermal timits Summary - Sorted by Margin Power MCPR APLHGR 511GR JR Value Margin Exp. FT IR JR Value Margin Exp. FT ZR JR Value FT IR JR Value Margin FT IR K K 1.558 28 17 42 1.877 0.767 28 17 42 10.18 0.870 19.8 28 35 12 4 8.09 0.858 51.3 23 47 40 4 1.557 28 19 44 1.884 0.764 28 19 44 10.16 0.868 19.7 28 11 36 4 8.10 0.857 51.2 23 39 48 4 1.533 27 25 46 1.921 0.750 26 27 40 10.09 0.862 18.8 27 37 12 4 8.14 0.857 50.7 23 23 48 4 1.533 27 45 36 1.925 0.748 26 39 28 10.07 0.860 18.8 27 49 38 4 8.13 0.857 50.6 23 47 24 4 1.527 26 15 42 1.934 0.744 26 27 44 10.05 0.859 19.7 27 25 14 4 11.50 0.848 23.3 27 25 14 4 1.527 26 19 46 1.936 0.744 26 43 34 10.03 0.857 19.6 27 13 36 4 11.51 0.846 23.0 27 37 12 4 1.518 27 47 36 1.943 0.741 26 23 44 9.68 0.827 18.1 27 39 12 4 11.46 0.846 23.3 27 47 36 4 1.517 27 25 48 1.944 0.741 26 17 38 9.68 0.827 19.5 26 33 12 4 11.49 0.844 23.0 27 49 38 4 1.511 26 23 44 1.946 0.740 26 29 42 9.67 0.827 19.9 27 25 16 4 11.35 0.839 23.6 28 25 50 4 1.511 26 17 38 1.946 0.740 26 41 30 9.66 0.826 18.1 27 49 40 4 11.34 0.838 23.6 28 49 26 4

L11CR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.28 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 9,351.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-32 Cycle: 24 Core Averege Exposure: MWd/MTU 30201.2 Exposure: MWd/MTU (G~d) 9500.0 (1195.20)

Delta F: M~d/MTU, (G~d) 149.0 ( 18.75) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 8) M(PRA) Power Exposure Zone Avg. Max. ZR JR Core Pressure: psia 1015.0 Top 24 0.175 5.093 19 0.303 0.548 5 40 Inlet Subcooling: Btu/lhm -24.74 23 0.318 11.616 20 0.256 0.269 3 42 Flow: Mlh/hr 96.04 ( 98.00 9) 22 0.648 22.941 21 0.367 0.713 7 42 21 0.744 27.671 22 0.626 0.776 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.811 30.410 23 1.260 1.370 15 40 59 59 19 0.856 31.886 24 1.221 1.375 17 44 55 55 18 0.892 32.260 25 1.054 1.290 13 44 51 51 17 0.956 32.517 26 1.454 1.532 15 42 47 ---- 34----------12----------34----. 47 16 1.007 32.952 27 1.470 1.537 15 38 43 43 15 1.038 33.432 28 1.247 1.561 17 42 39----------10-----------8--------- 39 14 1.046 34.000 35--------------------------- 35 13 1.089 33.242 31----------12-----------0----------12--------- 31 12 1.106 33.722 27--------------------------- 27 11 1.132 34.517 23-----------8-----------0--------- 23 10 1.166 35.164 19 19 9 1.214 35.607 15 ---- 34----------12----------34----. 15 8 1.275 36.461 1i 1i 7 1.329 37.374 7 7 6 1.408 38.186 3 3 5 1.467 38.828*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.472* 37.829 3 1.403 34.660 4.76 2 1.113 26.882 Control Rod Density: 8 Bottom 1 0.334 8.024 k-effective: 0.99741 Void Fraction: 0.383 8 AXIAL TILT -20.155 -10.065 Core Delta-P: psia 21.934 AVG SOT Sft/l2ft 1.1624 1.0984 Core Plate Delta-P: psia 17.500 Coolant Tamp: Deg-F 543.5 In Channel Flow: Mlb/hr 85.51 Active Channel Flow: Mlb/hr 81.68 Total Bypass Flow (6): 11.0 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0.0004 1 Top Ten Thermal limits Summary - Sorted hy Margin Power MCPR APLHG} LHGR Value FT ZR JR Value Margin FT ZR JR Value Margin Exp. Value Margin Exp. FT ZR JR K FT ZR JR K 1.561 28 17 42 1.871 0.770 28 17 42 10.14 0.868 20.2 28 35 12 4 8.03 0.855 51.7 23 47 40 4 1.561 28 19 44 1.878 0.767 28 19 44 10.13 0.867 20.1 28 49 36 4 6.04 0.854 51.5 23 39 48 4 1.537 27 15 36 1.925 0.748 26 21 34 10.06 0.860 19.2 27 37 12 4 8.08 0.853 51.0 23 23 48 4 1.536 27 25 46 1.926 0.748 26 27 40 10.05 0.859 19.2 27 49 38 4 8. 07 0.853 51.0 23 47 24 4 1.532 26 15 42 1.935 0.744 26 27 44 9.99 0.854 20.1 27 35 14 4 11.44 0.846 23.7 27 25 14 4 1.531 26 19 46 1.940 0.742 26 43 28 9 .97 0.853 20.1 27 47 26 4 11.45 0.845 23.5 27 37 12 4 1.523 27 13 36 1.941 0.742 26 17 38 9.67 0.826 18.5 27 39 12 4 11.42 0.844 23.7 27 47 36 4 1.521 27 25 48 1.942 0.741 26 23 44 9.66 0.825 18.5 27 49 40 4 11.44 0.844 23.4 27 49 38 4 1.514 26 17 38 1.944 0.741 26 15 42 9.65 0.825 19.8 26 33 12 4 11.30 0.838 24.0 28 25 50 4

1.513 26 23 44 1.947 0.740 26 19 46 9.63 0.823 19.7 26 11 34 4 11.29 0.837 24.0 28 49 26

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.29 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 9,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-33 Cycle: 24 Core Average Exposure: MWdIMTU 30701.2 Exposure: MWd/MTU (GWd) 10000.0 (1258.10)

Delta E: MWd/MTU, (a~d) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: 94Wt 2957.0 (100.00 9) N(PRA( Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.177 5.171 19 0.303 0.548 55 40 Inlet subcooling: Btu/lbm -24.74 23 0.321 11.786 20 0.255 0.267 3 42 Flow: Mlb/hr 96.04 ( 98.00 9) 22 0.655 23.293 21 0.366 0.712 7 42 21 0.753 28.077 22 0.627 0.776 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.821 30.853 23 1.255 1.359 15 40 59 59 19 0.874 32.355 24 1.210 1.370 17 44 55 55 18 0.916 32.748 25 1.055 1.290 13 44 51 51 17 0.986 33.021 26 1.455 1.536 15 42 47 ....- 34----------12 . 34 -.. .. 47 -.. 16 1.041 33.371 27 1.478 1.540 15 36 43 43 15 1.074 33.966 28 1.258 1.560 17 42 39----------8 - -- 8--------- 39 14 1.079 34.539 35-------------- 35 13 1.118 33.775 31-----------1-----------0 .12--------- 31 -.. 12 1.132 34.264 27-------------- 27 11 1.153 35.072 23----------8 - - 8--------- 23 10 1.184 35.756 19 19 9 1.226 36.196 15 ....- 34----------12 . 34 -. . 15 -.. 8 1.278 37.068 11 11 7 1.318 38.007 7 7 6 1.374 38.856 3 3 5 1.410" 39.527*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.403 38.531 3 1.333 35.329 Control Rod Density: % 4 .80 2 1.057 27.412 Bottom 1 0.317 8.184 k-effective: 0.99746 Void Fraction: 0.378 9 AXIAL TILT -18.203 -10.166 Core Delta-P: psia 21.885 AVG DOT Sft/l2ft 1.1560 1.0990 Core Plate Delta-P: psia 17.451 Coolant Tamp: Deg-F 543.4 In Channel Flow: Mlb/hr 85.54 Active Channel Flow: Rib/hr 81.73 Total Bypass Plow (8): 10. 9 (of total core flow)

Total Water Rod Flow (%): 4.0 (of total core flow(

Source Convergence 0.0004 1 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.560 28 17 42 1.857 0.775 28 17 42 9.76 0.846 21.5 28 35 12 4 7.66 0.824 52.6 23 39 48 4 1.559 28 19 44 1.865 0.772 28 19 44 9.76 0. 845 21.4 28 11 36 4 7.65 0.824 52.8 23 47 40 4 1.540 27 15 36 1.918 0.751 26 15 42 9.71 0.834 20.5 27 37 12 4 7. 69 0.822 52.1 23 23 48 4 1.538 27 25 46 1.929 0.746 26 19 46 9.71 0.833 20.4 27 i1 38 4 7. 68 0.821 52.1 23 47 24 4 1.536 26 15 42 1.930 0.746 27 15 26 9 .52 0.824 21.4 27 25 14 4 10. 95 0.819 24.9 27 23 12 4 1 .534 26 19 46 1.933 0.745 26 27 44 9.52 0.824 21.3 27 13 36 4 10. 95 0.818 24.8 27 11 38 4 1.531 27 13 36 1.935 0.744 26 17 34 9.31 0.804 21.1 26 33 12 4 10.90 0.817 25.2 27 25 14 4 1.528 27 25 48 1.936 0.744 27 25 16 9.30 0.802 21.0 26 1i 34 4 10.90 0.816 25.1 27 13 26 4 1.509 26 17 38 1.947 0.740 27 25 48 9.37 0.801 19.7 27 21 12 4 10.77 0.812 25.8 28 35 12 4 1.508 26 23 44 1.948 0.739 26 17 38 9.37 0.801 19.7 27 11 40 4 10.77 0.811 25.7 28 11 36 4

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.30 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 10,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-34 Cycle: 24 Core Average Exposure: M~d/MTU 31201.2 Exposure: MWd/MTU (G~d) 10500.0 (1321.00)

Delta E: M~d/MTUJ, (GdM) 500.0 C 62.90 Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 8) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.176 5.250 19 0.302 0.548 55 40 Inlet Subcooling: Stu/lbm -24.74 23 0.319 11.959 20 0.254 0.266 3 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.650 23.650 21 0.365 0.713 7 42 21 0.748 28.487 22 0.629 0.780 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.826 31.301 23 1.249 1.354 15 40 59 59 19 0.888 32.832 24 1.196 1.371 17 44 55 55 18 0.939 33.250 25 1.058 1.294 13 44 51 51 17 1.016 33.541 26 1.455 1.544 15 42 47 -- 34 - - -- 12 . 34 .. ..- 47 -.. 16 1.077 33.907 27 1.486 1.545 15 36 43 43 15 1.114 34.519 28 1.270 1.564 17 42 39 - 39 14 1.119 35.095 35 - 35 13 1.155 34.323 31 -- ....- 12 ....- -- 0 .12--------- 31 -.. 12 1.166 34.819 27 - 27 11 1.185 35.637 23 - 23 10 1.211 36.336 19 19 9 1.247 36.790 15 - -- 34-- - -- 12 . 34 .-. .. 15 -.. 8 1.289 37.678 11 11 7 1.311 38.635 7 7 6 1.340 39.511 3 3 5 1.352* 40.198*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.327 39.199 3 1.254 35.965 Control Rod Density: 8 4 .90 2 0.996 27.916 Bottom 1 0.298 8.336 k-effective: 0.99743 Void Fraction: 0.373 8AXIAL TILT -16.451 -10.232 Core Delta-?: psia 21.840 AVG BDT Sft/l2ft 1.1524 1.0994 Core Plate Delta-?: psia 17.407 Coolant Tamp: Deg-F 543.3 In Channel Flow: Mlb/hr - 85.56 Active Channel Flow: Mlb/hr 81.77 Total Bypass Flow (8): 10.9 (of total core flow)

Total Water Rod Flow (8): 4.0 (of total core flow)

Source Convergence 0. 00048 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value PT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K* Value Margin Exp. FT IR JR K 1.564 28 17 42 1.833 0.785 28 17 42 9.30 0.815 22.7 28 25 50 4 7 .14 0.789 55.3 23 47 40 5 1.563 28 19 44 1.841 0.782 28 19 44 9.29 0.814 22.6 28 11 36 4 7.14 0.789 55.1 23 39 48 5 1.545 27 15 36 1.883 0.765 26 15 42 9.27 0.804 21.7 27 23 50 4 7.16 0.785 54.5 23 23 48 5 1.544 26 15 42 1.894 0.760 26 19 46 9.26 0.804 21.6 27 11 38 4 10.37 0.785 26.3 27 23 12 4 1.543 27 25 46 1.899 0.758 27 15 26 9.00 0.788 22.5 27 25 48 4 10.37 0.785 26.2 27 11 38 4 1.542 26 19 46 1.905 0.756 27 25 16 8.99 0.787 22.5 27 13 36 4 7.15 0.785 54.5 23 47 24 5 1.540 27 13 36 1.911 0.754 26 17 34 8.88 0.775 22.2 26 27 12 4 10.33 0.782 26.3 28 25 50 4 1.537 27 25 48 1.912 0.753 27 25 48 8.88 0.775 22.2 26 11 34 4 10.24 0.781 27.1 28 11 36 4 1.516 27 13 42 1.916 0.751 26 27 44 8.98 0.774 20.9 27 21 12 4 10.29 0.781 26.6 27 25 14 1.516 27 15 44 1.917 0.751 27 47 26 8.98 0.774 20.9 27 11 40 4 10.29 0.780 26.5 27 13 26

LHOR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.31 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 10,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-35 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: M8Od/MTU 31701.2 Exposure: MWd/MTU (G~d) 11000.0 (1383.90)

Delta E: MWd/MTUJ, (G~d) 500.0 C 62.90) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %( N(PRA( Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.169 5.327 19 0.302 0.548 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.308 12.130 20 0.254 0.265 3 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.639 24.003 21 0.365 0.715 7 42 21 0.748 28.895 22 0.631 0.784 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 0.836 31.753 23 1.244 1.351 13 40 59 59 19 0.906 33.317 24 1.180 1.371 17 44 55 55 18 0.966 33.763 25 1.060 1.298 13 44 51 51 17 1.052 34.077 26 1.455 1.552 15 42 47 ....- 34----------12 -.... --- 34 -.... 47 16 1.120 34.461 27 1.494 1.551 15 36 43 43 15 1.159 35.093 28 1.282 1.568 17 42 39 0----------- 39 14 1.164 35.671 35 35 13 1.199 34.889 31 .. . .12-----------0 -.... --- 12--------- 31 12 1.206 35.390 27 27 11 1.222 36.217 23 0----------- 23 10 1.243 36.929 19 19 9 1.271 37.394 15 ....- 34----------12 -.... --- 34 ....- 15 8 1.300 38.292 11 11 7 1.302 39.259 7 7 6 1.302* 40.149 3 3 5 1.285 40.842*

2 6 10 14 18 22 26 30 34 38 942 46 50 54 58 4 1.241 39.832 3 1.162 36.562 5.18 2 0.924 28.391 Control Rod Density: 9 Bottom 1 0.277 8.479 k-effective: 0.'99740 Void Fraction: 0.368 9 AXIAL TILT -14.453 -10.268 Core Delta-P: psia 21.792 AVG BOT 8ft/l2ft 1.1485 1.0998 Core Plate Delta-P: psia 17.357 Coolant Temp: Deg-F 543.2 In Channel Flow: Mlb/hr 85.59 Active Channel Flow: Mlb/hr 81.81 Total Bypass Flow (%): 10.9 (of total core flow)

Total Water Rod Flow (9): 3.9 (of total core flow(

Source Convergence 0.00045 Top Ten Thermal Limits Summary - Sorted by Margin Power O4CPR APLHGR LMGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.568 28 17 42 1.807 0.797 28 17 42 8.75 0.775 23.9 28 25 50 4 6.80 0.759 56.1 23 39 48 5 1.567 28 19 44 1.814 0.794 28 19 44 8.74 0.775 23.8 28 11 36 4 6.79 0.759 56.2 23 47 40 5 1.552 26 15 42 1.846 0.780 26 15 42 8.72 0.766 22.8 27 23 50 4 6.81 0.755 55.5 23 23 48 5 1.551 26 19 46 1.857 0.776 26 19 46 8.72 0.765 22.8 27 1i 38 4 6.80 0.754 55.5 23 47 24 5 1.551 27 15 36 1.867 0.771 27 15 26 8.40 0.744 23.7 27 25 48 4 9.71 0.744 27.6 28 25 50 4 1.549 27 13 36 1.872 0.769 27 25 16 8.40 0.743 23.7 27 13 36 4 9.63 0.743 28.4 28 11 36 4 1.549 27 25 46 1.875 0.768 27 25 48 8.48 0.738 22.0 27 21 50 4 9.70 0.743 27.5 27 11 38 4 1.546 27 25 48 1.880 0.766 27 47 26 8.48 0.738 22.0 27 11 40 4 9.70 0.743 27.6 27 23 12 4 1.528 27 13 42 1.883 0.765 26 17 34 8.37 0.738 23.3 26 11 34 4 6.79 0.740 53.8 23 25 10 5 1.527 27 15 44 1.884 0.764 27 15 18 8.36 0.738 23.3 26 27 50 4 6.79 0.739 53.8 23 9 26 5

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.32 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 11,000.0 MWdIMTU AREVA Inc.

