Extended Power Uprate Data for NRC Confirmatory EPU Analyses

ML110120356
Person / Time
Site:	Saint Lucie
Issue date:	01/06/2011
From:	Richard Anderson Florida Power & Light Co
To:	Document Control Desk, Office of Nuclear Reactor Regulation
References
L-2010-278
Download: ML110120356 (94)
v • d • e

Text

Florida Power & Light Company, 6501 S. Ocean Drive, Jensen Beach, FL 34957 This letter forwards proprietary information in accordance with 10 CFR 2.390. The balance of this letter may be considered 3.

FlPL non-proprietary upon removal of Attachment January 6, 2011 L-2010-278 10 CFR 50.4 U. S. Nuclear Regulatory Commission Attn: Document Control Desk Washington, DC 20555 RE: St. Lucie Unit 2 Docket No. 50-389 Extended Power Uprate Data for NRC Confirmatory EPU analyses This letter provides the final St. Lucie Unit 2 data requested by the NRC via emails dated May 28, 2008, December 7, 2008, and June 13, 2010 that is needed to build St. Lucie-specific LOCA models for the NRC's confirmatory EPU analyses. This data is provided in Attachments I and 2.

Attachment 3 in its entirety contains information proprietary to Areva, and Attachment 4 contains the Areva affidavit for withholding Attachment 3 from public discloser. Please note that the Unit 2 Westinghouse proprietary information was previously provided in FPL letter L-2009-208 dated November 13, 2009 and is not resubmitted in this letter.

Please contact Ken Frehafer at 772-467-7748 or Kathy Rydman at 772-467-7680 if there are any questions regarding this information.

I declare under penalty of perjury that the foregoing is true and correct to the best of my knowledge.

Executed on January o ,2011.

Richard L. Anderson Site Vice President St. Lucie Plant RLA/KWF Attachments A-00 an FPL Group company

Attachment 1 to L-2010-278 ATTACHMENT 1 St. Lucie Unit 2 EPU Input Data Request to NRC for LOCA Model

Attachment I to L-2010-278 Page 1 of 59 ST. LUCIE UNIT 2 EPU Input Data Request to NRC for LOCA Model Item Parameter -Description Units Value Comments No.

1. Plant Operating Conditions

= * ': *:* =' ' .,: *',

I . For rated power conditions (Current):

a.

1. Primary and Secondary Flow rates:

1.1. Core flow Unc: + 14,500 gpm and gpm 403,500 min flow is 335,000.

1.2. Main coolant pumps 97,500 (2A1) gpm 96,000 (2A2) RCP Pump Test Data 94,000 (2B2) 1.3. Steam flow lbm/hr See Item la 7.1 1.4. Feedwater flow Ibm/hr See Item I a 7.1 1.5. SG recirculation ratio/boiler  % Power Circ section flow Ratio

% Power- 20 18.41 50 7.91 CircRatio 70 5.42 90 3.96 100 3.46

2. Primary and Secondary Pressures:

2.1. Pressurizer Nominal Operating Pressure is 2250 psia.

Pressure range is 2225 to 2275, with Unc: +/- 45

Attachment 1 to L-2010-278 Page 2 of 59 Item Parameter -Description Units Value Comments No.

Normal, + 90 Accident.

2.2. Core inlet Based on 2250 psia core psia 2286 outlet and 35.5 psi core pressure drop (UFSAR Table 4.4-4).

2.3. Core outlet Assumed to be the same as the pressurizer.

2.4. Reactor coolant pump Assume a I psi pressure discharge psia 2287 drop from RCP discharge to core inlet.

2.5. Steam generator dome SG outlet pressure from benchmark heat balance psia 886.8 at 100% Power plus dP to upstream of flow restrictor 2.6. Turbine control valve inlet Benchmark Heat psia 852.7Banc Balance 2.7 drop Detailed primary loop pressure distribution pAssumes ps al 3blw plugging. 10% SG tube 3u Primary and Secondaryi Temperatures: * ' *J * *'***'**

3.1. Hot leg Assumed to bem tue same as the core outlet OF 595 temperature since the Rx vessel does not have upper head injection.

3.2. Cold leg OF 549 Tcold temperature at full Unc: +/- 3F power.

3.3. Core outlet 595 OF

Attachment I to L-2010-278 Page 3 of 59 Item Parameter -Description Units Value Comments No.

3.4. Upper Head Assumed to be the same as the core outlet OF 595 temperature since the Rx vessel does not have upper head injection.

4. Water levels in the pressurizer and steam generators, 4.1. Pressurizer

% Tap Span See Figure 1 4.2. Steam Generators in 411.3 Level above tubesheet

5. Leakage flows (Bypass): This is the total core

% of vessel 3.7 bypass maximum value flow for minimum core flow rate.

5.1. Outlet nozzle clearances Assume bypass breakdown documented in Unit 1 UFSAR due to unit similarities.

5.2. Downcomer to upper head Assume bypass percent 0.16 breakdown documented in Unit 1 UFSAR due to unit similarities.

5.3. CEA shrouds Equivalent to a fraction of the leakage through percent N/A guide tubes (item la.5.5.1). This has not been quantified.

5.4. Upper head to upper plenum This has not been percent N/A quantified.

(guide structure holes) 5.5. Core bypass (guide tubes,

______ I barrel-baffle)

Attachment I to L-2010-278 Page 4 of 59 Item Parameter -Description Units Value Comments No.

5.5.1. Guide tubes Assume bypass breakdown documented in Unit 1 UFSAR due to unit similarities.

5.5.2. Barrel-baffle Assume bypass breakdown documented in Unit I UFSAR due to unit similarities.

6. Steam generator recirculation  % Power-ratio CircRatio

7. Heat balance information such as:

7.1. Feed and steam flows Ibm/hr 11,905,010 Benchmark Heat 11,806,740 Balance 7.2. Feedwater temperature Benchmark Heat Balance 7.3. Turbine inlet pressure. Benchmark Heat

1. Plant Operating Conditions Ib. For EPU conditions.

1.raesPrimary and Secondary Flow i

• 1.1. Core flow 4Minimum flow is gpm 403,500 375,000 gpm.

1.2. Reactor coolant pumps 97,500 (2A1) gpmgpm 96,000 (213 95,000 (2A2)1) RCP Pump Test Data 94,000 (2B2) 1.3. Steam flow lbm/s See Item lb 7.1 1.4. Feedwater flow Ibm/hr See Item l b 7.1 1.5. SG recirculation ratio/boiler  % Power-  % Power Circ

Attachment I to L-2010-278 Page 5 of 59 Item Parameter -Description Units Value Comments No.

section flow Ratio CircRatio 25 13.67 50 6.97 75 4.36 100 3.02

2. Primary and Secondary Pressures , ... .

(absolute pressures): "

2.1. Pressurizer Range: 2225 to 2275 2250 psia.

psia Unc.: + 45 psi normal,

+ 90 psi harsh.

2.2. Core inlet psia Assumed to remain 2286 similar to current conditions.

2.3. Core outlet psia Assumed to remain 2250 similar to current conditions.

2.4. Reactor coolant pump psia Assumed to remain discharge 2287 similar to current conditions.

2.5. Steam generator dome psia SG outlet pressure from benchmark heat balance at 100% Power plus dP to upstream of flow restrictor 2.6. Turbine control valve inlet psia Table 14 ----

2.7 Detailed primary loop psi Table 13 beloow Assumes 10% SG tube pressure drop distribution plugging.

3. Primary and Secondary Temperatures:

3.1 Hot leg OF 606.0 Assumes 10% SG tube plugging.

3.2 Cold leg OF 551 Corresponds to 100%

Unc: +/- 3F Power. Tcold at zero

Attachment I to L-2010-278 Page 6 of 59 Item Parameter -Description Units Value Comments No.

power is 532F.

3.3 Core outlet OF 607.9 Assumes 10% SG tube plugging.

3.4 Upper Head OF 606.0 Assumed to be the same as vessel outlet.

SWater levels in the pressurizer per and steam generators p N/ quantified.

4.1 Pressurizer  % Tap Span See Figure I below 4.2 Steam Generators in 411.3 Level above tubesheet 5 Leakage flows:  % of vessel 37----

flow 5.1 Outlet nozzle clearances pecn .2Assumed to be similar to current operating value.

5.2 DC to upper head percent 0.16 Assumed to be similar to current operating value.

5.3 CEA shroudsre oThis has not been quantified.

5.4 Upper head to upper plenum This has not been (guide structure holes) S Abquantified.

5.5 Corebnebypass (guide tubes, Se Table 1 5.5.1 Guide tubes pecn .6Assumed to be similar to current operating value.

5.5.2 Barrel-baffle pecn .7Assumed to be similar to current operating value.

6 Steam generator recirculation Pow er-Se It mIb 1.-----

ratio %CircRatio 7 Heat balance information such as:*: I 7.1 Feedwater and steam flows lbm/hr See Tab]e 14 ----

7.2 Feedwater temperature OF See Table 14 ----

7.3 Turbine inlet pressure. psia See Table 14 ----

Attachment I to L-2010-278 Page 7 of 59 Item Parameter -Description Units Value Comments No.

2. Analysis Topical Reports See Keterences provided below applicable to rated power:

" CENPD-132, through Suppl. 4-P-A, "Calculative Method for the CE Nuclear Power Large Break LOCA

1. Topical Report on the Evaluation Model",

March 200 1.

licensing analysis of record for See See Comment

• CENPD-137, LOCA at rated power and EPU Comment through Suppl. 2-P-conditions. A, "Calculative Method for the ABB CE Small Break LOCA Evaluation Model",

"April 1998.

No new Topical Reports for EPU analyses.

Analysis results are in the UFSAR.

3. Safety System Logic, Setpoints and Delay Times Critical Safety Parameters List (also called "Groundrules document") for the last reload for:

1. ESFAS I See Iable [ See lable ) I See I aOle -

2. RPS i See Table 5 See Table 5 See Table 5

Attachment I to L-2010-278 Page 8 of 59 Item Parameter -Description Units Value Comments N o. 3_S le 5T

3. SGIS/MSIS See Table 5 See Table 5 See Table 5

4. PORV See Table 5 See Table 5 See Table 5

5. SRV. See Table 5 See Table 5 See Table 5

4. Primary and Secondary Pressure Drops

1. Primary side pressure drop distribution with corresponding See Table flow rate, including leakage flows 13 See Table 13 (from design data or vendor analyses).

2. Secondary side pressure drop distribution with corresponding See flow rate, including leakage flows Attachment See Attachment 3 (from design data or vendor 3 analyses).