Controlled Document AN P-3293N P Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-36 Cycle: 24 Core Average Exposure: M~d/MTUI 32201.2 Exposure: M~d/MTU (GWd) 11500.0 (1446.80)

Delta E: M~d/MTU, (G~d) 500.0 C 62.90) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %) MCPRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.172 5.402 19 0.301 0.548 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.314 12.296 20 0,252 0.265 3 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.652 24.351 21 0.364 0.716 7 42 21 0.765 29.302 22 0.631 0.788 13 48 20 0.855 32.209 23 1.238 1.352 13 40 2 6 10 14 18 22 26 30 34 38 S42 46 50 54 58 19 0.929 33.813 24 1.175 1.373 17 44 59 59 55 55 18 0.997 34.292 25 1.061 1.302 13 44 51 51 17 1.091 34.631 26 1.456 1.562 15 42 47 ....- 34 -.... -- 10 ....- 34 ....- 47 16 1.164 35.038 27 1.500 1.559 13 36 43 43 15 1.207 35.689 28 1.291 1.574 17 42 39 0 39 14 1.210 36.270 35 35 13 1.242 35.477 31 . 12 -.. .. -.. -- 0 ....- 12--------- 31 12 1.245 35.981 27 27 1i 1.256 36.816 23 0 23 10 1.271 37.538 19 19 9 1.290 38.010 15 ....- 34 ....- -- 10 ....- 34 ....- 15 8 1.304" 38.911 l1 11 7 1.282 39,880 7 7 6 1.252 40.769 3 3 5 1.208 41.454" 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.143 40.423 3 1.057 37.116 Control Rod Density: % 5.23 2 0.841 28.831 Bottom 1 0.252 8.611 k-effective: 0.99759 Void Fraction: 0.361 6 AXIAL TILT -11.685 -10.272 Core Delta-P: psia 21,723 AVG BOT 8ft/12ft 1.1391 1.1001 Core Plate Delta-P: psia 17.288 Coolant Temp: Deg-F 543.0 In Channel Flow: Mlb/Er 85. 64 Active Channel Flow: Mlb/hr 81.87 Total Bypass Flow (%): 10.8 (of total core flow)

Total Water Rod Flow (6): 3.9 (of total core flow)

Source Convergence 0.00047 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLH4GR LEGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.574 28 17 42 1.780 0.809 28 17 42 8.22 0.733 24.5 28 25 50 5 6.53 0.733 56.6 23 47 40 6 1.572 28 19 44 1.789 0.805 28 19 44 8.21 0.732 24.5 28 11 36 5 6.84 0.733 52.3 24 17 18 9 1.562 26 15 42 1.808 0,796 26 15 42 8.19 0.724 23.5 27 23 50 5 6.53 0.732 56.5 23 39 48 6 1.559 27 13 36 1.823 0,790 26 19 46 8.19 0.723 23.5 27 i1 38 5 6.58 0.729 55.4 23 17 40 10 1.559 27 15 36 1.831 0,786 27 15 26 7.94 0.708 24.4 27 25 48 5 6.54 0.727 55.7 23 23 48 6 1 .558 26 19 46 1.840 0.782 27 47 26 7.94 0.707 24.4 27 13 38 5 6.56 0.726 55.3 23 39 18 10 1 .546 27 25 46 1.843 0.781 27 15 18 7.86 0.703 24.8 26 27 12 5 6.53 0.726 55.7 23 47 24 6 1.545 27 25 48 1.844 0.781 27 47 42 7.86 0.702 24.7 26 11 34 5 6.65 0.724 53.9 23 15 40 10 1.539 27 13 42 1.849 0.779 27 17 16 8.00 0.702 22.8 27 21 50 5 6.79 0.723 51.8 24 15 16 9 1.538 27 15 44 1.850 0.778 26 17 34 8.00 0.702 22.8 27 11 40 5 6.62 0.721 53.8 23 39 16 10

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.33 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 11t,500.0 MWd/MTU AREVA Inc.

Controlled Document AN P-3293N P Revision 1 Page A-37 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 32651.2 Exposure: MWd/MTU (G~d) 11950.0 (1503.40)

Delta E: MWd/MTU, (G~d( 450.0 ( 56.61) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 9) N(PRA) Power Exposure Zone Avg. Max. ZR JR Core Pressure: psia 1015.0 Top 24 0.175 5.471 19 0.301 0.546 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.319 12.449 20 0.251 0.263 3 42 Flow: Mlb/hr 96.04 ( 96.00 9) 22 0.662 24.670 21 0.363 0.715 7 42 21 0.779 29.677 22 0.632 0.792 13 48 2 6 10 14 16 22 26 30 34 36 42 46 50 54 58 20 0.672 32.630 23 1.231 1.348 13 40 59 59 19 0.947 34.270 24 1.169 1.374 17 44 55 55 18 1.023 34.763 25 1.062 1.304 13 44 51 51 17 1.124 35.149 26 1.456 1.568 15 42 47 ....- 34-----------0 . 34 -.. .. 47 -.. 16 1.203 35.577 27 1.506 1.558 13 36 43 43 15 1.248 36.249 28 1.300 1.578 17 42 39-----------0 ... -- 0--------- 39 14 1.251 36.631 35-------------- 35 13 1.281 36.024 31----------10-----------0 .10--------- 31 -.. 12 1.281 36.530 27-------------- 27 11 1.288 37.370 23-----------0 ... -- 0--------- 23 10 1.296 36.099 19 19 9 1.306* 38.572 15 ....- 34-----------0 . 34 -.. .. 15 -.. 8 1.306 39.471 11 11 7 1.262 40.430 7 7 6 1.207 41.306 3 3 5 1.140 41.972*

2 6 10 14 16 22 26 30 34 36 42 46 50 54 56 4 1.059 40.913 3 0.969 37.569 Control Rod Density: % 5.27 2 0.772 29.192 Bottom 1 0.231 8.720 k-effective: 0. 99760 Void Fraction: 0.355 9 AXIAL TILT -9.306 -10.237 Core Delta-P: psia 21. 666 AVG BOT Sft/l2ft 1.1312 1.1002 Core Plate Delta-F: psia 17.231 Coolant Temp: Deg-F 542.9 In Channel Flow: Mlb/hr 85. 67 Active Channel Flow: Mlb/hr 81.92 Total Bypass Flow (%): 10.8 (of total core flow)

Total Water Rod Flow (9): 3.9 (of total core flow)

Source Convergence 0.00044 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Margin Exp. Value Margin Exp. FT ZR JR K Value FT IR JR Value Margin FT ZR JR Value F'T ZR 7? K 1.578 28 17 42 1.761 0.618 28 17 42 8.09 0.715 19.0 28 17 42 15 6.91 0.747 53.1 24 17 18 9 1 .577 28 19 44 1.768 0.614 28 19 44 8.09 0.715 18.9 28 19 44 15 6.68 0.746 56.2 23 17 40 10 1.568 26 15 42 1.780 0.809 26 15 42 7.99 0.706 18.9 26 27 36 15 6.66 0.744 56.1 23 39 18 10 1.568 26 19 46 1.790 0.804 26 19 46 7.99 0.706 18.9 26 25 34 15 6.75 0.741 54.6 23 47 40 9 1 .558 27 13 36 1.813 0.794 27 15 18 7.82 0.704 25.5 28 25 50 5 6.73 0.740 54.7 23 15 40 10 1.555 27 25 48 1.815 0.793 27 47 42 7.82 0.704 25.5 28 11 36 5 6.74 0.740 54.5 23 39 48 9 1.555 27 15 36 1.815 0.793 27 17 16 7.97 0.698 17.9 27 15 44 14 6.72 0.738 54.6 23 39 16 10 1.553 27 25 46 1.818 0.792 27 41 48 7.96 0.697 17.9 27 17 46 14 6.98 0.735 50.7 24 15 46 10 1.546 27 15 44 1.823 0.790 27 15 26 7.90 0.696 18.6 26 21 34 15 6.60 0.728 54.9 23 23 48 9 1.545 27 13 42 1.825 0.789 27 25 48 7.90 0.696 18.6 26 27 40 15 6.60 0.728 54.9 23 47 24 9 LHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.34 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 11,950.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-38 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTUJ 32652.2 Exposure: 84Wd/MTU (G~d) 11951.0 (1503.50)

Delta E: MWd/M4TU, (G~d) 1.0 ( 0.13) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.213 5.471 19 0.298 0.529 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.386 12.449 20 0.242 0.253 57 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.790 24.671 21 0.355 0.682 53 42 21 0.916 29.678 22 0.636 0.824 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.005 32.631 23 1.186 1.360 47 32 59 59 19 1.073 34.271 24 1.280 1.397 29 30 55 55 18 1.123 34.784 25 1.034 1.297 51 32 51 51 17 1.178 35.150 26 1.500 1.554 45 34 47 -~~~14----------14------- 47 16 1.218 35.578 27 1.439 1.534 23 26 43 43 15 1.232" 36.250 28 1.281 1.520 43 20 39 .14-----------6----------14---------

-.. 39 14 1.209 36.832 35 35 13 1.218 36.026 31 - 8-----------8--------- 31 12 1.203 36.531 27 27 11 1.199 37.371 23 .14-----------8----------14---------

-.. 23 10 1.203 38.100 19 19 9 1.215 38.573 15 -~~~14----------14------- 15 8 1.226 39.472 1i ll 7 1.205 40.431 7 7 6 1.164 41.307 3 3 5 1.104 41.973" 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.025 40.914 3 0.934 37.570 Control Rod Density: % 5.11 2 0.741 29.193 Bottom 1 0.221 8.720 k-effective: 0.99761 Void Fraction: 0.345 9 AXIAL TILT -3.652 -10.237 Core Delta-P: psia 21.525 AVG BOT 8ft/l2ft 1.0822 1.1002 Core Plate Delta-P: psia 17.091 Coolant Temp: Deg-F 542.8 In Channel Flow: Mlb/hr 85.75 Active Channel Flow: Mlb/hr 82.04 Total Bypass Flow (9): 10.7 (of total core flow)

Total Water Rod Flow (9): 3.9 (of total core flow)

Source Convergence 0.00043 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.554 26 45 34 1.768 0.814 26 43 28 8.35 0.739 19.1 27 23 26 15 7.33 0.765 49.8 24 31 32 15 1.552 26 33 16 1.769 0.814 26 33 18 8.35 0.739 19.1 27 25 24 15 7.13 0.748 50.2 24 23 24 15 1.550 26 43 28 1.790 0.805 26 45 34 8.38 0.738 18.4 26 29 28 15 6.97 0.747 52.3 24 39 24 14 1.548 26 33 18 1.793 0.803 26 33 16 8.38 0.737 18.4 26 27 30 15 6.95 0.745 52.4 24 23 40 14 1.534 27 23 26 1.794 0.803 26 41 26 8.17 0.722 18.9 26 27 26 15 6.91 0.728 50.7 23 39 26 14 1.534 27 25 24 1.796 0.802 26 35 20 8.17 0.722 18.9 26 25 28 15 6.97 0.728 49.9 24 39 40 15 1.534 26 31 28 1.798 0.801 28 41 18 8.11 0.715 18.6 26 19 26 15 6.93 0.726 50.2 24 33 34 15 1.533 26 41 26 1.801 0.800 28 17 20 8.10 0.714 18.6 26 25 20 15 6.89 0.726 50.7 23 25 40 14 1.532 26 35 20 1.804 0.798 26 31 28 8.00 0.703 18.3 26 17 28 15 7.07 0.725 47.9 24 25 26 15 1.532 26 33 30 1.805 0.798 26 33 32 7.99 0.703 18.3 26 19 22 15 6.72 0.711 51.0 24 31 26 15 LHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.35 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 11,951.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-39 Cycle: 24 Core Average Exposure: MWd/MTU 32701.2 Exposure: MWd/MTU (a~d) 1:2000.0 (1509.70 Delta E: MWd/MTU, (GWd) 49.0 C 6.16) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 8) NM(PBA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.213 5.480 19 0.298 0.530 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.385 12.469 20 0.242 0.253 57 42 Flow: Mlb/hr 96.04 C96.00 8) 22 0.787 24.713 21 0.355 0.683 53 42 21 0.913 29.727 22 0.636 0.826 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.005 32.685 23 1.186 1.362 47 32 19 1.075 34.328 24 1.277 1.392 31 32 59 59 55 S ~ 55 18 1.127 34.844 25 1.035 1.299 51 32 51 51 17 1.183 35.211 26 1.500 1.557 45 34 47 -~14--------- 14 - 47 16 1.224 35.640 27 1.440 1.531 37 36 43 43 15 1.238* 36.312 28 1.283 1.522 43 42 39 .... 14-----------6 -- 14----------39 14 1.214 36.893 35 13 1.223 -~35 36.064 31 12 1.207 -~31 36.589 27 11 1.202 -~27 37.429 23 .... 14-----------6 -- 14----------23 10 1.206 38.158

+/-

9 1.217 38.631

.5----------14----------14------- 15 8 1.226 39.529 7 1.203 40.487 7 7 6 1.159 41.362 3 3 5 1.097 42.024k 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 1.017 40.962 3 0.926 37.614 5.13 2 0.734 29.227 Control Rod Density: %

Bottom 1 0.220 8.731 k-effective: 0.99757 Void Fraction: 0.344 8 AXIAL TILT -3.450 -10.221 Core Delta-P: psia 21.522 AVG BDT 8ft/l2ft 1.0820 1.1002 Core Plate Delta-P: psia 17.088 Coolant Temp: Deg-F 542.8 In Channel Flow: Mlb/hr 85.75 Active Channel Flow: Mlb/hr 82.04 Total Bypass Flow (8): 10.7 (of total core flow)

Total Water Rod Flow (%): 3.9 (of total core flow)

Source Convergence 0.00039 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR C? Value Margin FT IR C? Value Margin Exp. FT IR Value Margin Exp. FT IR JR K C? R 1.557 26 45 34 1.764 0.817 26 43 34 8.37 0.741 19.1 27 37 36 15 7.34 0.767 49.9 24 31 32 15 1.552 26 43 34 1.774 0.812 26 33 18 8.36 0.740 19.1 27 35 38 15 6.98 0.749 52.4 24 39 24 14 1.549 26 33 46 1.784 0.807 26 45 34 8.40 0.740 18.5 26 31 34 15 7.13 0.749 50.3 24 23 24 15 1.542 26 33 44 1.791 0.804 26 41 36 8.40 0.739 18.5 26 33 32 15 6.97 0.748 52.5 24 23 40 14 1.534 26 41 36 1.794 0.803 26 33 46 8.18 0.724 19.0 26 25 34 15 7.00 0.732 49.9 24 39 40 15 1.531 27 37 36 1.796 0.802 28 17 42 8.18 0.724 19.0 26 27 26 15 6.92 0.730 50.8 23 39 26 14 1.528 26 33 32 1.800 0.800 28 41 18 8.15 0.719 18.7 26 41 36 15 6.91 0.729 50.8 23 25 40 14 1.527 27 35 38 1.801 0.800 26 25 42 8.12 0.717 18.7 26 25 42 15 6.94 0.729 50.3 24 33 34 15 1.527 26 31 34 1.806 0.797 26 33 32 8.05 0.708 18.4 26 43 34 15 7.07 0.725 48.0 24 25 26 15 1.526 26 35 42 1.807 0.797 26 31 34 8.03 0.707 18.4 26 41 40 15 6.77 0.714 50.8 23 15 32 14

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.36 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 12,000.0 MWd/M*TU AREVA Inc.

Controlled Documen ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-40 Cycle: 24 Core Average Exposure: M~d/MTU 33201.9 Exposure: M~d/MTU CG~d) 12500.0 (1572.60)

Delta E: M~d/MTUJ, (G~d) 500.0 (62.90) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %) M(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.217 5.576 19 0.298 0.531 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.393 12.678 20 0.242 0.253 57 42 Flow: Mlb/hr 96.04 C98.00 9) 22 0.805 25.146 21 0.355 0.685 53 42 21 0.937 30.231 22 0.638 0.826 13 48 2 6 10 14 18 22 26 30 34 38 20 1.034 33.242 23 1.182 1.355 47 32 42 46 50 54 58 59 -- 59 19 1.109 34.928 24 1.263 1.366 31 32 55 55 18 1.164 35.471 25 1.038 1.304 51 32 51 51 17 1.223 35.845 26 1.498 1.559 45 34 47----------14 ... -- 14----------47 16 1.265 36.280 27 1.448 1.525 45 36 43 43 15 1.278* 36.960 28 1.294 1.525 43 42 39----------14-----------6 14----------39 -... 14 1.252 37.528 35-------------- 13 -~351.258 36.892 31-----------8 ... -- 8----------31 12 1.239 37.188 27-------------- 11 -~271.229 38.025 23----------14-----------6 .... 14----------23 10 1.226 38.754 19 19 9 1.226 39.223 15----------14 ... -- 14----------15 8 1.219 40.112 ii 1i 7 1.172 41.053 7 7 6 1.104 41.901 3 3 5 1.022 42.529*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.929 41.426 3 0.837 38.034 Control Rod Density: % 2 0.665 29.561 5.13 Bottom 1 0.199 8.831 k-effective: 0.99758 Void Fraction: 0.337 9 AXIAL TILT -0.549 -10.036 Core Delta-P: psia 21.456 AVG BOT Sft/l2ft 1.0699 1.0994 Core Plate Delta-P: psia 17. 022 Coolant Tamp: Deg-F 542.6 In Channel Flow: Mlb/hr 85.79 Active Channel Flow: Mlb/hr 62.10 Total Bypass Flow (8): 10.7 (of total core flow(

Total Water Rod Flow (8): 3.9 (of total core flow(

Source Convergence 0. 00036 Top Ten Thermal Limits Summary - Sorted hy Margin Power MCPR APLHIGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT 1K JR K 1.559 26 45 34 1.755 0.620 26 43 34 6.53 0.758 19.6 26 31 34 15 7.37 0.776 50.8 24 31 32 15 1.551 26 33 16 1.763 0.817 26 45 34 6.52 0.756 19.6 26 33 32 15 7.11 0.761 52.2 24 39 24 15 1.550 26 43 34 1.765 0.816 26 33 16 8.46 0.756 20.2 27 37 36 15 7.17 0.760 51.3 24 23 24 15 1.541 26 33 16 1.772 0.812 26 33 16 8.45 0.755 20.2 27 35 38 15 7.10 0.760 52.2 24 23 40 15 1.534 26 49 32 1.763 0.806 28 17 42 8.35 0.744 19.8 26 41 36 15 7.09 0.749 50.9 24 39 40 15 1.532 26 49 34 1.765 0.607 26 41 18 6.32 0.741 18.7 26 35 42 15 6.97 0.743 51.8 23 39 26 14 1.527 26 31 12 1.786 0.606 26 41 36 8.30 0.741 20.1 26 35 34 15 6.96 0.741 51.8 23 25 40 14 1.527 26 41 36 1.795 0.802 26 35 20 8.29 0.740 20.1 26 33 26 15 6.98 0.740 51.3 24 33 34 15 1.526 26 33 12 1.800 0.800 26 41 40 8.31 0.736 19.4 26 43 34 15 7.11 0.736 49.0 24 25 26 15 1.525 27 45 36 1.606 0.797 26 39 42 8.27 0.734 19.4 26 33 44 15 6.90 0.735 51.7 23 15 32 14

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.37 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 12,500.0 MWd/IMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-41 Cycle: 24 Core Average Exposure: MWd/MTU 33701.2 Exposure: MWd/MTUJ (GWd) 13000.0 (1635.50)

Delta E: MWd/MTU, (GWd) 500.0 ( 62.90) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 8) N(PPA) Power Exposure Zone Avg. Max. IRJR Core Pressure: psia 1015.0 Top 24 0.226 5.672 19 0.298 0.533 39 6 Inlet Subcooling: Btu/lbm -24.74 23 0.409 12.890 20 0.241 0.252 57 42 Flow: Mlb/hr 96.04 ( 98.00 8) 22 0.841 25.583 21 0.354 0.691 41 8 21 0.984 30.742 22 0.639 0.829 47 14 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.082 33.807 23 1.181 1.357 33 14 59 59 19 1.158 35.532 24 1.251 1.343 31 30 55 55 18 1.213 36.108 25 1.040 1.313 31 10 51 51 17 1.271 36.490 26 1.495 1.569 33 16 47----------14----------14------- 47 16 1.306 36.932 27 1.453 1.544 35 14 43 43 15 1.313* 37.618 28 1.304 1.537 41 18 39----------14-----------8-------14----- 39 14 1.282 38.173 35--------------------------- 35 13 1.285 37.309 31----------8------8-------- 31 12 1.260 37.795 27--------------------------- 27 11 1.244 38.627 23----------14-----------8-------14----- 23 10 1.231 39.354 19 19 9 1.220 39.817 15----------14----------16------- 15 8 1.196 40.692 1i ii 7 1.129 41.612 7 7 6 1.041 42.427 3 3 5 0.942 43.016*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.841 41.869 3 0.750 38.433 5.06 2 0.596 29.877 Control Rod Density: %

Bottom 1 0.178 8.926 k-effective: 0.99753 Void Fraction: 0.329 8 AXIAL TILT 3.098 -9.834 Core Delta-P: psia 21.374 AVG SOT Sft/l2ft 1.C0510 1.0985 Core Plate Delta-P: psia 16.940 Coolant Temp: Deg-F 542.4 In Channel Flow: Mlb/hr 85.84 Active Channel Flow: Mlb/hr 82.17 Total Bypass Flow (8): 10.6 (of total core flow)

Total Water Rod Flow (8): 3.8 (of total core flow)

Source Convergence 0.00028 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT 1R JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.569 26 33 16 1.722 0.836 26 33 16 8.58 0.770 20.7/ 26 35 20 15 7.33 0.782 51.9 24 31 32 15 1.557 26 45 28 1.737 0.829 26 33 18 8 .60 0.770 20.4 26 33 18 15 7.35 0.774 50.7 23 39 18 17 1.553 26 33 18 1.74 6 0.825 28 41 18 8.52 0.768 21.3 27 35 24 15 7.24 0.774 52.1 24 39 24 16 1.552 26 33 12 1.751 0.822 26 45 28 8.55 0.768 20.7 26 31 28 15 7.14 0.765 52.3 24 23 24 15 1.548 26 31 12 1.753 0.821 26 43 28 8.55 0.767 20.7 26 33 30 15 7.06 0.764 53.2 24 23 40 15 1.544 27 35 14 1.754 0.821 27 35 14 8.50 0.767 21.3 27 37 26 15 7.28 0.762 50.0 23 39 16 18 1.543 26 43 28 1.762 0.817 28 43 20 8.53 0.764 20.4 26 39 20 15 7.07 0.760 52.5 23 31 18 15 1.542 27 35 16 1.764 0.816 26 39 20 8.48 0.762 20.8 26 41 26 15 7.11 0.758 51.9 24 39 40 15 1.541 26 49 32 1.7 67 0.815 27 35 16 8.54 0.760 19.8 26 33 16 15 7.04 0.756 52.6 23 31 16 14 1.540 26 49 34 1.767 0.815 26 35 20 8.48 0.760 20.5 26 43 28 15 7.09 0.753 51.5 23 39 26 15

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction 8 CPR limit type 3 Figure A.38 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 13,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-42 Cycle: 24 Core Average Exposure: MWd/MTU 34201.2 Exposure: MWd/MTU (G94d) 13500.0 (1698.40)

Delta F: MD~d/MTUJ, (G~d) 500.0 C 62.90) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 %) M(PRA) Power Exposure Zone Avg. Max. 1R JR Core Pressure: psia 1015.0 Top 24 0.234 5.772 19 0.289 0.535 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.423 13.110 20 0.242 0.254 3 42 Flow: Mlb/hr 96.04 ( 96.00 9) 22 0.871 26.041 21 0.356 0.693 7 42 21 1.024 31.277 22 0.642 0.830 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.130 34.398 23 1.181 1.352 47 28 59 59 19 1.212 36.165 24 1.231 1.332 43 18 55 55 18 1.273 36.772 25 1.046 1.320 51 32 51 51 17 1.339 37.160 26 1.485 1.561 45 28 47 -- -~16 14----- 47 16 1.358* 37.604 27 1.462 1.544 47 26 43 43 15 1.353 38.294 28 1.318 1.543 11 36 39 .16----------.. 8 -- ....- 16 -- -- 39 14 1.312 38.833 35 -- 35 13 1.311 37.939 31 8 -- -- 31 12 1.279 38,413 27 -- 27 1i 1.254 39.237 23 .16----------.. 8 -- .. . 16 -- -- 23 10 1.232 39.958 19 19 9 1.207 40.408 15 -- -~14 16----- 15 8 1.166 41.262 i1 11 7 1.079 42.149 7 7 6 0.974 42.922 3 3 5 0.862 43.464*

2 6 10 14 18 22 26 30 34 4 0.754 42.269 38 42 46 50 54 58 3 0.666 38.791 2 0.529 30.161 Control Rod Density: 8 4 .94 Bottom 1 0.158 9.012 k-effective: 0.99750 Void Fraction: 0.320 9 AXIAL TILT 6. .995 -9.585 Core Delta-P: psia 21.291 AVG BOT eft/l2ft 1.C )309 1.0975 Core Plate Delta-P: psia 16. 857 Coolant Temp: Deg-F 542.2 In Channel Flow: Mlb/hr 85.89 Active Channel Flow: Nib/hr 62.25 Total Bypass Flow (8): 10.6 (of total core flow)

Total Water Rod Flow (9): 3.8 (of total core flow)

Source Convergence 0.00045 Top Ten Thermal Limits Sussmary - Sorted by Margin Power MCPR APLHGR LHGR Value FT 1K JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT TR JR K 1.561 26 45 28 1.719 0.855 26 45 26 8.68 0.785 21.5 26 43 28 15 7.51 0.801 51.8 23 17 40 17 1.561 26 11 34 1.730 0.850 26 33 16 8.69 0.782 20.9 26 45 28 15 7.50 0.798 51.7 23 39 18 17 1.558 26 49 32 1.737 0.846 26 43 29 8.63 0.780 21.5 26 33 18 15 7.39 0.793 52.5 24 39 24 17 1.554 26 33 16 1.739 0.845 27 47 26 8.67 0.779 20.8 28 17 42 17 7.39 0.793 52.5 24 23 40 17 1.553 26 33 12 1.741 0.844 26 49 34 8.58 0.779 21.9 26 41 26 15 7.45 0.798 51.0 23 15 40 18 1.548 26 31 12 1.742 0.844 26 17 42 8.67 0.778 20.7 28 19 44 17 7.47 0.787 50.7 23 15 24 18 1.544 27 47 26 1.742 0.844 28 41 18 8.60 0.778 21.6 26 41 22 15 7.41 0.783 51.0 23 39 16 18 1.543 28 11 36 1.746 0.842 26 27 44 8.59 0.777 21.5 26 39 20 15 7.37 0.779 51.0 24 39 40 17 1.538 27 35 14 1.750 0.840 26 49 32 8.63 0.776 20.9 26 33 16 15 7.27 0.777 52.0 23 23 46 16 1.538 26 43 28 1.750 0.840 27 25 49 8.56 0.776 21.9 26 35 20 15 7.19 0.776 52.9 24 31 32 15

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction 6 CPR limit type 3 Figure A.39 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 13,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-43 Cycle: 24 Core Average Exposure: MWd/MTU 34301.2 Exposure: MWd/MTU (GWd( 13600.0 (1711.00)

Delta E: M~d/MTUJ, (GD~d) 100.0 ( 12.58) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %( M(PRA( Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.235 5.793 19 0.300 0.534 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.426 13.155 20 0.242 0.254 3 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.878 26.135 21 0.356 0.692 7 42 21 1.033 31.389 22 0.642 0.828 13 48 2 6 10 14 18 22 26 30 34 36 42 46 50 54 58 20 1.141 34.522 23 1.181 1.349 13 28 59 59 19 1.224 36.298 24 1.227 1.330 17 18 55 55 18 1.286 36.911 25 1.047 1.320 9 32 51 51 17 1.354 37.301 26 1.483 1.562 11 34 47----------16 ... -- 14------- 47 16 1.370* 37.744 27 1.463 1.543 47 26 42 43 15 1.361 38.433 28 1.321 1.543 11 36 39----------16-----------8 .16--------- 39 -.. 14 1.318 38.968 35-------------- 35 13 1.316 38.067 31-----------8 ... -- 8--------- 31 12 1.283 38.539 27-------------- 27 11 1.256 39.360 23----------16-----------8 .16--------- 23 -.. 10 1.231 40.079 19 19 9 1.203 40.525 15----------16 ... -- 16------- 15 8 1.158 41.373 Ii 11 7 1.068 42.252 7 7 6 0.959 43.015 3 3 5 0.845 43.546*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.737 42.341 3 0.649 38.854 Control Rod Density: % 4 .92 2 0.515 30.212 Bottom 1 0.154 9.027 k-effective: 0. 99753 Void Fraction: 0.319 %AXIAL TILT 7.847 -9.525 Core Delta-P: psia 21.273 AVG BOT 8ft/l2ft 1.0265 1.0972 Core Plate Delta-P: psia 16.839 Coolant Tamp: Deg-F 542.2 In Channel Flow: Mlb/hr 85.90 Active Channel Flow: Mlb/hr 82.26 Total Bypass Flow (8): 10.6 (of total core flow)