5. Core and Fuel Design S§....

1. Number of assemblies N/A 217 ---

2. Dimensions Array: 16 x 16, The pitch is the sum of N/A Pitch: 8.180 in, 7.972 and 0.208 = 8.180 Length: 158.5 in in.

3. Spacer grid locations and K- See Table 4 for factors N/A grid locations and K-factors.

4. Vessel pressure drops Current values:

a) Inlet nozzle & 90 a) 5.0 degree turn, b) 10.4 b) Downcomer, lower c) 13.4 plenum, support d) 6.7 structure, c) Fuel assembly, d) Fuel assembly outlet to outlet nozzle.

Attachment I to L-2010-278 Page 9 of 59 Item Parameter -Description Units Value Comments No.

5. Bypass and leakage flows  % of total See item la.5.5 Similar to Item la.5.5 flow above above.

6. Number and location of fuel rods. 236 per assy Some fuel rods contain N/A 51,212 total. burnable absorber See Figs. 3 and 4 below for location.

7. Number and location of guide 5 guide tubes per tubes. N/A assy.

See Fig. 3 below for location.

Equipment Drawings and 7.

6. Design Reports To confirm the calculation of flow @*

path lengths and elevations, flow-- SeeTabe areas, volumes, metal mass and surface areas (including pipea schedules), and form loss (due to bends, contractions, expansions,

.rifices, etc.) for the followingpup SeT

4. Reactor vessel and internals (identification of all core bypass flow paths and flow rates, --- See Table 3 including upper plenum or head to downcomer, if available).

2. Prim ary loop piping (hot leg, cold-- Se Tal 3--

leg, pump suction)

3. Reactor coolant pumps --- See Table 3 ---

4. Steam generators and internals (U -tube lengths, separators, inlet-- Se Tal 3--

and outlet plenum, etc.), (TH Design Report)

Attachment I to L-2010-278 Page 10 of 59 Item Parameter -Description Units Value Comments No.

5. Pressurizer, surge line, spray lines, safety and relief valves and See Table 3 connecting lines, etc.

6. Main steam lines out to the turbine stop valves, including safety and relief valves and See Table 3 connecting lines, main steam isolation valves, flow restrictors, etc.

7. Main feedwater lines from the isolation valves to the steam See Table 3 generator inlet.

8. Auxiliary feedwater lines and feedwater pump type, See Table 3 configuration and capacity.

9. Safety injection equipment including SITs, high and low pressure injection systems and connecting piping.

10. Charging and letdown system See Table 3 (CVCS).

11. Residual heat removal system. See Item 6.9 for LPSI See Comments System. LPSI and RHR are the same system.

7. Reactor Vessel Internals .

Weight and surface area of reactor vessel internal structures:

8. Core support barrel Includes upper, center, 136,600 / and lower portions of the Lbs I sq. ft. 1126 Inside core support barrel; 1110 outside upper and lower flange; inner and outer nozzle

Attachment I to L-2010-278 Page 11 of 59 Item Parameter -Description Units Value Comments No.

areas.

9. Core shroud 34,000 / Includes vertical and Lbs / sq. ft. 594 Inside horizontal surfaces of the 867 outside core shroud.

10. Lower core support plate Includes top and bottom surfaces; surface areas Lbs / sq. ft. 8,000 /260 inside the holes of the plate.

11. Fuel alignment plate (Upper Core Includes top and bottom Plate) Lbs / sq. ft. 9,900/331 surfaces; surface areas inside the holes of the plate.

12. Upper guide structure Includes CEA shrouds with extensions; total UGS plate, flange, beam, c ln er ar ea toal Lbs I sq. ft . 120,000 / 7,120 &&cylinder areas; total fuel alignment plate area (Neglects guide tubes).

13. Core support assembly Includes vertical webs; flanges; cylinder; Lbs I sq. ft. 45,500 / 1193 columns; core support plate; bottom plate.

14. Flow skirt Includes top and bottom surfaces; surface areas Lbs I sq. ft. 3,600 / 223 inside the holes of the plate.

15. Control element assembly (CEA) 48,000/ Does not include shrouds Lbs / sq. ft. 18262100 Inside otside Doesunottinclude shroud extensions.

2 100 outside

16. Shroud extensions 10,400/

Lbs / sq. ft. 866 Inside -----

1035 outside

17. Grid assemblies /q.Each assembly has 9 Lbs I sq. ft. 18.5 I 5.0 per Grid grids for 217 assemblies.

Attachment I to L-2010-278 Page 12 of 59 Item Parameter -Description Units Value Comments No.

8. Steam Generator Internals

1. Weight of steam generator tube * .**;*****

. .*,4 ' :

sheet and surface area of tube * -7

• 7

,,;,i*. :*

sheet exposed to primary side K fluid.

1.1. Weight of Tube Sheet Weight with integral Ibm 93,230 forged lower cylindrical ring and cladding 1.2. Surface area of Tube Sheet in2 11251 (Primary Side)

2. Weight and surface area of steam ... ..  :

generator wrapper.

2. 1. Weight of SG wrapper Ibm 34,730 Includes wrapper roof 2.2. Surface area of SG wrapper ft2 1354 Wetted surface area on

-downcomer side

9. Steam Generator Fluid Volumes

4. Inlet plenum t 338.4 Includes Manway

2. Outlet plenum Wt 332.0 Includes Manway

3. Active and Wt 1230.0 inactive (within tube sheet) tubes 82.6

4. Number of steam generator tubes 8999

5. Length of shortest and longest in Single straight leg tube Length includes twice the straight length above 538.2 min the tubesheet, plus the U-776.6 max bend.

10. Steam Generator Parameters

Attachment I to L-2010-278 Page 13 of 59 Item Parameter -Description Units Value Comments No.

1. Inventory and recirculation ratio Power Secondary versus load (essential at rated Mass Inventory for clean, power conditions) 0 215680 unplugged tubes at EPU Ibm 25 183730 conditions. Recirculation 50 163860 ratios provided in Item 75 149910 lb. 1.5 100 139410

2. SG flow areas, K-factors and flows See Attachment See Attachment 3 3

11. MS Line Flow Restrictor 1.91 ft2 is the SG outlet Rstrctorflo

1. are ft 1.9 pe SG nozzle area. The main line flow venturi area is 2.27 ft2 per SG.

Steam Generator and Reactor

12. Vessel Heights

1. Volume versus height relationship for the steam generators with downcomer and boiler regions provided separately

2. Volume versus height for the reactor vessel with internals See Table 6 See Table 6 ----

installed

13. Reactor Coolant Pump Rated Conditions

1. Head ft 296.75 The value is the average of the four pum p-specific

Attachment I to L-2010-278 Page 14 of 59 Item Parameter -Description Units Value Comments No.

values (303, 296, 293 &

295 ft)

2. Flow The value is the average gpm 87,750 of the four pump-specific values (85,000 - 87,500 -

91,000 & 87,500 gpm)

3. Torque The value is the average lbf-fi 33,950 of the four pump-specific values (33,860 - 34,000

- 34,720 & 33,230 ft-lbf)

4. Speed rpm 900 Synchronous speed

5. Density The value is the average Ibm] ft3 4of the four pump-specific values (47.3, 47.4, 46.9 and 48.4 Ibm/ ft3 )

6. Homologous pump curves (four N/A See Table 7 quadrant)

7. Pump inertia and friction Uncertainty value of+

(coefficients of polynomial in 1% may be applied to pump speed) lbm-ft2 102,000 pump inertia in the analysis to gain ft-lbf 2735 operating margin.

- Constant for friction and windage torque.

8. Coolant primary system fluid ft3 112 volume within pump

9. RCP metal mass, excluding motor lbs 75,000 Dry weight.

10. Reverse rotation device RCP design torque for operational for RCPs N/A Yes anti-reverse rotation device equal to 62,000 ft-lbf.

11. Pump power to primary fluid MWt 14.2 (nominal),

Attachment 1 to L-2010-278 Page 15 of 59 Item Parameter -Description Units Value Comments No.

20 (max)

12. Coastdown characteristics N/A Figure 2

13. Pump trip setpoints N/A Overcurrent Overload Trip

14. Pump time delays and logic N/A N/A No safety related RCP trips.

14. Core Cooling System

1. HPSI and LPSI delivery curves gpm See Tables118, 9, 10,

2. SIT total volume ft3 1855 Four tanks, each with this capacity.

3. SIT initial pressure and liquid psia 3

(500 to 650 + 15) TS ranges for SIT volume W * (1420 to 1556 + pressure and liquid

32) volume.

4. CST minimum capacity gal 276,200

5. Charging pump flow versus Reciprocal pump. Flow pressure 40 (nominal) to 49 is per charging pump.

gpm (maximum) Nominal value does not 35 minimum, after include 4 gpm for RCP uncertainties bleed-off.

15.a Control Systems Rated power operation of the primary and secondary control systems for:

1. SG water level instrumentation Pre-EPU description of and control (three-element) the SG water level control system is provided in UFSAR N/A See Comment Figure 7.7-5. Additional information is contained in System Description 0711408 "Steam Generators and

Attachment I to L-2010-278 Page 16 of 59 Item Parameter -Description Units Value Comments No.

Feedwater Control System"

2. SG pressure (including bypass Pre-EPU description of and ADV) the Steam Bypass Control System is contained in UFSAR Sections 7.2.2.5.3, 7.4.1.4, 7.7.1.1.5, and 10.4.4. Reference Figure 19 (SBCS Simplified Block Diagram). See Essential Valve Characteristics Table 20 for operation of Atmospheric Dump Valves

3. Pressurizer heaters and sprays Pre-EPU description of the Pressurizer Pressure Control System is provided in Figure 16

4. Pressurizer level Pre-EPU description of the Pressurizer Level N/A See Comment Control System is contained in Figures 1 and 17

5. Auxiliary feedwater See Table 5 for Auxiliary Feedwater Actuation System setpoints.

The Auxiliary Feedwater N/A See Comment Actuation System logic is described in UFSAR Section 7.3.1.1.8 and UFSAR Figures 7.3-12 (drawing 2998-12613) &

7.3.14 (drawing 2998-

Attachment 1 to L-2010-278 Page 17 of 59 Item Parameter -Description Units Value Comments No.

15003)

6. CVCS (charging and letdown) Pre-EPU description of the CVCS System is contained in UFSAR Section 9.3.4 15.b Control Systems .. , **..

• EPU condition operation of the ** **

primary and secondary control systems for: i..

1. SG water level instrumentation Feedwater Control and control (three-element) System will be rescaled to reflect new FW pumps, new FW control valves and an expanded nominal flow rate. The post-trip transition logic for main to low power FW control valves will also be revised to improve SG level response.

2. SG pressure (including bypass EPU does not change and ADV) ADV control logic or setpoints. Steam Bypass valve capacity will be increased by EPU to restore design capacity in N/A See Comment %RTP. The SBCS is fntoal functionally implemented in the plant Distributed Control System (DCS). SBCS will be rescaled to match new valve Cv curves.