Total Water Rod Flow (%): 3.8 (of total core flow(

Source Convergence 0.00050 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHiGR LMGR Value FT Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K IR JR 1.562 26 i1 34 1.722 0.854 26 45 28 8.68 0.786 21.8 26 43 28 15 7.52 0.803 52.0 23 17 40 17 1.559 26 33 12 1.723 0.853 26 33 16 8.68 0.786 21.7 26 33 18 15 7.52 0.802 51.9 23 39 18 17 1.559 26 11 32 1.739 0.846 26 49 34 8.70 0.784 21.2 26 45 28 15 7.55 0.797 50.9 23 15 24 18 1.558 26 45 28 1.739 0.845 26 17 28 8.70 0.784 21.1 26 33 16 15 7.54 0.796 50.9 23 23 16 18 1.557 26 33 16 1.740 0.845 27 47 26 8.71 0.784 21.0 28 17 20 17 7.39 0.795 52.7 24 39 24 17 1.556 26 31 12 1.741 0.845 26 27 18 8.71 0.783 20.9 28 19 18 17 7.38 0.794 52.7 24 23 40 17 1.543 28 11 36 1.743 0.843 28 41 18 8.64 0.780 21.3 26 19 22 16 7.47 0.791 S1.3 23 15 40 18 1.543 27 47 26 1.745 0.842 28 17 42 8.57 0.779 22.1 26 41 26 15 7.44 0.788 S1.2 23 39 16 18 1.542 27 35 14 1.745 0.842 27 15 26 8.64 0.779 21.3 26 21 20 16 7.53 0.782 49.3 24 17 26 17 1.541 28 35 12 1.747 0.842 26 49 32 8.57 0.779 22.1 26 35 20 15 7.52 0.780 49.3 24 25 18 17

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.40 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 13,600.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-44 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 34302.2 Exposure: MWd/84TU (GWd) 13601.0 (1711.10)

Delta F: MWd/MTU, (GWci) 1.0 C 0.13) Axial Profile Edit Radial Power Power: MWL 2957.0 (100.00 6) N(PRA) Power Exposure Zone Avg. Max. 12 JR Core Pressure: psia 1015.0 Top 24 0.209 5.793 19 0.297 0.540 55 40 Inlet Subcooling: Btu/ibm -24.74 23 0.377 13.156 20 0.246 0.257 3 42 Flow: Mlb/hr 96.04 ( 98.00 %) 22 0.774 26.136 21 0.360 0.710 53 42 21 0.905 31.390 22 0.641 0.855 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.009 34.523 23 1.208 1.350 47 40 59 59 19 1.090 36.299 24 1.170 1.372 17 18 55 55 18 1.151 36.913 25 1.064 1.314 47 44 51 51 17 1.240 37.303 26 1.447 1.583 15 42 47 6 47 16 1.304 37.745 27 1.517 1.570 15 44 43 43 15 1.332 38.434 28 1.329 1.580 17 42 39 --...-12 12--------- 39 14 1.320 38.969 35 35 13 1.341* 38.068 31 6----------6 31 12 1.325 38.540 27 27 1i 1.312 39.361 23 -12

--... 12--------- 23 10 1.295 40.080 19 19 9 1.271 40.526 15 6 15 8 1.231 41.374 11 1I 7 1.147 42.253 7 7 6 1.045 43.016 3 3 5 0.940 43.547*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.839 42.342 3 0.754 38.855 Control Rod Density: 8 4.17 2 0.606 30.212 Bottom 1 0.183 9.027 k-effective: 0.99751 Void Fraction: 0.333 % AXIAL TILT 0.428 -9.524 Core Delta-P: psia 21.437 AVG HOT 8ft/l2ft 1.0778 1.0972 Core Plate Delta-P: psia 17.005 Coolant Temp: Deg-F 542.5 In Channel Flow: Mlb/hr 85.80 Active Channel Flow: Mlb/hr 82.12 Total Bypass Flow (8): 10.7 (of total core flow)

Total Water Rod Flow (8): 3.8 (of total core flow)

Source Convergence 0.00046 lop Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LUGR Value FT 12 JR Value Margin FT 12 JR Value Margin Exp. FT IR JR K Value Margin Exp. FT 12 JR K 1.583 26 15 42 1.719 0.855 26 15 42 8.47 0.771 22.3 28 43 42 15 6.80 0.763 56.6 23 15 40 11 1.582 26 19 46 1.724 0.853 26 41 16 8.47 0.771 22.3 28 19 44 15 6.80 0.763 56.5 23 39 16 1i 1.580 28 17 42 1.729 0.850 27 15 18 8.43 0.760 21.1 26 45 42 15 7.05 0.762 53.2 23 31 40 15 1.579 28 19 44 1.730 0.850 27 17 16 8.43 0.759 21.0 26 19 46 15 7.05 0.762 53.2 23 39 32 15 1.570 27 15 44 1.734 0.848 28 17 42 8.33 0.750 21.1 27 45 44 15 6.80 0.759 56.1 23 17 40 13 1.569 27 17 46 1.738 0.846 28 41 18 8.33 0.750 21.0 27 43 46 15 6.82 0.759 55.8 23 47 40 11 1.565 27 13 42 1.746 0.842 27 47 42 8.25 0.748 21.7 27 45 36 15 6.66 0.759 57.9 23 39 18 1i 1.564 27 19 48 1.748 0.841 27 41 48 8.25 0.747 21.7 27 25 46 15 6.81 0.757 55.7 23 39 48 11

1. 555 27 13 36 1.777 0.827 27 25 48 8.18 0.742 21.9 26 23 44 15 6.76 0.755 56.1 23 47 24 i1 1.554 27 25 48 1,778 0.827 27 47 26 8.17 0.742 21.9 26 43 38 15 6.76 0.755 56.1 23 23 48 i1

+

LHDR calculated COR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.41 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 13,601.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-45 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 34701.2 Exposure: M~d/MTU CG~d) 14000.0 (1761.30)

Delta E: M~d/MTU, (GWd) 399.0 C 50.20) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.226 5.867 19 0.297 0.540 55 40 Inlet Subcooling: Stu/lbm -24 .74 23 0.409 13.318 20 0.244 0.256 57 42 Flow: Mlb/hr 96.04 C 98.00 %) 22 0.840 26.472 21 0.359 0.708 53 42 21 0.990 31.784 22 0.640 0.846 47 48 34 38 42 46 50 54 58 20 1.097 34.963 23 1.213 1.342 47 40 2 6 10 14 18 22 26 30 19 1.166 36.774 24 1.167 1.362 43 44 59 59 55 55 18 1.219 37.415 25 1.061 1.304 47 44 51 51 17 1.289 37.825 26 1.447 1.573 45 42 47 -1i0 47 16 1.335 38.281 27 1.513 1.562 47 36 43 43 15 1.350* 38.982 28 1.333 1.569 43 42 39 -12

....- -- 14--------- 39 14 1.328 39.511 35 35 13 1.344 38.593 31 .. .. 10-----------6 0--------- 31 -1.. 12 1.322 39.058 27 27 11 1.300 39.874 23 -14

....- -- 14--------- 23 10 1.274 40.586 19 19 9 1.240 41.018 15 -1i0 15 8 1.187 41.843 ii 11 7 1.090 42.690 7 7 6 0.978 43.413 3 3 5 0.865 43.904k 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.761 42.661 3 0.678 39.142 Control Rod Density: 6 2 0.545 30.443 3.91 Bottom 1 0.165 9.097 k-effective: 0.99748 Void Fraction: 0.324 6 AXIAL TILT 4.945 -9.363 Core Delta-P: psia 21.334 AVG BOT Sft/12ft 1.0476 1.0967 Core Plate Delta-P: psia 16. 903 Coolant Temp: Deg-F 542.3 In Channel Flow: Mlb/hr 85.86 Active Channel Flow: Mlb/hr 82.21 Total Bypass Flow (6): 10.6 (of total core flow)

Total Water Rod Flow (6): 3.8 (of total core flow)

Source Convergence 0. 00046 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHRR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.573 26 45 42 1.721 0.654 26 41 16 8.55 0.785 23.1 28 43 20 15 7.97 0.804 46.4 24 37 36 19 1.572 26 19 16 1.727 0.851 27 17 16 8.55 0.784 23.1 28 41 18 15 7.87 0.800 47.2 24 39 38 19 1.569 28 43 42 1.728 0.851 27 15 16 8.54 0.775 21.9 26 45 42 15 7.86 0.799 47.2 24 37 40 19 1.568 28 19 16 1.728 0.851 26 45 42 8.54 0.774 21.9 26 41 16 15 7.87 0.791 46.1 24 39 40 19 1.562 27 47 36 1.736 0.847 28 41 18 8.42 0.764 21.9 27 45 44 15 7.16 0.773 53.0 23 39 32 17 1.561 27 25 14 1.741 0.844 26 43 42 6.42 0.764 21.8 27 43 16 15 7.12 0.768 53.0 23 31 40 17 1.557 27 45 44 1.744 0.843 27 47 42 8.36 0.763 22.6 27 45 36 15 6.98 0.767 54.6 23 39 18 15 1.556 27 47 42 1.747 0.842 27 41 48 8.36 0.763 22.5 27 35 16 15 7.07 0.766 53.3 24 31 24 17 1.556 27 17 16 1.757 0.837 27 47 26 8.39 0.760 21.7 27 47 36 15 7.01 0.765 54.0 23 47 40 14 1.555 27 19 14 1.765 0.833 *27 49 24 8.39 0.760 21.7 27 35 14 15 7.00 0.763 53.9 23 39 48 14

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.42 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 14,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Page A-46 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTU 35201.2 Exposure: M4Wd/MTU (GdM) 14500.0 (1824.20)

Delta E: M9Qd/MTU, (GWd) 500.0 ( 62.90) Edit Radial Power Axial Profile Power: M~t 2957.0 (100.00 %) NM(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.216 5.967 19 0.289 0.527 55 40 Inlet Subcooling: Btu/lbm -24.74 23 0.391 13.536 20 0.237 0.246 57 42 Flow: Mlb/hr 96.04 C 98.00 8) 22 0.805 26.929 21 0.349 0.693 53 42 21 0.950 32.323 22 0.626 0.829 13 46 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.052 35.563 23 1.203 1.320 47 40 59 59 19 1.134 37.412 24 1.236 1.353 43 44 55 55 16 1.204 38.083 25 1.041 1.283 47 44 51 51 17 1.294 36.504 26 1.455 1.562 45 42 47 47 16 1.353 38.969 27 1.506 1.540 45 44 43 43 15 1.377 39.677 28 1.318 1.575 43 42 39 39 14 1.363 40.195 35 35 13 1.389* 39.252 31 31 12 1.368 39.706 27 27 11 1.342 40.511 23 23 10 1.307 41.210 19 19 9 1.263 41.619 15 15 8 1.199 42.409 11 1i 7 1.091 43.209 7 7 6 0.968 43.879 3 3 5 0.847 44.316*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.739 43.024 3 0.657 39.465 Control Rod Density: 8 2.38 2 0.531 30.702 Bottom 1 0.162 9.176 k-effective: 0.997468 Void Fraction: 0.323 % AXIAL TILT 4.389 -9.101 Core Delta-F: psia 21.358 AVG BDT 8ft/l2ft 1.0596 1.0956 Core Plate Delta-F: psia 16. 931 Coolant Tamp: Deg-F 542.2 In Channel Flow: Mlb/hr 85.84 Active Channel Flow: Mlb/hr 82.18 Total Bypass Flow (6): 10.6 (of total core flow)

Total Water Rod Flow (6): 3.8 (of total core flow)

Source Convergence 0.00050 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Exp. FT IR JR K Value Margin FT IR JR Value Margin Exp. FT IR C? K Value Margin 1.575 28 43 42 1.721 0.854 28 17 42 8.71 0.807 24.3 28 43 42 15 7.14 0.802 56.6 23 17 40 14 1.575 28 41 44 1.725 0.852 28 41 18 8.70 0.807 24.3 28 41 44 15 7.14 0.801 56.6 23 39 18 14 1.562 26 45 42 1.732 0.849 26 15 42 8 .61 0.794 23.7 26 41 40 15 7.09 0.799 57.0 24 23 40 14 1.562 26 41 46 1.737 0.846 26 41 16 8.61 0.794 23.6 26 39 42 15 7.09 0.798 56.9 24 39 24 14 1.540 27 45 44 1.745 0.842 27 15 18 8.57 0.786 23.0 26 45 42 15 7.19 0.790 54.6 24 39 40 15 1.539 27 43 46 1.746 0.842 27 17 16 8.57 0.785 23.0 26 41 46 15 6.99 0.789 57.2 23 39 18 12 1.537 27 47 42 1.767 0.832 27 47 42 8.49 0.784 23.9 26 43 38 15 6.98 0.789 57.2 23 15 40 12 1.536 27 41 48 1.768 0.832 27 41 48 8.48 0.784 24.0 26 35 42 15 7.21 0.786 53.9 24 41 42 14 1.536 27 47 36 1.781 0.825 27 25 48 8.48 0.784 24.0 26 41 36 15 7.01 0.778 55.6 23 31 40 15 1.535 27 35 48 1.781 0.825 26 41 40 8.50 0.784 23.8 26 37 44 15 7.05 0.778 55.0 24 23 24 15

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.43 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 14,500.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-47 Cycle: 24 Core Average Exposure: MWd/MTUJ 35701.2 Exposure: M~d/MTU (Gda) 15000.0 (1887.10)

Delta E: MO~d/MTUI, (G~d) 500.0 ( 62.80) Axial Profile Edit Radial Power Power: MWt 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.239 6.063 19 0.290 0.526 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.432 13.748 20 0.236 0.246 57 42 Flow: Mlb/hr 96.04 ( 98.00 8) 22 0.892 27.367 21 0.347 0.689 53 42 21 1.081 32.840 22 0.627 0.812 13 48 2 6 10 14 18 22 28 30 34 38 42 46 50 54 58 20 1.183 36.138 23 1.219 1.305 47 38 59 59 19 1.264 38.032 24 1.218 1.325 43 44 55 55 18 1.318 38.742 25 1.038 1.261 47 44 51 51 17 1.383 39.187 26 1.454 1.534 45 20 47 -~~~~~16----------- 47 16 1.405* 39.665 27 1.496 1.548 47 26 43 43 15 1.399 40.385 28 1.325 1.540 43 20 39 39 14 1.364 40.897 35 35 13 1.378 39.932 31 .16----------12----------16---------

-.. 31 12 1.344 40.376 27 27 11 1.305 41.168 23 23 10 1.260 41.851 19 19 9 1.204 42.231 15 -~~~~18----------- 15 8 1.127 42.980 ii 11 7 1.007 43.729 7 7 6 0.676 44.340 3 3 5 0.751 44.720*

2 6 10 14 18 22 26 30 34 38 42 48 50 54 58 4 0.644 43.376 3 0.567 39.778 2 0.458 30.956 Control Rod Density: % 1. 93 Bottom 1 0.139 9.254 k-effective: 0.99736 Void Fraction: 0.310 % AXIAL TILT 10.987 -8.855 Core Delta-P: psia 21.216 AVG BDT 8ft/l2ft 1.0142 1.0947 Core Plate Delta-P: psia 16.790 Coolant Tamp: Deg-F 541. 9 In Channel Flow: Mlb/hr 85. 92 Active Channel Flow: Mlb/hr 82.30 Total Bypass Flow (%6( 10.5 (of total core flow)

Total Water Rod Flow (6): 3.8 (of total core flow)