Quick Open setpoint for

Attachment I to L-2010-278 Page 18 of 59 Item Parameter -Description Units Value Comments No.

sudden loss of load will be decreased from 30%

to z15%. Transition from Quick Open logic to Modulation control will be modified (through the use of controller output signal tracking) to smooth the steam header pressure response.

3. Pressurizer heaters and sprays EPU does not change the Pressurizer Pressure control logic or setpoints.

4. Pressurizer level The Pressurizer Level Control Program will be rescaled to reflect the increased Tavg range from 0 to 100% RTP.

Program endpoints in terms of volume will remain as is.

5. Auxiliary feedwater EPU does not change the N/A See Comment AFAS actuation logic or setpoints.

6. CVCS (charging and letdown) EPU does not change N/A See Comment CVCS control logic or

- -setpoints

16. Reactor Vessel Upper Head Assume to be the same

1. Upper head fluid temperature See item 1.b.3.4 as the core outlet

.above, temperature since the Rx at normal operating conditions. avessel does not have upper head injection.

Attachment I to L-2010-278 Page 19 of 59 Item Parameter -Description Units I Value Comments No.

17. Essential Valve Characteristics Number of valves, full open flow area, forward/ reverse flow coefficients (CV's), open/close rate, minimum flow at rated conditions, logic for opening and closing the valves for:

1. P'ressurizer POKVs See I ables 12 & 20-

2. Pressurizer safety valves Se Tables 12 & 20

3. Main steam safety valves See Tables 12 & 20

4. Atmospheric dump valves -------- See Tables 12 & 20

5. TCVs (turbine control valves) See Tables 12 & 20

6. Turbine bypass valves See Tables 12 & 20

7. TSVs, (turbine stop valves) See Tables 12 & 20

8. MFIVs See Tables 12 & 20

9. MSIVs See Tables 12 & 20 18.

to Reactor Core Parameters 20.

1. Control rod insertion versus time See after scram Attachment See Attachment 2 2

2. CEA worth versus insertion (with See and without highest worth rod Attachment See Attachment 2 stuck out of core) 2

3. Reactivity versus fuel See temperature and reactivity versus Attachment See Attachment 2 moderator density 2

4. Moderator temperature See ASee Attachment 2

Attachment 1 to L-2010-278 Page 20 of 59 Item Parameter -Description Units Value Comments No.

coefficient 2

5. Typical top peaked axial power See profile Attachment See Attachment 2 2

6. Minimum and maximum average See fuel clad gap conductivity at rated Attachment See Attachment 2 power conditions 2

7. Minimum local gap conductance See as a function of LHGR Attachment See Attachment 2 2

8. Gap conductance See Attachment See Attachment 2 2

9. Linear heat rate See Attachment See Attachment 2 2

10. Fuel average and centerline temperature as a function of AttachmentSee See Attachment 2 burnup for the hot rod in the hot 2 bundle.

11. Specifications for modeling a small break LOCA, in particular what models/assumptions are used regarding loop seal clearing and hot channel conservatisms.

The AREVA SBLOCA See methodology topical report was Attachment See Attachment 2 2

provided and this is very useful.

The FSAR or a report on the analysis of record is needed to move from the generic methodology to the plant specific application. Plots of key variables for the EPU LBLOCA

Attachment I to L-2010-278 Page 21 of 59 Item Parameter -Description No.

and SBLOCA analyses, including containment pressure response.

21. Operator Actions During LOCA

1. Reactor coolant pump trips Accident analysis (conditions to trip pumps - assumes LOOP automatic or manual) concurrent with LOCA, Pumps and pumps are not None automatically trip loaded into EDGs or on LOOP manually operated. Same assumption for EPU analysis.

2. HPSI throttling criteria If HPSI pumps are operating, and ALL of the following conditions are satisfied:

- RCS subcooling is greater than or equal to minimum subcooling

- Pressurizer level is at See Comments None least 30%

Section.

and NOT lowering,

- At least ONE S/G is available for RCS heat removal with level being restored to or maintained between 60 and 70% NR,

- Rx Vessel level indicates sensors 4 through 8 are covered, or

Attachment I to L-2010-278 Page 22 of 59 Item Parameter -Description Units Value Comments No.

NO abnormal differences (greater than 20'F) between THOT and Rep CET temperature, Then, THROTTLE Sl flow. Same assumption for EPU analysis.

3. MS line break auxiliary feedwater Due to the design of the control AFW system that automatically isolates the AFW from the broken loop, no auxiliary N/A See comment feedwater was assumed to be delivered during the post-trip MSLB event. No flow delivered for pre-trip MSLB either.

Most recent COLR provided to NRC via See FPL letter L-2009-116,

22. Core Operating Limits Report Comment See Comment dated 05-11-2009. EPU COLR to be provided

23. RCS Material Property Data For the various materials in the reactor coolant system (stainless steel, inconel, etc.):

I1. Density

2. Specific heat

3. Thermal conductivity

Attachment 1 to L-2010-278 Page 23 of 59 Item Parameter -Description Units Value Comments No.

2. Emissivity versus temperature See Table 15

24. Power Level / Uncertainty (New Requests)

1. Current Power Level MWth 2700

2. Current Power Uncertainty  % 2 Applicable for both (LBLOCA/SBLOCA) LBLOCA and SBLOCA

3. EPU Power Level Mwth 3020

4. EPU Power Uncertainty  % 0.3 @ full power. Applicable for both (LBLOCA/SBLOCA) LBLOCA and SBLOCA

Attachment I to L-2010-278 Page 24 of 59 Figure 1 ST. LUCIE UNIT 2 PRESSURIZER LEVEL PROGRAM Note: The Values Refer to the Actual Plant Settings Pressurizer Volume at 63.0% Span is 914 Cu. Ft.

Pressurizer Volume at 33.1% Span is 463 Cu. Ft.

Attachment I to L-2010-278 Page 25 of 59 Figure 2 - RCP Coastdown 800 600 0

0:

W, 300 FLORIDA POWER & LIGHT COMPANY ST. LUCIE PLANT UNIT 2 FIGURE 15.3.2-1 Complete Loss of Flow -

Four Pumps Coasting Down Total Core Inlet Flow versus Time 15.3-10 Amendment No. 17 (12/06)

Note: Curve represents current analyses.

Attachment I to L-2010-278 Page 26 of 59 Figure 3 CORE SUI BARREL

Attachment I to L-2010-278 Page 27 of 59 Figure 4 T S RPNMLK J HG F E II 1 II II U10 U66 1U120 X68IX62 L-2 V-I7 X45 Xl I U08I U43I X34I U22 X36 I U37 )U03IX16 I X46 F-16 FEEDFEED N-2 V-9 FEED L-13 FEED 0--9 J-2 FEED FEED F-7 U23 T42 IX18 IU48I TO5 IX27 I71-I U54 T55 1X28 I47 UTO X-10 T36 IU31 R-5 F-6 FEED -4 X-17 FEED R-0 R-3 R-13 FEED B-17 V-4 FEED S-5 G-5 TEE X63 U06 TO? X37 T09 U56 T01 U65 T16 X42 T1I U05 X51 I T63 L-18 'FEED B-13 -20 FEED H-1 5.19 L-17 F-19 P-1 FEED E-20 X13 FEED G-11 ------- 16 T41 )059 U40 X31 T11 U53 X12 T47 X22 U60 TOE X23 U38 X70 T29 U)27 F-18 FEED J-16 FEED A-8 G-3 FEED G-7 FEED W-7 Y-8 FEED N-l. FEED S-IA 1)36 -14 N-6 X64 U34 X43 T59 U10 X`19 T52 X04 T45 X20 U68 172 X33 U12 X52 TE7 FEED T4 FEED N-7 W-16 FEED W-11 FEED L-19 FEED C-16 N-15 FEED E4- FEED X06 159 U19 U55 T02 T51 )(06 S78 X07 T60 T03 U52 U09 U62 X01 87-

]-13 12 FEED1-11 N-il C-7 1-11 G-15 FEED E!13 FEED R-7 E-11 W-15 J-11 X-11 FEED 162 T-5 TX5"11 X44 T61 U57 X15 T49 X08 "48 X17 V49 T56 X-35 U18 X60 T62 -10 U35 FEED T-18 FEED J-7 W-6 FEED L-3 FEED C-11I FEED C-6 J-16 FEED E-18 FEED E-5 N-l6 T34 X71 U39 X09 T13 U11 X,26 T46 X14 U58 T12 X13 1)44 X65 T31 U13 -

J1 F-4 FEED J-4 FEED A-14 C-15 FEED R-15 FEED R-19 Y-14 FEED N-4 FEED S-4 16 M7 110i T14 X40 T20 U63 T04 U67 T18 X41 T17 U07 X58 T68 R-11 FEED B-9 T-2 FEED H-21 S-3 L-6 F-3 P-21 FEED E-2 (-9 FEED L-4 ______

U29 T3 X30 1U46 T15 X29 170 1)64 T60 X(25 T10 U45 X32 733 U30 S F-iFEED 0-18 X-4 FEED01-9 G-19 G-13 FEED 8-5 V-18 FEED 5-117 G-17 ______5 T261I(47 ,X24I U02 U1411 X38 U616 X39I U421 U041 X21 X46 T25 4 B-15 FEEDFEED N-20 V-1I FEEDI L-9 FEED D-13 J-20 FEED FEED S-7 ______ 4 I43I X53 IX72I U14 U51 I1U26I X67 X55 T30 T22 T24 R-16 E-16 FEED FEED D-5 L-20 V-5 FEED FEED T-16I R-6 3 U32 IT67 I132 IX494 X03 I(61 IT44 T64 U33 FromCycle15 E-7 V-1i V-16 FEED FEED FEED 0-16 L-7 T-7 2 rOyde 14

'Fm Fy7] Idenlifie" AssemTbly COPAN IŽZI Prevwms Cycle Location 18w PWER LIGT FLORDA FLORIDA POWER &LIGHT COMPANY ST. LUCIE PLANT UNIT 2 CYCLE 17 REFERENCE CORE LOADING PATTERN FIGURE 4.3-65 Amendment No. 18 (01/08)

Attachment I to L-2010-278 Page 28 of 59 Table 1 (Not Used)

Attachment I to L-2010-278 Page 29 of 59 Table 2 (Not Used)

Attachment I to L-2010-278 Page 30 of 59 Table 3 Unit 2 Piping Isometric Drawings by P&ID Flow Diagram Component/Isometric Drawing Reactor Vessel 2998-G-078, Sheet 110, Rev. 08 /2998-769, Rev. 2 Primary Loop Piping (RCS) 2998-G-078, Sheet 110, Rev. 08 2998-2662, Rev. 4 2998-2132, Rev. 6 2998-3793, Rev. 1 2998-1887, Rev. 3 2998-1886, Rev. 6 Reactor Coolant Pumps 2998-G-078, Sheet 11 IA, Rev. 11 2998-455, Rev. 6 2998-G-078, Sheet 111 B, Rev. 10 2998-457, Rev. 8 Iheet 2998-G-078, Sheet 11 IC,Rev. 13 2998-G-078, Sheet 11 ID, Rev. 10 Steam Generators 2998-G-078, Sheet 110, Rev. 8 2998-21342 Rev 0 2998-G_079,_ 1,_Rev._41 2998-G-079, Sheet 2A, 2998-G-080, Rev.4143 1, Rev.

Pressurizer/Surge Line/Spray Lines/Relief Lines 2998-G-078, Sheet 109, Rev. 18 2998-506, Rev 4 2998-G-078, Sheet 108, Rev. 5 2998-G-125, Sheet RC-AB-1, Rev 13 2998-G-125, Sheet RC-AB-2, Rev 11 2998-2048, Rev 5 Main Steam Lines Out to the Turbine Stop Valves 2998-G-079, Sheet 1, Rev. 41 2998-G-125, Sheet MS-L-l, Rev. 22 2998-G-079, Sheet 2, Rev. 35 2998-G-125, Sheet MS-L-2, Rev. 22 2998-G-125, Sheet MS-L-3, Rev. 10 2998-G-125, Sheet MS-L-4, Rev. 16 2998-G-125, Sheet MS-L-13, Rev. 11 2998-G-125, Sheet MS-L-14, Rev. 16 Main Feedwater Lines from the Isolation Valves to the Steam Generator Inlet 2998-G-080, Sheet 2A, Rev. 43 [ 2998-G-125, Sheet BF-M-6, Rev. 17 Auxiliary Feedwater Lines 2998-G-080, Sheet 2B, Rev. 36 2998-G-125, Sheet BF-M-7, Rev. 18 2998-G-125, Sheet BF-M-8, Rev. 20 1 2998-G-125, Sheet BF-M-9, Rev. 16 Safety Injection 2998-G-078, Sheet 130A, Rev. 19 2998-G-125, Sheet SI-N-4, Rev. 20 2998-G-078, Sheet 130B, Rev. 28 2998-G-125, Sheet SI-N-5, Rev. 19 2998-G-078, Sheet 131, Rev. 20 2998-G-125, Sheet SI-N-6, Rev. 18 2998-G-078, Sheet 132, Rev. 09 2998-G-125, Sheet SI-N-7, Rev. 15 2998-G-078, Sheet 110, Rev. 08 2998-G-125, Sheet SI-N-8, Rev. 18 2998-G-125, Sheet SI-N-9, Rev. 20

Attachment I to L-2010-278 Page 31 of 59 2998-G-125, Sheet SI-N-14, Rev. 25 2998-G-125, Sheet SI-N-16, Rev. 17 2998-G-125, Sheet SI-N-17, Rev. 14 2998-G-125, Sheet SI-N-18, Rev. 12 2998-G-125, Sheet SI-N-19, Rev. 15 2998-G-125, Sheet SI-N-20, Rev. 14 2998-G-125, Sheet SI-N-21, Rev. 13 2998-G-125, Sheet CS-K-1, Rev. 19 2998-G-125, Sheet CS-K-2, Rev. 20 2998-C-124, Sheet SI-I, Rev. 12 2998-C-124, Sheet SI-2, Rev. 10 2998-C-124, Sheet SI-3, Rev. 12 2998-C-124, Sheet SI-4, Rev. 13 2998-C-124, Sheet RC-I, Rev. 9 2998-C-124, Sheet RC-2, Rev. 13 Charging and Letdown System (CVCS) 2998-G-078, Sheet 110, Rev. 08 2998-G-125, Sheet CH-G-1, Rev. 21 2998-G-078, Sheet 120, Rev. 17 2998-G-125, Sheet CH-G-2, Rev. 19 2998-G-078, Sheet 121A, Rev. 31 2998-G-125, Sheet CH-G-3, Rev. 16 2998-G-078, Sheet 122, Rev. 25 2998-G-125, Sheet CH-G-4, Rev. 21 2998-G-125, Sheet CH-G-10, Rev. 12 2998-G-125, Sheet CH-G-14, Rev. 11 2998-G-125, Sheet CH-G--15, Rev. 15 2998-G-125, Sheet CH-G-16, Rev. 06 2998-G-125, Sheet CH-G-17, Rev. 13 2998-C-124, Sheet CH-1, Rev. 11 2998-C-124, Sheet CH-3, Rev. 12 2998-C- 124, Sheet CH-4, Rev. 09 2998-C-124, Sheet CH-6, Rev. 8 2998-C-124, Sheet CH-33, Rev. 7 2998-C-124, Sheet CH-72, Rev. 15 2998-C-124, Sheet CH-75, Rev. 14 2998-C-124, Sheet CH-78, Rev. 12 2998-C-124, Sheet CH-103, Rev. 9 2998-C-124, Sheet CH-104, Rev. 8 2998-C- 124, Sheet CH- 105, Rev. 6 2998-C-124, Sheet CH-106, Rev. 13 2998-C-124, Sheet CH-108, Rev. 7 2998-C- 124, Sheet CH- 109, Rev. 17 2998-C-124, Sheet CH-I 10, Rev. 14 2998-C-124, Sheet CH-I 11, Rev. 11 2998-C- 124, Sheet CH- 112, Rev. 13 2998-C-124, Sheet CH-129, Rev. 0 2998-C-124, Sheet RC-2, Rev. 13

Attachment I to L-2010-278 Page 32 of 59 Table 4 Spacer Grid Locations Grid # Distance (in) 1 5.175 2 22.375 3 38.188 4 54.000 5 69.812 6 85.625 7 101.438 8 117.250 9 133.062 10 148.875 Note: Measured from bottom of fuel assembly to top of grid.

K-Factors Location K-Factor Core inlet region/ bottom grid 1.18 Mid-grid 8 spacers (total) 5.68 Top grid (Top grid representative of inconel top grid) 0.69 Upper End Fitting 0.53 Note: Conditions: 50OF isothermal and 388,600 gpm vessel flow rate.

Attachment 1 to L-2010-278 Page 33 of 59 Table 5 RPSq F*Tl'AS and Af'A* Setnnints and Safetv Analvsis Limits Functional Description Monthly Tech Spec Setpoint Current Setpoint or EPU Setpoint or Comments Surveillance Uncertainty Requirement Uncertainty Setpoint (current cycle) Requirement RPS PZR Press Hi 2360 psia < 2370 psia + 45 psi (Normal) +/- 45 psi (Normal)

+/- 90 psi (Accident) +/- 90 psi (Accident)

RPS Cont. Press Hi 2.5 psig <3.0 psig +/- 1.65 psi +/- 1.65 psi RPS S/G Press Lo 626 psia > 626 psia +/- 40 psi (Normal) +/- 40 psi (Normal)

+/- 80 psi (Accident) +/- 80 psi (Accident)

RPS S/G Level Lo 20.5% > 20.5% +/- 5% (Normal) +/- 5% (Normal) Monthly Surveillance Setpoint

+/- 14% (Accident) +/- 14% (Accident) and Tech Spec Setpoint changed to 35% and > 35% for EPU RPS RCS Low Flow _ 95.4% Design 3.5% 3.5% (Normal)

Flow 7.5% (Accident)

SIAS/CIS Cont. Press Hi 3.41 psig  :< 3.5 psig +/- 1.65 psi +/- 1.65 psi CSAS Cont. Press Hi-Hi 5.31 psig < 5.4 psig +/- 1.65 psi +/- 1.65 psi SIAS PZR Press Lo 1740 psia > 1736 psia +/- 45 psi (Normal) +/- 45 psi (Normal)

+/- 90 psi (Accident) +/- 90 psi (Accident)

MSIS S/G Press Lo 600 psia > 600 psia +/- 40 psi (Normal) +/- 40 psi (Normal)

+/- 80 psi (Accident) +/- 80 psi (Accident)

RAS RWT Level Lo 5.67 feet 5.67 feet +/- 6 inches +/- 6 inches AFAS S/G Level Lo 19.5% > 19.0% +/- 5% (Normal) +/- 5% (Normal)

+ 14% (Accident) +/- 14% (Accident)

AFAS S/G Press DP Hi 270 psid < 275 psid Not specified +/- 60 psi (Normal)

+/- 115 psi (Accident)

AFAS FW Press DP Hi 142.5 psid <150.0 psid Not specified < 245 psid (setpoint) EPU setpoint requirement based on

+/- 85 psi (Normal) uncertainty AFAS logic time delay 210 sec 120 sec 120 sec (minimum actuation time)

PORV Open Pressure N/A 2370 psia (nominal) 2370 psia (nominal) For non-LTOP conditions, (setpoint) PORVs operate on RPS PZR Press Hi Main Steam Safety RV -N/A 1000 psia (nominal) +1 -3% (Bank 1&2 +/- 3% (Bank I tolerance) 1040 psia (nominal) tolerance) +2%, -3% (Bank 2 tol.)

3% (accumulation) 3% (accumulation)

Attachment I to L-2010-278 Page 34 of 59 PZR Safety RV N/A 2500 psia (nominal) +/- 2% (tolerance) +/- 3% (tolerance) 13%(accumulation) 3% (accumulation)

Note: When revised, Safety Analysis limits are set equal to the Tech Spec setpoint plus or minus the defined uncertainty.

Attachment I to L-2010-278 Page 35 of 59 Table 6 REACTOR COOLANT SYSTEM GEOMETRY Top Bottom Flow Path Elevation Elevation Minimum 2Flow Volume Area ift )

Comoonent Lenath Mft Hot Leg 14.53 2.38 -1.75 9.62 139.81 Suction Leg 22.83 1.04 -7.25 4.91 112.07 Discharge Leg 1.25 -1.25 Parallel 16.39 4.91 80.46 Non-parallel 16.42 1.25 -1.25 4.91 80.52 Reactor Coolant Pump 22.81 1.25 -1.79 4.91M 112 Pressurizer 47.20 10.83 1500 Liquid level 30.66 10.83 50.07(') 800 Surge Line 54.51 10.83 1.75 0.56 29.30 Steam Generator Inlet nozzle (ea) 2.23 2.24 0.95(*) 9.62 21.77 Inlet plenum 4.64 6.91 0.36 61.04 342.94 Tubes (active and 56.81 37.65 6.91 0.0024(c) 1247.71 passive)

Outlet plenum 5.50 6.91 0.36 61.04 337.95 Outlet nozzle (ea) 1.72 1.39 0.16(ol 4.91 8.58 Reactor Vessel Inlet nozzles 3.6 1.5 -1.5 4.9 78 Downcomer 20.9 1.5 -20.9 30.3 674 Lower plenum 6.4(b') -20.9 -27.0 43.7 702 Lower support 3.5 -17.4 -20.9 28.0 473 structure and inactive core Active core 11.4 -6.0 -17.4 54.8 669 Upper inactive 1.5 -4.5 -6.0 47.1 85 core 2.0 Outlet plenum 11.059) -4.5 23.45 524 CEA shroud 12.21g) 9.8 2.0 430 UGS annulus, outside 4.5 6.5 2.0 122 CEA shroud Top Head -- 13.0 6.5 753 Outlet nozzles 4.1 2.0 -2.0 9.62 105 4.4-47 Amendment No. 18 (01/08)

Table 6 - Continuation

Attachment I to L-2010-278 Page 36 of 59 TABLE 4.4-8 (Cont'd)

Notes.