Source Convergence 0.00044 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLIIGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.548 27 47 26 1.725 0.852 27 47 26 8.65 0.810 25.4 28 43 20 15 7.58 0.819 53.1 23 31 16 18 1.548 27 25 14 1.727 0.851 27 25 48 8.65 0.809 25.3 28 41 18 15 7.56 0.818 53.2 23 15 32 18 1.540 28 43 20 1.736 0.847 27 25 16 8.63 0.796 23.8 27 35 14 15 7.64 0.812 51.5 23 47 32 18 1.540 28 41 18 1.738 0.846 27 15 26 8.56 0.796 24.7 27 35 16 15 7.63 0.810 51.5 23 31 48 18 1.540 28 49 36 1.741 0.845 28 49 26 8.61 0.795 23.9 27 47 36 15 7.15 0.803 56.6 23 39 18 15 1.539 28 25 12 1.742 0.844 28 25 50 8.55 0.795 24.7 27 45 26 15 7.33 0.803 54.4 23 39 32 17 1.534 26 45 20 1.743 0.843 28 41 18 8.54 0.795 24.7 26 41 22 15 7.33 0.803 54.3 23 31 40 17 1.533 26 41 16 1.744 0.843 28 17 42 8.54 0.795 24.7 26 39 20 15 7.14 0.802 56.7 23 17 40 15 1.528 27 25 16 1.755 0.838 26 41 16 8.51 0.793 24.9 26 37 18 15 7.26 0.798 54.6 23 31 18 17 1.528 27 45 26 1.757 0.837 26 15 42 8.51 0.793 24.9 26 43 24 15 6.15 0.797 43.2 24 31 32 20

LHOR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.44 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 15,000.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-48 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: M~d/MTU 35951.2 Exposure: M~d/MTtJ (G~d) 15250.0 (1918.60)

Delta E: M~d/MTUT, (GWd) 250.0 ( 31.45) Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.224 6.116 19 0.289 0.522 55 40 Inlet Subcooling: Btu/lbm -24 .74 23 0.404 13.864 20 0.232 0.242 57 42 Flow: Mlb/hr 96.04 ( 98.00 6) 22 0.834 27.609 21 0.342 0.679 53 42 21 0.993 33.129 22 0.624 0.793 13 48 20 1.108 36.461 23 1.260 1.329 33 14 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 19 1.191 38.377 24 1.179 1.295 43 44 59 59 55 55 18 1.254 39.102 25 1.031 1.296 51 32 51 51 17 1.336 39.551 26 1.455 1.563 33 12 47 47 16 1.386 40.027 27 1.487 1.579 25 14 43 43 15 1.401 40.746 28 1.331 1.567 25 12 39 39 14 1.382 41.248 35 35 13 1.410* 40.270 31 31 12 1.384 40.705 27 27 11 1.347 41.488 23 23 10 1.300 42.160 19 19 9 1.241 42.523 15 15 8 1.162 43.249 ii 1i 7 1.039 43.969 7 7 6 0.907 44.549 3 3 5 0.782 44.898*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.876 43.530 3 0.601 39.913 Control Rod Density: 6 2 0.489 31.065 0.49 Bottom 1 0.150 9.287 k-effective: 0. 99768 Void Fraction: 0.316 6 AXIAL TILT 7.684 -8.688 Core Delta-P: psia 21.293 AVG BDT eft/l2ft 1.0410 1.0940 Core Plate Delta-P: psia 16.871 Coolant Temp: Deg-F 542.0 In Channel Flow: Mlb/hr 85.87 Active Channel Flow: Mlb/hr 82.22 Total Bypass Flow (6): 10. 6 (of total core flow)

Total Water Rod Flow (6): 3.8 (of total core flow)

Source Convergence 0. 00038 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.579 27 25 14 1.701 0.864 27 47 26 8.78 0.814 24.4 27 35 14 15 7.36 0.823 56.3 23 47 32 13 1.579 27 47 26 1.702 0.864 27 25 48 8.76 0.813 24.4 27 47 26 15 7.36 0.823 56.2 23 31 48 13 1.567 28 25 12 1.709 0.860 28 49 26 8.66 0.809 25.2 27 35 16 15 7.31 0.811 55.5 23 31 16 14 1.567 28 49 36 1.710 0.860 28 25 50 8.65 0.809 25.3 27 45 26 15 7.31 0.811 55.5 23 47 34 14 1.563 26 33 12 1.719 0,855 28 49 34 8.69 0.807 24.5 26 33 16 15 7.31 0.810 55.4 23 33 46 14 1.563 26 49 34 1.720 0.855 26 33 50 8.68 0.807 24.6 26 45 28 15 7.28 0.808 55.6 23 15 32 14 1.552 27 35 16 1.72 9 0.850 27 25 16 8.74 0.802 23.2 28 35 12 15 7.09 0,799 56.9 23 47 24 14 1.552 27 45 26 1.733 0.848 27 15 26 8.79 0.802 22.4 26 33 12 15 7.10 0.798 56.8 23 23 48 14 1.547 26 49 32 1.737 0.846 26 33 16 8.72 0.801 23.3 28 49 36 15 7.07 0.794 56.8 23 23 16 14 1.547 26 31 12 1.742 0.844 26 15 34 8.56 0.801 25.2 26 33 18 15 7.05 0.792 56.6 23 15 24 14

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.45 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 15,250.0 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-49 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/MTTO 36106.4 Exposure: MWd/MTUJ (GWd) 15405.2 (1938.10)

Delta F: MWd/MTUJ, (GWd) 155.2 ( 19.53) lAxial Profile Edit Radial Power Power: MWt 2957.0 (100.00 %) N(PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.226 6.147 19 0.284 0.514 55 40 Inlet Subcooling: Btu/lbm -24.21 23 0.410 13.932 20 0.228 0.238 57 42 Flow: Mlb/hr 98.00 (100.00 8) 22 0.847 27.750 21 0.336 0.670 53 42 21 1.010 33.297 22 0.615 0.781 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.126 36.649 23 1.253 1.316 33 48 59 59 19 1.207 38.579 24 1.217 1.284 35 44 55 55 18 1.268 39.315 25 1.020 1.285 51 32 51 51 17 1.347 39.770 26 1.470 1.549 33 12 47 47 16 1.393 40.248 27 1.477 1.564 35 14 43 43 15 1.405 40.969 28 1.319 1.553 25 12 39-------------- 39 14 1.385 41.469 35-------------- 35 13 1.412" 40.484 31-------------- 31 12 1.384 40.916 27-------------- 27 11 1.346 41.693 23-------------- 23 10 1.297 42.357 19 19 9 1.235 42,709 15 15 8 1.153 43.420 1I ii 7 1.028 44.123 7 7 6 0.893 44.683 3 3 5 0.766 45.014" 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.659 43.630 3 0.584 40.002 Control Rod Density: % 0.00 2 0.476 31.137 Bottom 1 0.146 9.309 k-effective: 0.99807 Void Fraction: 0.312 8 AXIAL TILT 8.623 -8.600 Core Delta-P: psia 21. 927 AVG HOT eft/12ft 1.0349 1.0936 Core Plate Delta-P: psia 17.507 Coolant Temp: Deg-F 542.0 In Channel Flow: Mlb/hr 87.66 Active Channel Flow: Mlb/hr 83.96 Total Bypass Flow (8): 10.5 (of total core flow)

Total Water Rod Flow (8): 3.8 (of total core flow)

Source Convergence 0.00035 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LMGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.564 27 35 14 1.732 0.849 27 47 26 8.71 0.811 24.7 27 35 14 15 7.29 0.818 56.6 23 47 32 13 1.563 27 47 26 1.732 0.849 27 25 48 8.70 0.810 24.8 27 47 26 15 7.30 0.818 56.5 23 31 48 13 1.553 28 25 12 1.738 0,846 28 49 26 8.60 0.807 25.6 27 35 16 15 7.26 0.807 55.8 23 47 34 14 1.553 28 49 36 1.739 0.845 28 25 50 8.59 0.806 25.6 27 45 26 15 7.26 0.807 55.7 23 33 48 14 1.549 26 33 12 1.748 0.841 26 49 34 8.64 0.805 24.9 26 33 16 15 7.25 0.807 55.8 23 31 16 14 1.549 26 49 34 1,749 0.841 26 33 50 8.63 0.804 24.9 26 45 28 15 7.22 0.804 55.9 23 15 32 14 1.537 27 35 16 1.761 0.835 27 25 16 8.53 0.800 25.6 26 33 18 15 7.04 0.795 57.2 23 47 24 14 1.537 27 45 26 1.765 0,833 27 15 26 8.52 0.800 25.6 26 43 34 15 7.04 0.795 57.1 23 23 48 14 1.533 26 31 12 1.768 0.831 26 33 16 8.69 0.800 23.5 28 35 12 15 7.01 0.790 56.9 23 23 16 14 1.533 26 49 32 1.773 0.829 26 15 34 8.74 0.800 22.8 26 33 12 15 6.99 0.788 56.9 23 15 24 14 LHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.46 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 15,405.2 MWdIMTU ARE'VA Inc.

Controlled Document ANP-3293NP Revision 1 Page A-50 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Cycle: 24 Core Average Exposure: MWd/b4TU 36186.7 Exposure: MWd/MTU (G~d) 15484.6 (1948.10)

Delta E: MWd/MTtI, (GWd( 79.6 ( 10.01 Axial Profile Edit Radial Power Power: M~t 2957.0 (100.00 8) N(PRA) Power Exposure Zone Avg. Max. 1R JR Core Pressure: psia 1015.0 Top 24 0.229 6.163 19 0.284 0.514 55 40 Inlet Subocooling: Btu/lbm -23.70 23 0.414 13.967 20 0.228 0.238 57 42 Flow: Mlb/hr 99.96 (102.00 8) 22 0.857 27.824 21 0.336 0.670 53 42 21 1.021 33.385 22 0.616 0.781 13 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.138 36.747 23 1.252 1.316 33 48 59 59 19 1.218 38.685 24 1.215 1.283 35 44 55 55 18 1.277 39.426 25 1.021 1.287 29 10 51 51 17 1.353 39.883 26 1.469 1.552 33 12 47 47 16 1.397 40.363 27 1.478 1.565 35 14 43 43 15 1.408 41.085 28 1.322 1.556 25 12 39-------------- 39 14 1.387 41.582 35-------------- 35 13 1.413* 40.594 31-------------- 31 12 1.385 41.024 27-------------- 27 11 1.345 41.798 23-------------- 23 10 1.295 42.458 19 19 9 1.231 42.804 15 15 8 1.146 43.508 ii 11 7 1.019 44.200 7 7 6 0.882 44.750 3 3 5 0.754 45.072*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.648 43.679 3 0.573 40.046 Control Rod Density: % 0.00 2 0.467 31.173 Bottom 1 0.143 9.321 k-effective: 0.99794 Void Fraction: 0.308 8 AXIAL TILT 9.264 -8.552 Core Delta-F: psia 22.574 AVG SOT Sft/l2ft 1.0308 1.0934 Core Plate Delta-P: psia 18.153 Coolant Temp: Deg-F 542.1 In Channel Flow: Mlb/hr 89.45 Active Channel Flow: Mlb/hr 85.69 Total Bypass Flow (8): 10.5 (of total core flow)

Total Water Rod Flow (8): 3.8 (of total core flow)

Source Convergence 0.00044 Top Ten Thermal Limits SUimeary - Sorted by Margin Power MCPR APLHGR tHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.565 27 35 14 1.741 0.844 27 47 26 8.74 0.814 24.9 27 35 14 15 7.30 0.820 56.7 23 47 32 13 1.564 27 47 26 1.741 0.844 27 25 48 8.72 0.813 24.9 27 47 26 15 7.30 0.820 56.7 23 31 48 13 1.556 28 25 12 1.746 0.842 28 49 26 8.62 0.809 25.7 27 35 16 15 7.28 0.811 56.0 23 47 34 14 1.556 28 49 36 1.747 0.842 28 25 50 8.61 0.809 25.8 27 45 26 15 7.28 0.811 55.9 23 33 48 14 1.552 26 33 12 1.756 0.837 26 49 34 8.65 0.808 25.0 26 33 16 15 7.26 0.809 55.9 23 31 16 14 1.552 26 49 34 1.756 0.837 26 33 50 8.64 0.807 25.1 26 45 28 15 7.22 0.805 56.0 23 15 32 14 1.537 27 35 16 1.771 0.830 27 25 16 8.78 0.804 23.0 26 33 12 15 7.05 0.798 57.3 23 47 24 14 1.537 27 45 26 1.776 0.828 27 15 26 8.72 0.804 23.7 28 35 12 15 7.05 0.797 57.3 23 23 48 14 1.536 26 31 12 1.780 0.826 26 33 16 8.76 0.803 23.0 26 49 34 15 7.02 0.792 57.1 23 23 16 14 1.536 26 49 32 1.782 0.825 26 49 32 8.70 0.803 23.8 28 49 36 15 7.00 0.790 57.1 23 15 24 14 tHGR calculated CPR calculated with with pin-power pin-power reconstruction reconstruction & CPR limit type 3 Figure A.47 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 15,484.8 MWd/MTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-51 Cycle: 24 Core Average Exposure: M~d/MTU 36664.4 Exposure: MWd/MTU (G~d) 15962.5 (2008.20)

Delta E: M~d/MTU, (GWd) 477.7 ( 60.10) Axial Profile Edit Radial Power Power: M~t 2735.9 ( 92.52 8) M (PRA) Power Exposure Zone Avg. Max. TR JR Core Pressure: psia 1015.0 Top 24 0.242 6.262 19 0.285 0.517 55 40 Inlet Subcoocling: Btu/lbm -22.15 23 0.442 14.187 20 0.228 0.238 57 42 Flow: Mlb/hr 99.96 (102.00 6) 22 0.916 28.284 21 0.337 0.674 53 42 21 1.089 33.934 22 0.619 0.782 47 48 2 6 10 14 16 22 26 30 34 39 42 46 50 54 58 20 1.205 37.359 23 1.247 1.320 33 48 59 59 19 1.275 "39.335 24 1.199 1.283 43 44 55 55 18 1.321 40.105 25 1.029 1.305 31 10 51 51 17 1.386 40.573 26 1.460 1.570 33 12 47 47 16 1.419 41.055 27 1.483 1.572 35 14 43 43 15 1.420* 41.760 28 1.340 1.573 25 12

'9--------------------------- 39 14 1.391 42.265 5

35--------------------------- 35 13 1.415 41.256 5

1--------------------------- 31 12 1.381 41.671 27--------------------------- 27 11 1.336 42.426 23--------------------------- 23 10 1.277 43.060

.9 19 8 1.203 43.368

.5 15 8 1.108 44.021

.1 11 7 0.970 44.653 7 7 6 0.828 45.139 3 3 5 0.688 45.402*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.594 43.962 3 0.524 40.296 0.00 2 0.428 31.376 Control Rod Density:8 Bottom 1 0.132 9.384 k-effective: 0. 99731 Void Fraction: 0.289 % AXIAL TILT 12.666 -8.243 Core Delta-P: psia 22.189 AVG BOT 8ft/l2ft 1.0078 1.0921 Core Plate Delta-P: psia 17.775 Coolant Temp: Deg-F 542.2 In Channel Flow: Mlb/hr 99.70 Active Channel Flow: Mlb/hr 96.04 Total Bypass Flow (6): 10.3 (of total core flow)

Total Water Rod Flow (9): 3.7 (of total core flow)

Source Convergence 0. 00039 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLHGR LBGR Value FT IR JR Value Margin FT TB JR Value Margin Exp. FT TB JR K Value Margin Exp. FT TR JR K 1.573 28 25 12 1.862 0.789 28 49 26 8.19 0.771 26.0 27 35 14 15 6.76 0.768 57.7 23 31 48 13 1.573 28 49 26 1.862 0.789 28 25 50 8.17 0.770 26.0 27 47 26 15 6.89 0.769 56.0 23 33 48 15 1.572 27 35 14 1.864 0.789 27 25 48 8.29 0.766 24.1 26 33 12 15 6.88 0.768 56.0 23 47 34 15 1.571 27 47 26 1.864 0.789 27 47 26 8.22 0.766 24.8 28 35 12 15 6.81 0.768 56.9 23 47 32 14 1.570 26 33 12 1.968 0.787 26 33 50 8.26 0.765 24.1 26 49 34 15 6.64 0.757 58.1 23 31 16 14 1.569 26 49 34 1.869 0.787 26 49 34 8.20 0.764 24.8 28 49 26 15 6.60 0.754 58.1 23 15 32 14 1.552 26 31 12 1.898 0.775 26 31 50 8.03 0.762 26.8 27 35 16 15 6.55 0.750 58.3 23 47 24 14 1.551 26 49 32 1.898 0.774 26 49 32 8.02 0.761 26.8 27 45 26 15 6.56 0.749 58.2 23 23 48 14 1.536 27 35 16 1.899 0.774 27 25 16 8.24 0.761 23.8 26 31 12 15 6.51 0.742 58.0 23 23 16 14 1.535 27 45 26 1.903 0.772 27 15 26 8.06 0.759 26.1 26 33 16 15 6.66 0.741 55.9 24 25 18 15

LI4GR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction 6 CPR limit type 3 Figure A.48 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 15,962.5 MWdIMTU AREVA Inc.