(a) For the cylinder (b) Represents a geometrical rather than an actual flow path length (c) Flow path area per tube (d) Reactor vessel nozzle centerline is the reference elevation; it has an elevation of 0.0 ft.

(e) Nozzle centerline (f) RCP outlet (g) Approximate flow path length 44-48 Table 6 - Continuation

Attachment I to L-2010-278 Page 37 of 59 Elevation Above SG Secondary Side 3

SG Riser/Wrapper 3 SG Total (ft3)

Downcomer (ft ) (ft )

Tubesheet 0in (secondary face of tubesheet) 265.5 in (start of lower edge 251.5 1465.5 1717.0 of shell cone) 270.5 in (start of lower edge 258.3 1493.3 1751.6 of wrapper cone) 294.2 inc (end of wrapper 303.3 1669.6 1972.9 cone) 329.5 in (end of shell cone) 497.1 2053.6 2550.7 361.6 inc (inside edge of 789.9 2501.0 3290.9 wrapper roof) 449.7 inc (top of cyclones) 2413.8 2889.2 5303.0 585.0 in (interior face of N/A N/A 7984.8 venture in steam nozzle)

Attachment I to L-2010-278 Page 38 of 59 Table 7 Reactor Coolant.Pump Homologous Curves VALPHA HAN HVN BAN BVN VALPHA HAD HVD BAD BVD 0.0 1.5800 -1.4200 0.7700 -1.4500 0.0 1.5800 1.2200 0.7700 1.3150 0.1 1.5000 -1.2150 0.8020 -1.1120 -0.1 1.6600 1.2850 0.8100 1.3800 0.2 1.4200 -1.0820 0.8450 -0.8720 -0.2 1.7600 1.3450 0.8800 1.4500 0.3 1.3700 -0,9120 0.8660 -0.6480 -0.3 1.8700 1.4400 0.9800 1.5100 0.4 1.3300 -0.7280 0.8850 -0.4420 -0.4 2.0000 1.5500 1.0900 1.5800 0.5 1.2950 -0.4940 0.9100 -0.2700 -0.5 2.1300 1.7200 1.2350 1.6400 0.6 1.2700 0.0000 0.9300 0.2600 -0.6 2.3000 1.9300 1.3900 1.7200 0.7 1.2400 0.2080 0.9530 0.4300 -0.7 2.4700 2.1800 1.5800 1.8300 0.8 1.1820 0.4350 0.9730 0.6130 -0.8 2.7000 2.4900 1.7850 1.9600 0.9 1.1050 0.7080 0.9890 0.8000 -0,9 2.9300 2.8100 2.0400 2.1200 1.0 1.0000 1.0000 1.0000 1.0000 -1.00 3.1500 3.1500 2.2900 2.2900 VALPHA HAT HVT BAT BVT VALPHA HAR HVR BAR BVR 0.0 0.4330 1.2200 -1.4400 1.3150 0.0 0.4330 -1.4200 -1.4400 -1.4500 0.1 0.4740 1.1820 -0.9200 1.2450 -0.1 0.3430 -1.7150 -1.6600 -1.8500 0.2 0.5020 1.1400 -0.6300 1.1800 -0.2 0.0112 -1.9600 -1.9100 -2.2000 0.3 0.5120 1.0850 -0.4200 1.1100 -0.3 -0.2460 -2.1500 -2.1900 -2.5200 0.4 0.5240 1.0450 -0.2500 1.0420 -0.4 -0.5130 -2.3400 -2.4900 -2.8500 0.5 0.5460 1.0000 -0.1000 0.9750 -0.5 -0.8300 -2.5200 -2.8300 -3.1500 0.6 0.5830 0.9500 0.0200 0.9050 -0.6 -1.0350 -2.6900 -3.2400 -3.4900 0.7 0.6410 0.9000 0.1300 0.8170 -0.7 -1.6000 -2.8100 -3.6000 -3.8400 0.8 0.7120 0.8700 0.2510 0.7280 -0.8 -2.0500 -2.9300 -4.0500 -4.2300 0.9 0.8000 0.8650 0.3900 0.6280 -0.9 -2.5500 -3.0100 -4.5400 -4.6100 1.0 0.9080 0.9080 0.5620 0.5620 -1.0 -3.1000 -3.1000 -5.0300 -5.0300 Note: According to WEC, the definition of the column headings can be found in the reactor coolant pump model input description in the CEFLASH-4A topical report.

Attachment I to L-2010-278 Page 39 of 59 Table 8 Minimum HPSI/LPSI Flow Minimum HPSI/LPSI Flow LPSI Pump Failure LPSI Pump Failure (LPSI B Off_ Other Piimn* Onb (LPSI B Off, Other Pumps On)

(L .. S .. Of . Other. Pumps.. .. I RCS Pressure Flow to Loops Al, RCS Pressure Flow to Loops B1, B2 (psia) A2 (gpm) (psia) (gpm)

(Flow to each Loop) (Flow to each Loop) 1063.1 0.0 1063.1 0.0 1062.6 21.3 1062.6 21.3 1062.0 42.5 1062.0 42.5 1045.8 63.8 1045.8 63.8 1009.7 85.0 1009.7 85.0 954.3 106.3 954.3 106.3 883.3 127.5 883.3 127.5 800.7 148.8 800.7 148.8 708.4 170.0 708.4 170.0 603.7 191.3 603.7 191.3 476.6 212.5 476.6 212.5 307.6 233.8 307.6 233.8 148.1 248.6 148.1 248.6 125.5 250.4 125.5 250.4 125.1 290.5 117.9 251.0 124.2 330.5 94.3 252.8 121.6 410.8 59.9 255.4 117.9 491.0 12.4 258.7 113.1 571.4 0.0 259.5 107.6 651.8 101.3 732.3 94.3 812.8 86.7 893.4 78.4 974.0 69.5 1054.7 59.9 1135.4 49.5 1216.1 38.2 1296.9 25.9 1377.8 12.4 1458.7 0.0 1526.7

Attachment 1 to L-2010-278 Page 40 of 59 Table 9 Minimum HPSI/LPSI Flow Minimum HPSI/LPSI Flow Loss of EDG Failure Loss of EDG Failure (HPSI B. LPSI B Off. Other Pumps On) (HPSI B, LPSI B Off, Other Pumps On)

RCS Pressure Flow to Loops Al, RCS Pressure Flow to Loops B1, (psia) A2 (gpm) (psia) B2 (gpm)

(Flow to each Loop) (Flow to each Loop) 1063.1 0.0 1063.1 0.0 1062.6 10.6 1062.6 10.6 1062.0 21.3 1062.0 21.3 1045.8 31.9 1045.8 31.9 1009.7 42.5 1009.7 42.5 954.3 53.1 954.3 53.1 883.3 63.8 883.3 63.8 800.7 74.4 800.7 74.4 708.4 85.0 708.4 85.0 603.7 95.6 603.7 95.6 476.6 106.3 476.6 106.3 307.6 116.9 307.6 116.9 148.1 124.3 148.1 124.3 125.5 125.2 125.5 125.2 125.1 165.2 117.9 125.5 124.2 205.3 94.3 126.4 121.6 285.4 59.9 127.7 117.9 365.5 12.4 129.3 113.1 445.7 0.0 129.8 107.6 525.9 101.3 606.2 94.3 686.4 86.7 766.7 78.4 847.0 69.5 927.3 59.9 1007.7 49.5 1088.1 38.2 1168.5 25.9 1248.9 12.4 1329.3 0.0 1397.0

Attachment I to L-2010-278 Page 41 of 59 Table 10 Maximum HPSI/LPSI Flow Maximum HPSI Flow (1 HPSI On, all others Off)

No ECCS Failure (All Pumps On) RCS Pressure Flow to Loops Al, (psia) A2, B1, B2 (gpm)

Flow to Loops RPrssue Al, A2, B1, B2 (gpm) (Flow to each Loop)

(psia) (Flow to each Loop) 1454.8 0 1451.8 14.4 1454.8 0.0 1434.7 28.8 1451.8 28.8 1397.7 43.1 1434.7 57.5 1342.1 57.5 1397.7 86.3 1268.1 71.9 1342.1 115.0 1175.4 86.3 1268.1 143.8 1063.1 100.6 1175.4 172.5 929.8 115.0 1063.1 201.3 773.6 129.4 929.8 230.0 592.3 143.8 773.6 258.8 383.3 158.1 592.3 287.5 207.8 168.8 383.3 316.3 198.9 169.4 234.9 337.7 180.3 170.4 233.7 392.8 155.0 171.9 232.2 448.0 119.8 173.9 228.9 558.3 67.2 176.8 224.9 668.7 0 180.3 220.3 779.2 215.3 889.7 209.8 1000.3 203.8 1110.9 197.4 1221.6 190.5 1332.2 183.2 1443.0 175.2 1553.8 166.5 1664.6 157.1 1775.6 146.8 1886.6 135.4 1997.7 122.9 2108.9 108.9 2220.3 93.4 2331.8 76.0 2443.5 56.5 2555.4 34.8 2667.5 10.4 2779.7 0.0 2824.0

Attachment I to L-2010-278 Page 42 of 59 Table 11 Minimum HPSI Only Delivery for SBLOCA RCS Pressure Flow Rate to Loop Flow Rate to Loop Total Flow (psia) Al or A2 (gpm) B1 or B2 (gpm) Delivered (gpm) 1212 0.0 0.0 0 1205 15.9 15.9 63.6 1198 19.2 19.2 76.8 1177 27.4 27.4 109.6 1104 48.6 48.6 194.4 1035 61.1 61.1 244.4 943 72.6 72.6 290.4 829 85.1 85.1 340.4 699 98.3 98.3 393.2 551 112.2 112.2 448.8 393 125.1 125.1 500.4 217 137.9 137.9 551.6 0 152.1 152.1 608.4 Table 12

Attachment 1 to L-2010-278 Page 43 of 59 Component Data Required Component ! Flow Diagram Component Information Pressurizer PORVs V 1474 2998-G-078 Sheet 108 Rev. 5 2998-18810 Rev. 3 V 1475 1 Pressurizer Safety Valves V1200 2998-G-078 Sheet 109 R18 2998-19690 Rev. 1 VI201 2998-19691 Rev. I V1202 Main Steam Safety Valves V8201 2998-G-079, Sheet 1, Rev. 41 2998-2381, Rev 11 V8202 V8203 V8204 V8205 V8206 V8207 V8208 V8209 V8210 V8211 V8212 V8213 V8214 V8215 V8216 Atmospheric Dump Valves MV-08-18A 2998-G-079, Sheet 1, Rev. 41 2998-11458 Rev. 10 MV-08-19A MV-08-18B MV-08-19B Turbine Control Valves (Governor)

FCV-08-644 2998-G-079 Sheet 2, Rev.35 2998-2184 Rev. 10 FCV-08-645 2998-31, Rev 17 FCV-08-646 FCV-08-647 Turbine By-Pass Valves PCV- 8801 2998-G-079 Sheet 2 Rev. 35 2998-625 Rev. 11 2998-4091 Rev. 2 2998-4092 Rev. I Turbine Stop Valves (Throttle)

FCV-08-640 2998-G-079 Sheet 2, Rev.35 2998-2184 Rev. 10 FCV-08-641 2998-31, Rev 17 FCV-08-642 FCV-08-643 Main Feed Isolation Valves HCV-09-IA I 2998-G-080 Sheet 2A Rev. 43 12998-9486 Rev. 4

Attachment I to L-2010-278 Page 44 of 59 HCV-09-1 B HCV-09-2A HCV-09-2B 2998-9487 Rev. 4 Main Steam Isolation Valves HCV-08-IA 2998-G-079 Sheet 1, Rev. 41 2998-1011 Rev. 3 Sheet 1/9 HCV-08-1 B 1 1 2998-1012 Rev. 0 Sheet 2/9 Miscellaneous Components V09107 2998-G-080 Sheet 2B Rev.36 2998-20110 Rev. 1 V09108 2998-741 Rev. 3 SE-09-2 2998-13008 Rev. 3 2998-13006 Rev. 1 2998-13009 Rev. 2 MV-09-9 2998-19745 Rev. 2 2998-1872 Rev. 6 2998-5616 Rev. 0 V09119 2998-3033 Rev. 4 V09120 2998-742 Rev. 2 V09123 2998-20110 Rev. 1 V09124 2998-741 Rev. 3 SE-09-3 2998-13008 Rev. 3 2998-13006 Rev. l 2998-13009 Rev. 2 MV-09-10 2998-19745 Rev. 2 2998-1872 Rev. 6 2998-5617 Rev. 0 V09135 2998-3033 Rev. 4 V09136 2998-742 Rev. 2 V09139 2998-752 Rev. 5 V09140 2998-751 Rev. 2 SE-09-4 2998-13007 Rev. 1 2998-13008 Rev.3 2998-13009 Rev. 2 MV-09-11 2998-19745 Rev. 2 2998-1871 Rev. 7 2998-5617 Rev. 0 V09151 2998-3033 Rev. 4 V09152 2998-742 Rev. 2 SE-09-5 2998-13007 Rev. 1 2998-13008 Rev.3 2998-13009 Rev. 2 MV-09-12 2998-19745 Rev. 2 2998-1871 Rev. 7 2998-5616 Rev. 0 V09157 2998-3033 Rev. 4 V09158 2998-742 Rev. 2 V3225 2998-G-078 Sheet 132 Rev. 9 2998-19174 Rev. 2 2998-4353 Rev. 5 V3624 2998-784 Rev. 6 V3258 2998-655 Rev. 1 V3227 2998-658 Rev. I

Attachment I to L-2010-278 Page 45 of 59 V3215 2998-19174 Rev. 2 2998-4353 Rev. 5 V3614 2998-784 Rev. 6 V3259 2998-655 Rev. 6 V3217 2998-658 Rev. I V3245 2998-4353 Rev. 5 2998-19174 Rev. 2 V3644 2998-784 Rev. 6 V3261 2998-655 Rev. I V3247 2998-658 Rev, I V3235 2998-19174 Rev. 2 2998-4353 Rev 5 V3634 2998-784 Rev. 6 V3260 2998-655 Rev. I V3237 2998-658 Rev. 1 FE-3312 2998-G-078 Sheet 131 Rev. 20 HCV-3615 2998-1219 Rev. 9 V3114 2998-655 Rev. 1 V3805 2998-2076 Rev. 19 FE-3311 V3113 2998-19800 Rev. 0 HCV-3616 2998-20356 Rev. 0 2998-20355 Rev. 0 HCV-3617 2998-20356 Rev. 0 2998-20355 Rev. 0 FE-3322 HCV-3625 2998-1219 Rev. 9 V3124 2998-655 Rev. I HCV-3626 2998-1218 Rev. 9 FE-3321 V3766 8770-14084 Rev. 1 8770-14099 Rev. 1 HCV-3627 2998-1218 Rev. 9 FE-3332 HCV-3635 2998-1219 Rev. 9 V3134 2998-655 Rev. I FE-3331 V3133 2998-1530 Rev. 5 HCV-3636 2998-1218 Rev. 9 HCV-3637 2998-1218 Rev. 9 FE-3342 V3144 2998-655 Rev. I FE-3341 V3143 2998-20097 Rev. 0 HCV-3646 2998-1218 Rev. 9 HCV-3647 2998-1218 Rev. 9 V3106 2998-G-078 Sheet 130B Rev. 28 2998-657 Rev. 2 V3206 2998-1024 Rev. 3 FCV-3306 2998-4815 Rev. 7

Attachment 1 to L-2010-278 Page 46 of 59 2998-4816 Rev. 6 FE-3306 V3107 2998-657 Rev. 2 V3207 2998-1024 Rev. 3 FCV-3301 2998-4815 Rev. 7 2998-4816 rev. 6 FE-3301 SO-03-19 V3427 2998-679 Rev. 7 V3656 2998-781 Rev.3 SO-03-20 2998-G-078 Sheet 130A Rev. 19 V3414 2998-679 Rev. 7 V3654 2998-780 Rev.3 V2674 2998-G-078 Sheet 121A Rev. 31 2998-16238 Rev. 0 V2501 2998-3386 Rev. 4 V2118 2998-1036 Rev. 1 V2322 2998-G-078 Sheet 122 Rev. 25 2998-1033 Rev. 0 SS-02-1A 2998-7437 Rev. 3 Suction 2998-9068 Rev. 5 Stabilizer for 2998-9067 Rev. 4 CHG PP 2A Pulsation 2998-9070 Rev. 2 Damper for 2998-9069 Rev. 2 CHG PP 2A V2169 8770-14084 Rev. 1 8770-14099 Rev. 1 V2336 8770-14345 Rev. 1 V2319 2998-1033 Rev. 0 SS-02-1B 2998-7437 Rev. 3 Suction 2998-9068 Rev. 5 Stabilizer for 2998-9067 Rev. 4 CHG PP 2B Pulsation 2998-9070 Rev. 2 Damper 2998-9069 Rev. 2 CHG PP 2B V2168 8770-14084 Rev. ]

8770-14099 Rev. l V2464 8770-12770 Rev. 1 2998-17048 Rev. 0 V2316 2998-1033 Rev. 0 SS-02-IC 2998-7437 Rev. 3 Suction 2998-9068 Rev. 5 Stabilizer for 2998-9067 Rev. 4 CHG PP 2C Pulsation 2998-9070 Rev. 2 Damper for 2998-9069 Rev. 2 CHG PP 2C V2167 8770-14084 Rev. 1 8770-14099 Rev. 1 V2339 2998-1031 Rev. 5 FE-2212

Attachment I to L-2010-278 Page 47 of 59 V2429 2998-560 Rev. 2 V2523 2998-2786 Rev. 5 V2462 8770-14084 Rev. l 8770-14099 Rev. 1 V2535 2998-560 Rev. 2 V2598 2998-15232 Rev. 3 V2485 2998-3487 Rev. 2 V2433 2998-1749 Rev. 3 SE-02-2 2998-18973 Rev. 0 2998-18974 Rev. 0 2998-19677 Rev. 0 2998-19678 Rev. 0 V2484 2998-3487 Rev. 2 V2432 2998-1749 Rev. 3 SE-02-1 2998-18973 Rev. 0 2998-18974 Rev. 0 2998-19677 Rev. 0 2998-19678 Rev. 0 V2593 2998-1009 Rev. 2 V2515 2998-548 Rev. 14 V2516 2998-548 Rev. 14 V2522 2998-G-078 Sheet 120 Rev. 17 2998-2785 Rev. 5 V2341 2998-560 Rev. 2 2998-17024 Rev. 0 V2342 2998-560 Rev. 2 2998-17023 Rev. 0 (Letdown 2998-1611 Rev. ]

Heat Exchanger)

LTDN HT EXCH V2347 2998-557 Rev. 3 2998-17023 Rev, 0 PCV-2201Q 2998-2586 Rev. 6 V2349 2998-4013 Rev. 0 2998-17023 Rev. 0 FE-2202 V2358 2998-1037 Rev. ]

2998-17025 Rev. 0 (Purification 2998-19775 Rev. 0 Filter) 2998-6065 Rev. 3 Purif Filter 2A 2998-16332 Rev. 1 2998-5498 Rev. 4 V2360 2998-1037 Rev. 1 2998-17025 Rev. 0 V2520 2998-2584 Rev. 6 V2359 2998-590 Rev. 5 2998-17042 Rev. 1 V2370 2998-1029 Rev. 2

Attachment I to L-2010-278 Page 48 of 59 (Purification 2998-3642 Rev. 2 Ion Exchanger)

Purif IX 2A V2378 2998-1037 Rev. 1 2998-17025 Rev. 0 V2382 2998-1037 Rev. 1 2998-17025 Rev. 0 V2395 2998-17025 Rev. 0 2998-1037 Rev. 1 (Letdown 2998-5064 Rev. 1 Strainer)

S2900 V2415 2998-17025 Rev. 0 2998-1037 Rev. 1 V2418 2998-17025 Rev. 0 2998-1037 Rev. 1 V2452 2998-17025 Rev. 0 2998-1037 Rev. I (Purification 2998-19775 Rev. 0 Filter) 2998-5498 Rev. 4 Purif Filter 2B 2998-6065 Rev. 3 2998-16332 Rev. ]