Controlle.d Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page A-52 Cycle: 24 Core Average Exposure: MO~d/MTUY 37064.4 Exposure: M~d/MTU (GDM) 16362.5 (2058.50)

Delta E: MWd/MTU, (GWd) 400.0 C 50.32 Axial Profile Edit Radial Power Power: M~t 2513.4 ( 85.00 8) M)PRA) Power Exposure Zone Avg. Max. IR JR Core Pressure: psia 1015.0 Top 24 0.253 6.350 19 0.284 0.517 55 40 Inlet Subcooling: Btu/lbm -20.61 23 0.466 14.383 20 0.227 0.237 57 42 Flow: Mlb/hr 99.96 (102.00 8) 22 0.969 28.695 21 0.336 0.678 55 34 21 1,149 34.422 22 0,621 0.781 47 48 2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 20 1.263 37.898 23 1.243 1.324 33 14 59 59 19 1,323 39.904 24 1.185 1.285 43 18 55 55 18 1.358 40.692 25 1.036 1.322 31 10 51 51 17 1.414 41.164 26 1.454 1.587 33 12 47 47 16 1.437k 41.643 27 1.489 1.580 35 14 43 43 15 1.429 42.367 28 1.356 1.590 35 12 39--------------------------- 39 14 1.395 42.839 35--------------------------- 35 13 1.417 41.811 31-------------- 31 12 1.380 42.213 27-------------- 27 11 1.329 42.948 23-------------- 23 10 1.262 43.558 19 19 9 1.179 43.830 15 15 8 1.073 44.436 11 1i 7 0.927 45.015 7 7 8 0.780 45,445 3 3 5 0.650 45,659*

2 6 10 14 18 22 26 30 34 38 42 46 50 54 58 4 0.548 44.180 3 0.483 40.488 Control Rod Density: % 0.00 2 0.394 31.533 Bottom 1 0.122 9.432 k-effective: 0. 99733 Void Fraction: 0.270 8 AXIAL TILT 15. 614 -7.957 Core Delta-P: psia 21.825 AVG BOT 8ft/12ft 0.! 9877 1.0908 Core Plate Delta-?: psia 17.418 Coolant Temp: Deg-F 542.3 In Channel Flow: Nib/hr 89.93 Active Channel Flow: Nih/hr 86.39 Total Bypass Flow (%): 10.0 (of total core flow)

Total Water Rod Flow (8): 3.6 (of total core flow)

Source Convergence 0.00049 Top Ten Thermal Limits Summary - Sorted by Margin Power MCPR APLEOR LHGR Value FT IR JR Value Margin FT IR JR Value Margin Exp. FT IR JR K Value Margin Exp. FT IR JR K 1.590 28 35 12 1.996 0.737 27 47 26 7.61 0.723 26.9 27 35 14 15 6.41 0.721 56.8 23 33 48 15 1.589 28 49 26 1.996 0.736 28 49 26 7.74 0.722 25.0 26 33 12 15 6.41 0.721 56.9 23 47 34 15 1.587 26 33 12 1.997 0.736 27 25 48 7.68 0.722 25.7 28 35 12 15 6.36 0.716 56.8 23 31 48 14 1,585 26 49 34 1.998 0.736 28 25 50 7.60 0.721 26.9 27 47 26 15 6.36 0.716 56.9 23 47 32 14 1.580 27 35 14 2.007 0.732 26 33 50 7.72 0.720 25.1 26 49 34 15 6.11 0.703 58.8 23 31 16 14 1.579 27 47 26 2.008 0.732 26 49 34 7.66 0.720 25.7 28 49 26 15 6.08 0.700 58.9 23 15 32 14 1.568 26 31 12 2.039 0.721 27 25 16 7.70 0.717 24.8 26 31 12 15 6.05 0.698 59.1 23 47 24 14 1.566 26 49 32 2.040 0.720 26 31 50 7. 67 0.715 24.8 26 49 32 15 6.06 0.698 59.0 23 23 48 14 1.548 27 23 12 2.042 0.720 26 49 32 7.44 0.711 27.7 27 35 16 15 3.21 0.697 71.9 22 33 6 11 1.548 27 49 24 2.045 0.718 27 15 26 7.42 0.710 27.7 27 45 26 15 6.12 0.691 57.3 23 39 18 17

LHGR calculated with pin-power reconstruction

CPR calculated with pin-power reconstruction & CPR limit type 3 Figure A.49 Quad Cities Unit 2 Representative Cycle 24 Control Rod Pattern and Axial Distributions at 16,362.5 MWdIMTU AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page B-I Appendix B Elevation Views of the Quad Cities Unit 2 Representative Cycle 24 Fresh Reload Batch Fuel Assemblies ARE-VA Inc.

C;ontroIled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page B-2

]

Figure B.1 Elevation View for the Quad Cities Unit 2 Representative Cycle 24 Fresh Fuel ATRIUM I0XM [ ] Fuel Assembly Design AREVA Inc.

Controlled Docu ment ANP-3293NP Revision 1 Page B-3 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design

]

Figure B.2 Elevation View for the Quad Cities Unit 2 Representative Cycle 24 Fresh Fuel ATRIUM IOXM [ ] Fuel Assembly Design AREVA Inc.

Controfled Document ANP-3293NP Revision I Page B-4 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design

[

I Figure B.3 Elevation View for the Quad Cities Unit 2 Representative Cycle 24 Fresh Fuel ATRIUM I0XM [ ] Fuel Assembly Design AREVA Inc.

Controlled Document ANP-3293NP Revision I Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page C-I Appendix C Quad Cities Unit 2 Representative Cycle 24 Fresh Fuel Locations AREVA Inc.

Controlled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page C-2 Table C.1 Quad Cities Unit 2 Representative Cycle 24 Reload Fuel Identification and Locations (Core Coordinates)

Assembly Type: ATRIUM 10XM QCI2-24 Bundle

Description:

[

Number Loaded: 96 ]

Fuel Core Fuel Core Fuel Core Fuel Core ID Coord. ID Coord. ID Coord. ID Coord.

XRA0 01 27-32 XRA025 19-32 XRA049 15-34 XRA073 11-32 XRA0 02 29-34 XRA0 26 2 9-42 XRA0 50 27-46 XRA074 29-50 XRA0 03 31-34 XRA027 31-42 XRA0 51 33-46 XRA0 75 31-50 XRA004 33-32 XRA028 41-32 XRA052 45-34 XEA0 76 49-32 XRA0 05 33-30 XRAO29 41-30 XRA053 45-28 XRA0 77 49-30 31-28 XRA030 31-20 XRA054 33-16 XRA0 78 3 1-12 XRA007 29-28 XRA031 29-20 XRA055 27-16 XRA079 29-12 XRA&008 27-30 XRA032 19-30 XRA0 56 15-28 XRA080 11-30 XRA0 09 25-34 XRA033 19-36 XRA0 57 19-40 XRA0 81 11-34 XRA0 10 27-36 XRA034 2 5-42 XRA0 58 2 1-42 XRA0 82 27-50 XPA0 11 33-36 XRA035 3 5-42 XRA059 39-42 XRA083 33 -50 XRA0 12 35-34 XRA0 36 41-36 XRA0 60 41-40 XRA0 84 49-34 XRA013 35-28 XRAO37 41-26 XRA061 4 1-22 XRA085 49-28 XRA0l4 33-26 XRAO38 35-20 XRA062 39-20 XRA0 86 3 3-12 XRA0 15 27-26 XRA03 9 25-20 XRA063 21-20 XRA087 27-12 XRA0 16 25-28 XRA04O0 19-26 XRAO64 19-22 XRA0 88 11-28 XRAO017 21-34 XRA04 1 17-34 XRA0 65 17-38 XRA089 15-42 XRA0 18 27-40 XRA042 27-44 XRA0 66 23-44 XRA090 19-46 XRA0 19 33-40 XRA043 3 3-44 XRA0 67 37-44 XRA0 91 41-46 XRA02 0 39-34 XRA044 43-34 XRA068 43-38 XRA0 92 4 5-42 XFA021 39-28 XRA045 43-2 8 XRA069 43-24 XRA0 93 45-20 XRA022 33-22 XRA046 33-18 XRA0 70 37-18 XPA0 94 41-16 XPA023 27-22 XRA047 27-18 XRA0 71 23-18 XRA0 95 19-16 XRA024 21-28 XRA048 17-2 8 XRAO072 17-24 XRA0 96 15-20 AREVA Inc.

Contrcoied Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page 0-3 Table C.2 Quad Cities Unit 2 Representative Cycle 24 Reload Fuel Identification and Locations (Core Coordinates)

Assembly Type: ATRIUM I10XM QCI2-24 Bundle

Description:

[ ]

Number Loaded: 64 Fuel Core Fuel Core Fuel Core Fuel Core ID Coord. ID Coord. ID Coord. ID Coord.

XRA097 23-36 XRAIl3 13-36 XRA12 9 15-44 XRA145 11-40 XRA098 25-38 XRA114 25-48 XRA130 17-46 XRA146 21-50 XRA099 35-38 XRA115 35-48 XRAI131 43-46 XRA147 39-50 XRA1I00 37-36 XRAIl6 47-36 XRA132 4 5-44 XRA148 49-40 XRA1 01 37-26 XRA1I17 47-26 XRA133 45-18 XRAI149 49-22 XRA1 02 35-24 XRA1 18 35-14 XRAI134 43-16 XRA1 50 39-12 XRA1I03 25-24 XRA119 25-14 XRAI35 17-16 XRA151 2 1-12 XRA104 23-26 XRAI20 13-26 XRA136 15-18 XRA152 11-22 XRA105 15-36 XRA121 11-38 XRAI 37 13-42 XRA1 53 11-42 XRA1I06 25-46 XRA122 23-50 XRAI 38 19-48 XRA1 54 19-50 XRA1 07 3 5-46 XRA123 37-50 XRAI 39 41-48 XRAI 55 4 1-50 XRAI 08 45-36 XRAI24 49-38 XRA140 47-42 XRAI 56 49-42 XRA109 45-26 XRA125 49-24 XRAI141 47-2 0 XRAI157 49-20 XRAII0 35-16 XRA126 3 7-12 XRA142 41-14 XRA158 41-12 XRA1 11 25-16 XRAI27 2 3-12 XRA143 19-14 XRAI159 19-12 XRAII12 15-26 XRAI 28 11-24 XRA144 13-2 0 XRAI160 11-20 AREVA Inc.

Controfled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page C-4 Table C.3 Quad Cities Unit 2 Representative Cycle 24 Reload Fuel Identification and Locations (Core Coordinates)

Assembly Type: ATRIUM 10XM QCl2-24 Bundle

Description:

[

Number Loaded: 88

]

Fuel Core Fuel Core Fuel Core Fuel Core ID Coord. ID Coord. ID Coord. ID Coord.

XRA161 17-42 XRA1I83 27-10 XRA2 05 51-24 XRA227 45-4 8 XRAI62 19-44 XRAI84 9-28 XRA2 06 37-10 XRA228 47-4 6 XRAI63 41-44 XRAI85 7-32 XRA207 23-10 XRA229 47-16 XRAI 64 43-42 XRAI86 29-54 XRA2 08 9-24 XRA230 4 5-14 XRA165 43-20 XRA1I87 31-54 XRA2 09 7-36 XRA231 15-14 XRAI66 41-18 XR~AI88 53-32 XRA210 25-54 XRA232 13-16 XRAI67 19-18 XRA189 53-30 XRA2 11 35-5 4 XRA233 11-4 4 XRAI68 17-20 XRAI90 31- 8 XRA212 53-3 6 XRA2 34 17-50 XRAI69 11-36 XRA1 91 29- 8 XRA213 53-2 6 XRA235 43-50 XRAI70 25-50 XRA192 7-30 XRA214 35- 8 XRA236 4 9-44 XRAI171 35-50 XRA193 7-34 XRA215 25- 8 XRA237 4 9-18 XRA1I72 4 9-36 XRAI194 27-54 XRA2 16 7-26 XRA238 4 3-12 XRAI73 4 9-26 XRAI95 33-54 XRA217 7-38 XRA239 17-12 XRAI174 35-12 XRAI 96 53-34 XRA218 23-54 XRA240 11-18 XRAI75 25-12 XRAI97 53-2 8 XRA219 37-54 XRA241 9-42 XRAI7 6 11-2 6 XRA1I98 33- 8 XRA220 53-3 8 XRA242 19-52 XRAI 77 9-34 XRAl99 27- 8 XRA2 21 53-2 4 XRA243 41-52 XRA178 27-52 XRA2 00 7-28 XRA222 37- 8 XRA244 51-4 2 XRAI79 33-52 XRA2 01 9-38 XRA2 23 23- 8 XRA245 51-2 0 XRAI80 51-3 4 XRA202 23-52 XRA2 24 7-24 XRA246 4 1-10 XRAl81 51-2 8 XRA203 37-52 XRA2 25 13-4 6 XRA2 47 19-10 XRAI82 33-10 XRA204 51-38 XRA2 26 15-4 8 XRA2 48 9-20 AREVA Inc.

Controfled Document ANP-3293NP Revision 1 Quad Cities Unit 2 Cycle 24 Representative Fuel Cycle Design Page D-1 Appendix 0 Quad Cities Unit 2 Representative Cycle 24 Radial Exposure and Power Distributions AREVA Inc.

1 3 5 7 9 ii 13 15 17 19 21 23 25 27 29 60 44. 462 41. 789 43. 535 43.430 43. 693 58 41. 583 43.173 42. 753 42.791 41.728 43.825 56 44.934 44.200 44.099 42.128 41. 847 41. 770 40.811 40.673 40.099 54 44.579 43.418 42.578 19.457 39.207 18.618 0.000 0.000 0.000 0.000 52 44.586 43. 642 41.600 36. 066 19.469 0.000 20. 339 0.000 22.175 0.000 19.949 50 44.511 43.637 43. 066 36. 590 17.483 0.000 0.000 0.000 0.000 0.000 0.000 0.000 48 44.926 43.054 41.661 36. 513 35.708 0.000 20.006 0.000 22. 434 23.610 0.000 22.941 22.898 46 44.124 42.508 36. 175 17.506 0.000 20. 936 0.000 0.000 22. 975 23.238 0.000 0.000 22. 850 44 44.063 19. 476 19.466 0.000 20. 028 0.000 21.579 0.000 22. 573 0.000 21. 313 0.000 22.036 42 34.318 42.020 39. 125 0.000 0.000 0.000 0.000 0.000 21. 579 0.000 22.537 0.000 19. 976 0.000 40 44.396 43.066 41.846 18.602 20.333 0.000 22.4 63 23. 026 22.631 0.000 23.309 23.618 21. 942 0.000 22. 902 38 40. 606 42.671 41. 472 0.000 0.000 0.000 23. 615 23. 232 0.000 22.569 23.638 23. 353 0.000 20. 788 23.506 36 43. 724 42.718 39. 793 0.000 22.192 0.000 0.000 0.000 21. 339 0.000 21.954 0.000 20.980 0.000 22. 911 34 43. 347 42.763 40. 717 0.000 0..000 0.000 22.976 0.000 0.000 19. 982 0.000 20. 781 0.000 22.054 0.000 32 43. 679 43.815 40. 040 0.000 19.973 0.000 22.925 22.855 22. 047 0.000* 22.935 23. 506 22.954 0.000 22. 088 30 43. 672 43. 777 40.029 0.000 19. 955 0.000 22.897 22.867 22. 056 0.000 22.938 23. 486 22.942 0.000 22. 092 28 43. 325 42.749 40. 757 0.000 0.000 0.000 22.957 0.000 0.000 19.958 0.000 20. 759 0.000 22.045 0.000 26 43. 747 42.676 40.607 0.000 22.195 0.000 0.O000 0.000 21. 316 0.000 21.924 0.000 20. 989 0.000 22.922 24 41.654 42.695 41.490 0.000 0.000 0.000 23. 607 23.221 0.000 22.548 23. 626 23. 335 0.000 20.811 23.523 22 44.411 43.110 41.869 18.627 20. 317 0.000 22. 456 23.023 22. 615 0.000 23. 337 23. 635 21.971 0.000 22.928 20 34.411 42. 063 39.123 0.000 0,000 0.000 0.000 0.000 21. 606 0.000 22.563 0.000 19. 999 0.000 18 44 .062 19.458 19. 485 0.000 20.022 0.000 21. 548 0.000 22.591 0.000 21. 341 0.000 22.057 16 44.158 42.525 36. 134 17.494 0.000 20.923 0.000 0.000 23. 003 23. 246 0.000 0.000 22.869 14 44.916 43.042 41. 763 36. 524 35. 759 0.000 20. 031 0.000 22.457 23. 618 0.000 22.970 22.929 12 44.536 43.666 43. 048 36. 620 17.487 0.000 0.000 0.000 0.000 0.000 0.000 0.000 10 44.563 43.702 41. 723 36.108 19.447 0.000 20. 354 0.000 22.188 0.000 19. 973 8 44.567 43. 375 42.660 19.481 39.249 18.601 0.000 0.000 0.000 0.000 6 44.928 44.150 44.079 42.129 41.964 41. 598 39. 819 40. 823 40. 158 4 41.523 43.148 42.799 42.778 41. 726 43. 795 2 44.462 40.704 43.493 43. 433 43. 707 Figure D.1 Quad Cities Unit 2 Representative Cycle 24 BOC Exposure Distribution (0.0 GWdlMTU) z

,u (a o &.*

m C 0o CD-C N.

0 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 60 43.698 43.295 43. 502 41.791 44.453 58 43.746 41.757 42.775 42.769 43.124 41.550 56 40.158 40.689 40. 832 41. 616 41.941 42.159 44.039 44. 124 44. 886 54 0.000 0.000 0.000 0.000 18.597 39.244 19.,463 42.691 43. 375 CD 44.588 52 19.955 0.000 22.164 0.000 20.333 0.000 19. 443 36. 114 41. 720 43.715 44.434 50 0.000 0.000 0.000 0.000 0.000 0.000 0.000 17. 470 36. 637 43. 011 43.679 44.553 48 22.904 22.944 0.000 23.591 22.436 0. 000 20.009 0.000 35.748 36. 547 41. 500 43. 004 44. 893 46 22.812 0.000 0.000 23. 228 22.970 0. 000 0. 000 20.913 0.000 17.485 36. 146 42.561 44.133

0. 000 21. 546 0.000 0.000 19.468 19.457 44.027 CD 44 22.003 0.000 21. 320 0.000 22.556 20.015 42 0.000 19.980 0.000 22.541 0.000 21.585 0. 000 0.000 0.000 0.000 0.000 39. 165 42. 085 34.432 40 22.885 0.000 21. 947 23.598 23. 308 0.000 22.594 22.999 22.449 0.000 20.308 18.608 41.864 43.119 44.414 38 23.503 20.789 0.000 23. 319 23. 593 22.544 0.000 23.208 23.580 0.000 0.000 0.000 39. 837 42.706 41.669 c-I (C

36 22.883 0.000 20. 968 0.000 21. 921 0.000 21. 313 0. 000 0.000 0.000 22.162 0.000 40. 765 42. 682 43.725 CD 34 0.000 22.034 0.000 20.754 0. 000 19.854 0.000 0.000 22.948 0.000 0.000 0.000 40. 617 42.739 43.329 32 22.075 0.000 22.911 23.470 22.903 0.000 22.002 22.811 22.890 0.000 19.954 0.000 40.052 43. 742 43.668 22.830 22.927 0.000 19.969 0.000 40.056 43. 786 43.670 0I 30 22.102 0.000 22.936 23.508 22.914 0.000 22.016 28 0.000 22.070 0.000 20.800 0. 000 19. 992 0.000 0.000 22. 968 0.000 0.000 0.000 40.729 42. 795 43.348 26 22.925 0.000 20.995 0.000 21.965 0.000 21.332 0.000 0.000 0.000 22.167 0.000 40.627 42.727 43. 762 24 23.526 20. 811 0.000 23.338 23.624 22.557 0.000 23.241 23.609 0.000 0.000 0.000 41. 635 42.601 41.677 22 22.914 0.000 21.967 23.625 23.338 0.000 22.612 23. 003 22.455 0.000 20.352 18. 620 41.872 43.116 44.426 20 0.000 19.997 0.000 22.555 0.000 21.604 0.000 0.000 0.000 0. 000 0.000 39. 170 42.039 34.355 18 22.027 0.000 21.329 0.000 22.602 0. 000 21.593 0.000 20. 022 0.000 19.486 19.479 44.056 16 22.835 0.000 0.000 23.,253 23.002 0.000 0.000 20.958 0.000 17.529 36. 167 42.545 44.142 14 22.926 22.967 0.000 23. 615 22.455 0.000 20. 030 0.000 35.751 36.548 41. 510 43.029 44.914 12 0.000 0.000 0.000 0.,000 0.000 0.000 0.000 17.494 36. 647 43. 060 43. 639 44.561 10 19.971 0.000 22. 178 0.000 20.356 0. 000 19.482 36. 104 41.780 43. 735 44.590 8 0.000 0. 000 0.000 0.000 18.622 39.263 19.474 42.686 43.386 44. 632 6 40.169 40. 844 39. 817 41.720 41. 963 42.156 44.072 44.192 44.945

0" 4 43.801 41.761 42,769 42.800 43. 188 41. 582 2 43.706 43.443 43.486 40.719 44.505 oCD Figure D.1 Quad Cities Unit 2 Representative Cycle 24 BOC Exposure Distribution (0.0 GWd/MTU) (Continued)

n p0 3 9 11 13 15 17 19 21 23 25 27 29 60 47.093 44. 895 46. 845 46.860 47.133 58 45.,855 48. 386 48.703 49.165 48.370 50. 371 56 47.846 48,466 50.009 49.884 51. 058 51.805 51.349 51.398 50, 951 54 48.711 50.301 31.816 51. 042 34.515 17.028 17.553 17.758 17.852

47. 874 52 49. 062 49.882 47.599 35,884 18.647 39. 482 20. 634 41. 847 21.133 40,2 64 48.037 50 47.,814 49.060 50. 914 47.989 34,374 19.774 20. 907 21. 577 22,058 22.592 22.184 21.839 48 47.841 48.315 49,943 47,939 49,734 19,562 40.957 22.351 42.485 43. 716 23. 112 44.336 42, 323 46 48.411 50. 253 47.715 34.419 19.586 41. 266 23.016 23.004 43. 451 43. 737 23.469 23. 011 42,525 44 50.025 31.874 35. 915 19.803 41. 000 23.034 43.896 23. 973 44. 562 23. 302 43. 695 23.466 43. 858 42 38.984 49.866 51. 019 18. 697 20,945 22,380 23,028 23,989 43.948 23. 172 44.361 23.502 42,468 23.082 40 47.100 48.385 51.126 34.564 39.528 21.621 42.543 43.518 44.627 23. 179 42,987 43.289 43.,791 23.119 42.727 38 43. 777 48.701 51. 607 17.113 20,702 22.108 43. 756 43. 757 23.314 44.393 43.303 43.033 23. 309 42.793 43.207 36 47.070 49.173 50. 548 17,676 41. 932 22.646 23.,149 23. 493 43.730 23.505 43.803 23.313 43. 249 23.322 44.526 34 46.,814 49.400 51. 612 17.870 21.211 22.237 44.399 23.037 23.481 42. 483 23.127 42.789 23. 318 44.029 22.878 32 47.,157 50.429 50. 975 17,.942 40.343 21.885 42.379 42,555 43. 881 23.092 42.765 43.214 44.550 22.856 41.561 30 47.142 50.376 50. 943 17.920 40.317 21.878 42.352 42.566 43.886 23.092 42.767 43.192 44.539 22.855 41. 567 28 46. 771 49.340 51.585 17.801 21.173 22.216 44.372 23. 031 23.478 42.460 23.126 42.768 23.312 44. 020 22.876 26 47,057 49,076 51.117 17.585 41,889 22.620 23.136 23.488 43.706 23. 504 43.777 23. 313 43.250 23. 319 44.535 24 44.784 48. 673 51.561 17. 041 20.657 22.084 43,737 43.741 23.314 44.375 43. 292 43. 012 23.306 42,810 43. 228 22 47,094 48,391 51.108 34.547 39.487 21. 601 42.526 43,509 44.608 23. 175 43.008 43.293 43. 805 23.115 42.753 20 39. 051 49. 881 50.995 18.673 20.928 22.368 23.020 23,982 43. 963 23. 164 44.373 23.487 42.477 23.075 18 50.014 31.846 35.917 19.790 40. 986 23.027 43.862 23. 966 44,573 23.295 43. 706 23,454 43. 863 16 48,434 50,260 47,672 34.399 19.578 41,248 23.012 23. 000 43. 472 43.742 23.464 23.003 42.529 14 47.828 48.299 50.032 47.944 49.778 19,557 40.978 22.350 42,506 43.727 23. 115 44.358 42.337 12 47. 831 49. 084 50.903 48. 025 34,379 19.775 20.911 21.584 22.070 22.607 22.197 21.850 10 48. 017 49.125 50. 012 47.649 35. 871 18,655 39.507 20.658 41,887 21. 170 40.314 8 47. 867 48. 676 50.388 31.846 51.090 34,512 17.062 17.628 17.829 17.911 6 47.,842 48.419 49. 991 49.886 51.170 51. 672 50.535 51.673 51. 053 4 45.804 48,372 48. 780 49.213 48.429 50.384 2 47.103 43.843 46.840 46.894 47.171 Figure D.2 Quad Cities Unit 2 Representative Cycle 24 EQC Exposure Distribution (16.4 GWdIMTU) z

-v 03 Co CD Co

-0 Z C

p 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 60 47.139 46. 730 46. 811 44.893 47.079 58 50.297 48.403 49. 145 48.713 48.327 45.822 56 51. 005 51. 409 51. 365 51.641 51. 123 49. 905 49. 947 48. 390 47.799 54 17. 851 17.756 17. 544 17.012 34.482 51. 071 31.819 50. 410 48.675 47. 891 52 40. 269 21. 130 41. 835 20.629 39.474 18.647 35.864 47.653 50. 012 49.143 47.899 50 21.839 22.181 22.590 22.056 21. 577 20. 909 19.777 34.369 48.050 50.876 49. 110 48 42.325 44.334 23. 106 43.700 42.486 22.352 40. 965 19.567 49.776 47. 983 34.412

49. 817 47.700 47.858

48. 279 50.310 47.815 48.422 C) 0 46 42.493 23.006 23. 460 43.723 43.445 23. 004 23.018 41.251 19.595 44 43. 829 23.460 43.691 23. 292 44.543 23. 969 43. 868 23.040 40.999 19. 815 35. 926 31. 864 49.995 42 23. 082 42.463 23. 486 44.350 23. 158 43. 944 23. 988 23. 036 22.392 20.958 18.708 51. 066 49.936 39.098

43. 245 42. 966 44.596 43. 504 42.541 21. 636 39.521 34.593 51. 176 48.451 40 38

42. 713

43. 203

23. 114 42.790 43.780 23.294 42.978 43.245 23.171 44.366 23. 317 43.740 43. 735 22.117 20.708 17.131 50.115 48.749 47.120 44.825 0

36 44.501 23. 317 43.228 23. 299 43. 766 23.501 43. 706 23. 495 23. 151 22.646 41. 898 17.640 51. 388 49.119 47.055 34 22.879 44.008 23.308 42.759 23.122 42.454 23. 481 23. 036 44.372 22. 229 21. 190 17.828 51. 405 49.347 46. 782 32 30

41. 549 41.571 22.854 22.850 44.508 44.527

43. 166

43. 194 42.727 42.731

23. 092

23. 087 43.843

43. 852 42.520

42. 531 42.348

42. 376 21.880

21. 872

40. 313 40.318 17.909 17.901

50. 961

50. 954 50.341 50.378 47.135 47.132 0D 28 26

22. 875 44.535 44.036

23. 317

23. 302

43. 245 42.787

23. 290 23.111 43.794 42.480 23.494

23. 472 43.715

23. 025

23. 480 44.376

23. 129 22.208 22.610

21. 161

41. 856

17. 786 17.568

51. 544

51. 121 49.373

49. 114

46. 786 47.067 03 24 43. 232 42. 804 23. 289 42.997 43.276 44.369 23.304 43.752 43.733 22.073 20. 642 17.023 51. 677 48.661 44.802 o 22 42.740 23. 110 43.789 43.270 42. 994 23. 158 44.597 43.487 42.520 21. 589 39.501 34.524 51. 102 48.390 47.105 20 23.074 42. 474 23. 480 44.355 23.148 43. 951 23.972 23.011 22.359 20. 916 18.657 51.025 49. 852 38.995 B 18 43. 839 23. 454 43. 698 23.291 44.578 23. 960 43.893 23. 014 40.974 19. 779 35. 907 31.852 50. 004 16 42.498 23. 002 23. 466 43. 759 43.479 22. 998 23. 000 41. 268 19. 567 34.425 47.695 50. 274 48.419 14 42.335 44.357 23. 120 43.735 42.515 22. 348 40. 967 19.540 49. 756 47. 959 49.806 48.289 47.826 12 21. 851 22.201 22.612 22.076 21.597 20.906 19. 761 34.359 48.020 50.898 49. 056 47.856 10 40. 311 21. 175 41.886 20. 664 39.509 18.651 35.888 47.616 50. 022 49.135 48. 034 8 17.912 17.833 17.637 17.078 34.539 51.098 31. 824 50. 391 48. 661 47.921 6 51. 063 51. 691 50.538 51.802 51.185 49.913 49.980 48.450 47.847 4 50. 394 48.459 49.207 48.787 48.419 45. 858 2 47.169 46. 901 46. 833 43.860 47. 146 Figure D.2 Quad Cities Unit 2 Representative Cycle 24 EOC Exposure Distribution (16.4 GWdlMTU) (Continued) z o C,

> c£)

Q.