FE-8011 2998-G-079 Sheet 1, Rev. 41 2998-1420 Rev.6 FE-8021 2998-1421 Rev. 4 2998-2646 Rev. 1 V 1442 2998-G-078 Sheet 109 Rev. 18 2998-3066 Rev. 5 2998-17056 Rev. 0 V 1249 2998-187 Rev. 3 PCV-II OOF 2998-546 Rev. 13 Vi1444 2998-3066 Rev. 5 2998-17057 Rev. 0 V 1477 2998-G-078 Sheet 108 Rev. 5 2998-13278 Rev. 3 V 1479 2998-13277 Rev. 0 V 1476 2998-13278 Rev. 3 V1478 2998-13277 Rev, 0 V 1443 2998-G-078 Sheet 109 Rev. 18 2998-3066 Rev. 5 2998-17057 Rev. 0 PCV-1IOOE 2998-546 Rev. 13 V1248 2998-187 Rev. 3 V 1441 2998-3066 Rev. 5 2998-17055 Rev. 0 FE-01-2 2998-G-078 Sheet 108 Rev. 5 2998-13912 Rev. 1 FE-01-1 2998-13912 Rev. 1 FE-09-2A 2998-G-080 Sheet 2B Rev.36 2998-2595 Rev. 2 FE-09-2B 2998-2595 Rev. 2 FE-09-2C 2998-2595 Rev. 2 MV-08-14 2998-G-079 Sheet I Rev. 41 2998-10622 Rev. 5 MV-08-15 2998-10622 Rev. 5 MV-08-16 2998-10621 Rev. 6

Attachment 1 to L-2010-278 Page 49 of 59 MV-08-17 2998-10621 Rev. 6 V08359 2998-G-079 Sheet 2 Rev. 35 2998-3012 Rev. 8 V08360 2998-3012 Rev. 8 V09294 2998-G-080 Sheet 2A Rev 43 2998-2143 Rev. 5 V09252 2998-2143 Rev. 5

Attachment I to L-2010-278 Page 50 of 59 Table 13 Primary Loop Pressure Drop Distribution LBLOCA SBLOCA Geometry AP Geometry AP Geometry AP Geometry AP Station Friction AP Forward Flow Reverse Flow Friction AP Forward Flow Reverse Flow

_Valus "

S.PrE.-.EPU> (psi)*si*,(*i**(psits.jj 9(ýp"i,) .(psi)j Reactor Vessel 4.90 27.84 38.42 5.14 28.93 39.90 Outlet RV to Inlet SG 0.30 0.66 0.66 0.28 0.64 0.64 Inlet SG to SG outlet 26.62 10.22 8.90 26.06 10.00 8.71 Outlet SG to Inlet RCP 0.58 2.73 2.73 0.56 2.65 2.65 RCPs ---- 75.16 84.42 ---- 75.55 85.23 RCP outlet to RV inlet 0.42 0.89 0.89 0.42 0.87 0.87 Va e j E U (psiy (psi ).< (psi). . .; I ',,psi {(i*i (psi) .

Reactor Vessel 6.13 34.82 48.09 6.41 36.13 49.84 Outlet RV to Inlet SG 0.38 0.83 0.83 0.36 0.80 0.80 Inlet SG to SG outlet 33.34 12.81 11.17 39.24 11.65 15.17 Outlet SG to Inlet RCP 0.72 3.42 3.42 0.70 3.31 3.31 RCP ---- 94.09 105.72 ---- 100.21 117.44 RCP outlet to RV inlet 0.52 1.12 1.12 0.52 1.09 1.09 Note: Pressure drops include uncertainties of +10% friction and +20% geometry.

Table 13 - CONT. - Associated Conditions LBLOCA SBLOCA

.Pre-IEP'U Values Power Level - MWTh 2754 2754 Vessel Flow Rate - Ibm/sec 35,796 34,868 Core Flow Rate - Ibm/sec 34,471 34,868 Bypass Flow - % 3.7 3.7

',EPtIJValues_____

Power Level - MWTh 3030 3030 Vessel Flow Rate - Ibm/sec 40,072 38,884 Core Flow Rate - Ibm/sec 38,589 38,884 Bypass Flow- % 4.2 4.2

Attachment 1 to L-2010-278 Page 51 of 59 Table 14 Heat Balance Information

% EPU Feedwater Steam Flow Feedwater Turbine Inlet Turbine Inlet Power Flow lbm/hr (2 SG) Temperature, F Valve, psia Pressure, psia Ibm/hr (2 SG 100 13,345,890 13,247,580 436.2 854.6 803.3 90 11,872,120 11,773,810 426.9 860.7 711.0 75 9,696,551 9,598,249 410.1 870.8 576.4 50 6,223,793 6,125,495 374.6 879.3 361.7 25 2,994,037 2,895,675 322.7 881.8 190.0 Table 15 RCS Pressure Boundary Material Property Data Material Density Specific Thermal Emissivity Comment (lbm/ft3) Heat Conductivity vs Temp (Btu/Ibm-F) (Btu/hr-ft-F)

Carbon 483.8* 0.129* 22.92* 0.78-0.82 *SA-516 Gr 70 Steel @130-530 **smooth oxidized C** iron Stainless 499.4* 0.13* 10.44* 0.57-0.66 *304/304L SS Steel @230-870 **316 SS repeated C** heating Inconel 528.8 0.106 8.58 0.85-0.98 600 @480-1090 C Inconel 511.5 0.107 7.75 0.85-0.98 Emissivity assumed 690 @480-1090 C same as Inconel 600

Attachment I to L-2010-278 Page 52 of 59 FIGURE 16 PRESSURIZER PRESSURE CONTROL PROGRAM Pressure (psla) 2500 Safety Valves Open (2500 psia) 2400 PORVs Open (2370 psia) 2370 High Pressure Trip (2370 psia) 2340 High Pressure Alarm (2340 psia) 2325 Spray Valves Fully Open (Above 2325 psia) 2300 Spray Valves Fully Closed (Below 2275 psia) 2275 Proportional Heaters "OFF" (2275 psia) 2250 Control Setpoint (2250 psia) 2225 / Proportional Heaters "ON" (2225 psia) 2220 2200

'ifI Backup Heaters "OFF" Above 2220 psia Backup Heaters "ON" Below 2200 psia 2100 Low Pressure Alarm (2100 psia)

Net Heat In Net Heat Out - (Not To Scale)

Attachment 1 to L-2010-278 Page 53 of 59 FIGURE 17 PRESSURIZER LEVEL ERROR CONTROL Level Error From Item Description Nominal

(% Span) 1 First Backup Charging Pump Start Signal - 2.5 2 First Backup Charging Pump Stop Signal - 1.1 3 Backup Signal to Start All Charging Pumps -5 4 Backup Signal to Stop Backup Charging +4 Pumps 5 High Level Error Alarm +5 6 Low Level Error Alarm -5 7 All Pressurizer Heaters Energized +4 8 Minimum Letdown - 1.1 9 Maximum Letdown + 12.5

Attachment I to L-2010-278 Page 54 of 59 Figure 18 - LTOP PORV ACTUATION SCHEMATIC S"PORV Opens V-1474 (P-1103 and P-1104)

V-1475 (P-1105 and P-1106)

V-1474 V- 1475 (PIMaintl2-SMI-0i,03AIFig,3lPev,1,tif)

Attachment I to L-2010-278 Page 55 of 59 Figure 19 - Unit 2 SBCS Simplified Block Diagram See Next Page

Attachment 1 to L-2010-278 Page 56 of 59 116~

Unit 2 SBCS Big Note . m,.,.

.IF r..0 0 1C-NI01 A 3 b..I*

wc21"k I

IXT I T 241 V uvc i

---

How. hsw A0*m O-Tsw.%W At"L Lpmn.Swat - PCVJNWi IIIIIIIIIII NL2stŽ. -20.J

ý&m,4tý& Uj s.- t1! - W I 2~o~WU~u..rw cs IVLD I: 200.2 K'S 0"ON" (*a CU 2 K (Ps 36rA@PAWS IY4ft 14 J. 5*sww Teo1S.Idus ". VWIKs ANYin iLSi .e CIS'Wp l ,..... *r- ...................... T-TF*

, ii

Attachment I to L-2010-278 Page 57 of 59 Table 20 - Unit 2 Essential Valve Characteristics Component Full Open Flow Forward/ Open/Close Rate Min Flow at Rated Open/Close Logic Area Backward CV Conditions Pressurizer 0.0202 Ft 2 N/A I sec open (this 398,000 Ibm/hr steam PORVs are actuated on high PZR pressure using PORVs This is an effective value is for non- per valve 2/4 logic. The nominal (TS) setpoint is <2370 area, back LTOP evaluations) psia. This setpoint will not change for EPU.

calculated from the See Table 5 for additional information.

identified flow rate. PORVs are also actuated by the LTOP logic.

The PORV logic and existing setpoints is shown in Figure 18.

Pressurizer Safety 0.01 Fe N/A 0.05 sec open 212,182 Ibm/hr steam Spring loaded valve that opens at nominal set Valves This is an effective per valve @ setpressure pressure, achieves full open position at 103% of area, back + 3% accumulation setpressure; recloses at a pressure of 99% to calculated from the 85% of setpressure; see Table 5 for additional identified flow rate. information Main Steam 0.1054 Fe for the N/A 1.0 sec open 744,210 Ibm/hr per Spring loaded valve that opens at nominal set Safety Valves 1000 psia valves. valve @ 1000 psia pressure, full open at 103% of setpressure; see This is an effective 774,000 lbm/hr per Table 5 for additional information area, back valve @1040 psia calculated from the identified flow rate; 0.1052 Ft 2 for the 1040 psia valves.

This is an effective area, back calculated from the identified flow rate.

Atmospheric Open / Close (sec)

Dump Valves

Attachment 1 to L-2010-278 Page 58 of 59 Component Full Open Flow Forward/ Open/Close Rate Min Flow at Rated Open/Close Logic Area Backward CV Conditions MV-08-18A 0.0396 sq ft per 553 37.2-50.3/35.5- 275,000 Ibm/hr @985 ADV control is via pressure indicating valve, effective 47.9 psia; 54,000 Ibm/hr @ controllers PIC-08-IA, PIC-08-1B, PIC-08-3A, area back 55 psia (design PIC-08-3B. In the Manual mode of operation, MV-08-19A calculated from 35.5-47.9/35.8- capacity) the controller is used to directly set valve identified flow rate. 48.3 position. In the Automatic mode of operation, valve position is varied to maintain the desired MV-08-18B 36.9-49.9/35.6- pressure. PSL2 ADV controllers are maintained 48.1 in Manual during full power plant operation.

This normal control mode is based on PSL-2 TS MV-08-19B 37.2-50.2/36.6- LCO 3.7.1.7. ADV control will not change for 49.6 EPU.