_ 0 C

1 3 5 7 9 ii 13 15 17 19 21 23 25 27 29 60 o,197 0.224 0.235 0.240 0.239 58 o.319 0,379 0.420 0.436 0.448 0.437 56 0.230 0.323 0.435 0.557 0,636 0.665 0.673 0.667 0.676 54 0.262 0.409 0.565 0.866 0.797 1,o45 1.o12 1.oo4 0.997 1.oo2 52 0.275 0.419 0.610 0.805 1.091 1.131 1,209 1.185 1.162 1.152 1.190 *2 50 0.262 0.419 0.575 0.789 1.113 1.183 1.201 1,242 1.247 1.247 1.151 1.123 48 0.230 0.406 0.608 0.790 0.864 1.095 1.304 1.285 1,342 1.335 1.281 1.247 1.045 46 0.324 0.566 0.805 1.115 1.096 1.175 1.294 1.300 1,392 1.380 1.322 1.236 1.101 44 0.439 0.869 1.094 1.184 1.305 1,295 1.364 1.393 1,395 1.335 1,384 1.307 1.371 42 0.348 0.564 0.801 1,134 1.203 1.286 1.301 1.394 1.373 1,280 1.346 1.334 1.439 1.378 40 0.203 0.387 0.641 1.050 1.212 1,244 1.343 1.392 1.396 1.280 1,014 1.036 1.383 1.406 1.501 38 8.229 0.427 0.667 1.017 1.189 1.249 1.337 1.381 1.335 1.345 1,036 1.045 1.378 1.504 1.548 36 0.238 0.443 0.685 1.011 1.167 1.250 1.282 1.323 1.384 1.334 1,383 1.378 1.458 1.428 1.516 34 0.243 0.450 0.686 1.004 1.157 1.153 1.248 1.237 1.307 1.439 1,406 1.504 1.427 1.449 1.347 32 0.242 0.442 0.683 1.008 1.194 1.125 1.046 1.102 1.371 1.378 1,500 1.548 1.514 1.346 1.099 30 0.241 0.441 0.681 1.006 1.193 1.124 1.046 1.102 1.371 1.378 1,500 1.547 1,514 1.346 1.099 (")

28 0.241 0.445 0.680 0.999 1.154 1.152 1.247 1.237 1.307 1.439 1,406 1.504 1.427 1.448 1.347 l.*

26 0.235 0.438 0.665 1.005 1.163 1.248 1.281 1.322 1.384 1.334 1,382 1.377 1.457 1.427 1.515 *"

24 0.227 0.422 0.662 1.012 1.186 1.247 1.335 1.380 1.334 1.345 1,035 1.044 1.377 1.503 1.546 22 0.201 0.384 0.638 1.047 1.210 1.242 1.342 1.392 1.395 1.279 1,013 1.035 1.381 1.405 1.499 20 0.346 0.561 0.800 1.132 1.201 1.285 1.300 1.393 1.372 1.279 1.344 1.333 1.438 1.376 *.

18 0.438 0.868 1.092 1.183 1.304 1.295 1.363 1.393 1,394 1.334 1.383 1.306 1.369 (*

16 0.323 0.565 0.805 1.114 1.095 1.174 1.294 1.300 1,391 1.379 1.322 1.236 1.100 14 0.230 0.405 0.608 0.790 0.862 1.094 1.304 1.285 1,342 1.335 1.281 1.246 1.044 12 0.262 0,419 0.576 0.790 1.114 1.183 1.201 1.242 1.247 1.248 1.152 1.124 10 0.276 0.419 0.616 0.806 1.092 1.132 1.209 1.187 1.165 1.155 1.193 8 0.262 0.410 0.565 0.867 0.797 1.046 1.014 1.009 1.002 1.007 6 0.230 0.323 0.435 0.557 0.635 0.663 0.684 0.682 0.681 4 0.319 0.379 0.422 0.441 0.453 0.441 2 0.198 0.227 0.238 0.242 0.241 Figure D.3 Quad Cities Unit 2 Representative Cycle 24 Radial Power Distribution at 0.0 MWdlMTU Z

m C C

w po a-0 CD en C

31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 C)

C) 60 0.239 0.240 0.235 0.224 0.196 CD 58 0.437 0.448 0.436 0.419 0.377 0.318 56 0.676 0.666 0.672 0.659 0.633 0.556 0.434 0.323 0.230 .r~.

54 1.002 0.996 1.003 1.010 1.043 0.796 0.866 0.564 0.410 0.262 52 1.190 1.152 1.162 1.184 1.208 1.130 1.091 0.805 0.615 0.419 0.276 CD

~0 50 1.122 1.150 1.246 1.246 1.241 1.200 1.182 1.114 0.790 0.576 0.420 0.262 48 0.407 0.230 CD 1.044 1.246 1.280 1.334 1.341 1.284 1.304 1.095 0.863 0.791 0.612 en 46 1.101 1.235 1.321 1.378 1.391 1.299 1.294 1.175 1.096 1.115 0.806 0.566 0.324 CD 44 1.371 1.306 1.382 1.333 1.393 1.392 1.363 1.295 1.305 1.184 1.094 0.870 0.439 42 1.377 1.438 1.332 1.342 1.276 1.370 1.392 1.300 1.286 1.203 1.134 0.801 0.564 0.348 40 1.501 1.405 1.380 1.032 1.009 1.277 1.394 1.392 1.343 1.244 1.213 1.051 0.643 0.388 0.203 1.018 0.679 0.427 0.228 CD 38 1.547 1.503 1.375 1.041 1.032 1.343 1.333 1.379 1.336 1.249 1.189 36 1.516 1.427 1.456 1.375 1.379 1.332 1.383 1.322 1.281 1.248 1.166 1.008 0.678 0.441 0.237 -Il C

34 1.347 1.448 1.426 1.503 1.404 1.438 1.306 1.236 1.247 1.152 1.154 1.000 0.671 0.447 0.242 CD 32 1.099 1.345 1.514 1.546 1.499 1.376 1.370 1.101 1.045 1.124 1.192 1,005 0.680 0.441 0.241 30 1.098 1.345 1.513 1.546 1.499 1.376 1.370 1.101 1.045 1.123 1.192 1.005 0.680 0.440 0.241 C) 28 1.346 1.447 1.425 1.501 1.404 1.437 1.305 1.235 1.246 1.151 1.153 0.998 0.679 0.444 0,240 C) 26 1.515 1.426 1.455 1.374 1.378 1.331 1.382 1.321 1.280 1.246 1.162 1.003 0.663 0.437 0.235 CD 24 1.546 1.501 1.374 1.039 1.031 1.342 1.332 1.378 1.334 1.246 1.184 1.011 0.660 0.421 0.226 0 22 1.045 0.636 0.383 0.201 CD 1.499 1.404 1.378 1.030 1.008 1.276 1.392 1.390 1.340 1.241 1.208 en

(~.

20 1.376 1.436 1.331 1.341 1.275 1.369 1.391 1.299 1.284 1.200 1.131 0.798 0.561 0.346 18 1.369 1.305 1.381 1.332 1.392 1.390 1.361 1.293 1.303 1.182 1.091 0.867 0.438 16 1.100 1.235 1.321 1.378 1.389 1.298 1.292 1.172 1.094 1.113 0.804 0.565 0.323 14 1.044 1.246 1.280 1.334 1.340 1.283 1.302 1.092 0.860 0.789 0.610 0.405 0,230 12 1.124 1.152 1.248 1.247 1.241 1.199 1.181 1.110 0.786 0.573 0.418 0.261 10 1.193 1.155 1.165 1.187 1.209 1.130 1.090 0.802 0.605 0.417 0.274 8 1.007 1.002 1.009 1.015 1.046 0.796 0.865 0.563 0.407 0.261 6 0.680 0.682 0.684 0.669 0.637 0.557 0.434 0.322 0.229 4 0.441 0.452 0.441 0.423 0.380 0.319 2 0.241 0.242 0.238 0.227 0.198 Figure D.3 Quad Cities Unit 2 Representative Cycle 24 Radial Power Distribution at 0.0 MWd/MTU (Continued) z

,C")

C 1 3 ii 7 91 15 7 19 21 2 25 7 2 153 5.759 1124 1340 0.15 1793 1.19 2.16 .48 123 82 274 12986 60018 028 037 .9 .3 .0 14 0 135. 0.516 155 0.7 1.518 019135 58014 025 040 .9 .8 .8 0.222 1847 0.275 0.3269 0.3584 0.378 0.376 CD 56 060 095 0.0.8 1.34 0.208 0.301 0.409 0.2511 0.591 0.564 0.661 0.2675 54 068 0.33 092 148701.246 0.388 0.6679 0.669 0.933 1.1567 1.222 1.2487 1.2451**

52 .13 069 0.3 153201.24801 .404 061.9 0.493 1.219 1.144 1.408 1.238 1.474 1.428 50 0.148 0.248 0.592 0.7 0.9345.6

.6 1.27 1. 0 401124 1.4 681. 5161. 5551. 5511. .20 535 48 0.8 039 0.134 0.2459 0.403 0.593 0.781 1.238 1.222 1.475 1.274 1.289 1.5964 1.316 1.304 46 010 032 0.209 0.388 01023 0.955 1.523 1.153 1.428 1.489 1.252 1.267 1.536 1.527 1.268 C 0 344 010 . 0.303 0.668 0.932 1.270 1.222 1.4625 1.2794 1.489 1.2413 1.467 1.282 1.497 1.2415 Q 42 0. 2370. 4130.6 691.254 1206 1.401 1.474 1.489 1.2489 1.258 1.441 1.2151 1.447 1.2613 1.4250 40 0.138 0.279 0.512 0.934 1.1864 1.467 1.272 1.251 1.240 1.440 1.206 1.189 1.1596 1.415 1.2502O 38 0.1689 0.329 0.5694 1.159 1.409 1.5150 1.287 1.5265 1.465 1.213 1.4187 1.187 1.396 1.190 1.4162 C r 36 0.180 0.362 0.656 1.226 1.239 1.554 1.562 1.534 1.280 1.445 1.194 1.396 1.201 1.391 1.161 0 34 0.190 0.3827 0.672 1.252 1.474 1.550 1.314 1.525 1.494 1.259 1.413 1.189 1.391 1.199 1.4151 C 32 0.1937 0.378 0.677 1.254 1.2864 1.533 1.327 1.266 1.243 1.450 1.200 1.161 1.1595 1.413 1.2501 CD 30 012 0.2378 0.67612 .253 1.286 1.533 1.302 1.266 1.2420 1.450 1.200 1.161 1.159 1.413 1.250 C.

28 019 030 0.669 1.249 1.4732 1.550 1.231 1.525 1.495 1.2590 1.2413 1.189 1.390 1.199 1.24150 26 0.179 0.35 9 123 0.638 12710.554 1.523 1.535 1.281 1.446 1.1952 1.396 1.201 1.391 1.1619 24 0.164602063.47 0.5913.5

.0 .1 1.280 138 1.266 1.476 1.21 4 1.188 1.18 5136 1.3189 1.161 o*

22 0.137 0.24 0.511 0.78 0.9335.6

.6 1.27312 1 1.240 1.441 1269 1.5188 1.155 1.455 1.20136 18 0.303024 0.668061 0.932311702222011631628 1.490 1.241 1.467 1.282 1.9 125 16014 0.208 0.389 0.611 1.239 0.936 143 1409.5 1.176 6 1.537 1.2527 1.269 100136.4 0.140 0.611 0.93010.220 1.15 410 1.243065 1.46710.2877-84.4 .4 .8 .6 0.668 0.934 1.159 1.2262 1.252 1.254 2 0.135 0.167 0.181 0.190 0.192 Figure D.4 Quad Cities Unit 2 Representative Cycle 24 Radial Power Distribution at 15,484.8 MWdIMTU (EOFP) z

13-

m C a.

o r-3 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 0 60 0.191 0.189 0.179 0.165 0.135 58 0.376 0.379 0.359 0.326 0.275 0.218 56 0.674 0.661 0.645 0.590 0.509 0.409 0.301 0.208 0.134 CD 54 1.251 1.249 1,222 1.157 0.933 0.668 0.667 0.388 0.246 0.148 CD 1.286 1.474 1.239 1.409 1.165 1.220 0.933 0.611 0.405 0.249 0.153 CA 52 1.551 1.556 1.517 1.469 1.402 1.271 0.936 0.593 0.379 0.249 CD 50 48 1.535 1.305 1.316 1.565 1.290 1.275 1.476 1.223 1.239 0.781 0.593 0.406 0.148 0.246 0.134 0 46 44 1.269 1.245 1.527 1.498 1.537 1.283 1.268 1.468 1.253 1.242 1.490 1.491 1.463 1.281 1.176 1.463 1.239 1.223 0.937 1.271 0.611 0.933 0.389

0. 669 0.209 0.303 0

42 1.453 1.262 1.448 1.216 1.443 1.259 1.491 1.490 1.476 1.403 1.221 0.670 0.413 0.238 40 1.203 1.416 1.197 1.190 1.209 1.443 1.242 1.253 1.274 1.469 1.166 0.936 0,514 0.280 0.138 38 1.163 1.191 1.398 1.189 1.190 1.216 1.467 1.268 1.289 1.517 1.411 1.161 0.607 0.330 0.167 "11 0 36 1.162 1.393 1.203 1.398 1.197 1.448 1.283 1.536 1.564 1.556 1.240 1.226 0,648 0.362 0.180 C-34 1.416 1.200 1.392 1.191 1.416 1.262 1.497 1.527 1.316 1.552 1.475 1.252 0.663 0.382 0.190 C__

32 1.251 1.415 1.161 1.163 1.203 1.453 1.245 1.269 1.304 1.536 1.287 1.254 0.677 0.378 0.192 0 30 1.250 1.414 1.181 1.163 1.202 1.453 1.245 1.268 1.304 1.535 1.287 1.253 0.677 0.378 0.192 28 1.415 1.199 1.392 1.190 1.416 1.261 1.497 1.527 1.316 1.551 1.475 1.250 0.669 0.380 0.189 Co 26 1.161 1.392 1.202 1.398 1.196 1.448 1.282 1.537 1.564 1.556 1.239 1.223 0.638 0.360 0.179 CD 24 1.162 1.190 1.398 1.188 1.189 1.216 1.468 1.268 1.289 1.517 1.409 1.157 0.590 0.327 0.166 _0 22 1,201 1.415 1.196 1.189 1.207 1.443 1.242 1.253 1.274 1.469 1.165 0.934 0.510 0.278 0.137 CD 0 20 1.452 1.261 1.448 1.215 1.443 1.259 1.491 1.491 1.476 1.402 1.220 0. 669 0.412 0.237 18 1.245 1.498 1.283 1.468 1.242 1.491 1.281 1.464 1.224 1.272 0.933 0. 668 0.303 B 16 14 1.269 1.305 1,528 1.316 1.537 1.565 1.268 1.289 1.253 1.274 1.491 1.476 1.463 1.223 1.176 1.239 1.240 0.781 0.937 0.594 0.611 0.405 0.389 0.246 0.209 0.134 a) 12 1.536 1.552 1.556 1.517 1.469 1.402 1.271 0.935 0.592 0.378 0.249 0.148 10 1.287 1.476 1.240 1.410 1.165 1.220 0.933 0.611 0.403 0.248 0.153 8 1.254 1.252 1.226 1.159 0.935 0.669 0.667 0.388 0.246 0.148 6 0,677 0.671 0.656 0.595 0.511 0.410 0.301 0.208 0.134 4 0.378 0.381 0.362 0.328 0.276 0.218 2 0.192 0.190 0.181 0.167 0.135 Figure 0.4 Quad Cities Unit 2 Representative Cycle 24 Radial Power Distribution at 15,484.8 MWd/MTU (EOFP) (Continued)

,Oz CD-*-

ML15251A386

Text

Description:

Description:

Description:

Navigation menu

Search