Turbine Control Data N/A 12,222,940 lbm/hr at Valves close on Turbine Trip. Trip logic Valves (Governor) 1256.6 in2 for 4 unavailable; EPU for total of four includes: Reactor Trip, High-High SG Level, valves was not used in valves Overspeed, Generator Lockout and various design equipment protection functions.

Assumed the same Turbine governor valves are currently operated as Unit 1. in Sequential Valve mode with valve position controlled by the DEH computer. Various control strategies (feedback loops) are available including: Impulse Pressure, Megawatt Control and Speed Control.

As part of EPU main turbine upgrades, the governor valves will be operated in Single Valve mode.

Turbine By-Pass Not available due An upgraded valve An upgraded system Steam Bypass Control System (SBCS) has both Valves to planned valve open time in the capacity of modulation and quick open control modes. A capacity upgrade quick open mode approximately 6.9E6 control block diagram, including setpoints where of approximately 2 Ibm/hr. is planned as applicable, is shown in Figure 19.

sec is planned as part of EPU Minor changes to the SBCS logic are planned as part of EPU part of EPU. QO load rejection setpoint will be reduced to -15%. Valve demand curves will be revised to reflect new valve capacities and valve trim. Transition from QO to modulation mode will be enhanced.

Attachment I to L-2010-278 Page 59 of 59 Component Full Open Flow Forward/ Open/Close Rate Min Flow at Rated Open/Close Logic Area Backward CV Conditions Turbine Stop Data 0.26 sec (close) 12,222,940 lbm/hr at Valves close on Turbine Trip. Trip logic Valves (Throttle) 2375.8 in2 for 4 unavailable; EPU for total of four includes: Reactor Trip, High-High SG Level, valves was not used in valves Overspeed, Generator Lockout and various design equipment protection functions.

Assumed the same Turbine stop valves are normally full open as Unit I. during power operation. The stop valves are opened in a DEH speed control mode during initial turbine startup (to 1700 RPM).

Main Feed 1.268 Fte 13,750 Close stroke time 13,345,890 lbm/hr MFIVs close on either AFAS or MSIS. See Isolation Valves (Estimate based on 1.0 to 2.4 sec. 100% Flow Table 5 for AFAS/MSIS actuation signals and full flow of 18" associated setpoints.

Sch 120 pipe)

Main Steam 4.665 sq ft N/A After MSIS signal 13,247,580 ibm/hr MSIVs close on MSIS. See Table 5 for MSIS Isolation Valves (estimate based on is generated. 6.75 100% Flow actuation signals and associated setpoints.

29.245" diameter sec- value includes port size) sensor response time of 1.15 secs and valve closure time of 5.6 secs.

Attachment 2 to L-2010-278 ATTACHMENT 2 CORE PARAMETERS Following 28 pages

Attachment 2 L-2010-278 ST. LUCIE UNIT 2, Representative First Uprate Cycle REFERENCE CORE LOADING PATTERN Y X W V T S R P N M L K J H G F E D C B A X40 X31 X25 X07 I I + + 21 S-6 P-iS G-5 J-ii I I X43 X20 U66 Y83 Y53 Y86 U53 XI7 X39 i i - 20 V-13 G-13 L-19 FEED FEED FEED R-15 G-9 J-4 X2

[

Y88 Y59 Y03 I X56 4 [ [

T03 X63 Y15 Y64 Y94 X21 f-- f 19 4FEED FEED PEED S-191 F-lI W-16 FEED FEED FEED E-4

-~ ~ ~ ~

X10IO X48 Y66 X66 Y42 X54 I Y44 X51 Y45 X68 Y75 X47 X1s i -1 18 D-i7 D-4 FEED R-19I FEED IJ-20 FEED N-20 FEED G-19 FEED V-4 V-17 X33 Y95 Y76 U49 Y18 U06 Y28 U29 Y29 U05 Y02 U63 Y58 Y82 X36 17 D-i3 FEED FEED F-9 FEED V-16 FEED X-5 FEED D-16 FEED N-6 FEED FEED J-18 X22 Y79 X69 Y37 X03 Y08 U28 Y23 U15 Y24 X05 Y20 X70 Y60 X14 -- 16 J-15 FEED W-iS FEED L-2 FEED H-I FEED P-I FEED X-II FEED C-i5 FEED J-7 U61 Y21 Y50 U0B Y14 U55 Y70 U30 Y71 U54 Y17 U03 Y51 Y0i 062 X04 R-7 PEEDSFEED S-18 FEED T-lI FEED B-5 FEED L-17 FEED F-18 FEED FEEDIC-il X(37

- 14 L-13 Y96 X53 X59 Y27 U13 Y67 Y13 U45 YIO Y68 U35 Y34 X60 X50 Y84 S-16

- 13 X2 3 FEED S-3 X(-9 FEED A-8 FEED FEED E-5 FEED FEED Y-8 FEED B-9 C-i6 FEED X(28

- 12 E-15 Y54 T01 Y41 U33 Y32 U24 U47 U68 U46 U32 Y26 U25 Y52 P04 Y55 G-17 2700 -- 11 X29 FEED iFEED E-2 FEED E-20 E-17 F-13 T-5 T-2 FEED T-20 FEED L-6 FEED 2(09

- 10 P-5 Y91 X57 X64 Y40 U36 Y63 Y25 U48 Y22 Y65 U27 Y31 X52 X62 Y92 T-7

-9 X(41 FEED W-6 IX-13 FEED A-14 FEED FEED T-17 FEED FEED Y-14 FEED B-13 F-i9 FEED 2(08

-8 F-6 059 Y09 Y43 U02 Y36 U64 Y57 U23 Y74 U52 Y07 U04 Y48 Y16 060 L-9

-7 W-il FEED FEED S-4 FEED L-5 FEED X-17 FEED E-II FEED F-4 FEED FEED G-15 X12 Y62 X71 Y30 X01 Y19 U21 Y33 UI7 Y35 X02 Y39 X65 Y61 X26 6

N-15 FEED W-7 FEED B-lI FEED H-21 FEED P-21 FEED L-20 FEED C-7 FEED N-I X38 Y89 Y78 U65 Y04 U01 Y38 U31 Y05 U07 Y11 U50 Y77 Y90 X44 5

N-4 FEED FEED J-16 FEED V-6 FEED B-17 FEED D-6 FEED S-13 FEED FEED V-9 X(32 I2X46 P 73 2(X72 Y49 2(61 IP46 X(49 IP47 X(67 Y80 2(458 X30 4

D-5 ID-18IFEEDI R-3 PEEDI J-2 FEED N-2 IFEED 0-3 FEED IV-i V-S X 5 P 811 Y72 Y06 X528 T02 2X55 Y12 Y69 Y87 2(16 Id 3

- FEED FEED FEED C-6 S-Il F-3 FEED FEED FEED X34 X19 U58 Y81 Y56 Y93 U51 X15 IX35 2

N-18 R-13 G-7 FEED FEED FEED L-3 R-9 D-9 X(06 I2(27 I2X13 2(X42 1 Previous Cycle Location N-li R-17 E-7 Fi

[TZZ Assembly Identifier 1800

St. Lucie Unit 2, Representative First Cycle Uprate Attachment 2 Reference Core Loading Pattern L-2010-278 LEGEND REGION TI

( 3. 7 9 9 W/o) D REGION X4 4.100Wo)

D REGION Ul (3.802w/O)

D REGION XS

4. 1 0 0 W/o)

D Z REGION U2 3.802w/O)

D REGION X6 (4.100W/o)

D REGION U4 (4.202w/o)

D REGION Y1 (4.200w/O)

DREGION US (4.202W/o)

REGION Y2 (4.200W/o)

SREGION X1 REGION Y3 (3.900 W/o) (4.400W/o)

D REGION X2 S3E900ow/)

SREGION S4.20 Y4 W/)

REGION X3 SREGION YS (3.900w/O) (4.400W/o)

Attachment 2 L-2010-278 ST. LUCIE UNIT 2, Representative First Uprate Cycle REGION AND FUEL ASSEMBLY LOCATIONS y x w V T S R P N M L K J H G F E D C B A X3 X2 X2 IXl 21 X40 X31 X25 X07 I I X3 X2 U5 1 Y5 Y3 Y5 IU5 X2 X3 X20 -- _ 20 X43 U66 Y83 Y53 Y86 U53 X17 X39 Y5 Y4 Y1 X5 T1 X5 Y1 Y4 Y5 X2

- 19 4 Y88 Y59 Y03 X56 T03 X63 Y15 Y64 Y94 X21 X2 X4 Y4 X6 Y2 X5 Y2 X5 Y2 X6 Y4 X4 X2

- 18 X10 X48 Y66 X66 Y42 X54 Y44 X51 Y45 X68 Y75 X47 X18 X3 Y5 Y4 U5 Y1 U1 Y1 1U2 Y1 U1 Y1 U5 Y4 Y5 X3 17 X33 Y95 Y76 U49 Y18 U06 Y28 U29 Y29 U05 Y02 U63 Y58 Y82 X36 X2 Y4 X6 Yi X1 Yi U2 Y1 U2 Y1 X1 Y1 X6 Y4 X2 -- 16 X22 Y79 X69 Y37 X03 Y08 U28 Y23 U15 Y24 X05 Y20 X70 Y60 X14 15 Y Y2 U11 Y1 U5 Y4 U2 Y4 U5 Yi U1 Y2 Y1 U5

-- 15 X3 xl U61 Y21 Y50 U08 Y14 U55 Y70 U30 Y71 U54 Y17 U03 Y51 Y01 U62

- 14 X04 Y5 X5 X5 Y1 U2 Y4 Y1 U4 Y1 Y4 U2 Y1 X5 X5 Y5 X3 7

-- 13 X2 Y96 X53 X59 Y27 1U13 Y67 Y13 U45 Y10 Y68 U35 Y34 X60 X50 Y84 X2

- 12 X2 3 Y3 Ti Y2 U2 Y1 U2 U4 U5 U4 U2 Y1 U2 Y2 Ti Y3 X28 -- 11 2700 -- i0 X2 Y54 T01 Y41 U33 Y32 U24 U47 U68 U46 U32 Y26 U25 Y52 T04 Y55 X2 -1 X29 Y5 X5 X5 Y1 U2 Y4 Y1 U4 Yi Y4 U2 Y1 X5 X5 Y5 X0 9

-9 X3 Y91 X57 X64 Y40 U36 Y63 Y25 U48 Y22 Y65 U27 Y31 X52 X62 Y92 xl -- 8 X4 1 15 i Y2 U11 Y1 u5 Y4 U2 Y4 U5 Y1 U1 Y2 Y1 U5 X0 8

-7 159 Y09 Y43 U02 Y36 U64 Y57 U23 Y74 U52 Y07 U04 Y48 Y16 U60 X2 Y4 X6 Ti X1 Y1 U2 Y1 U2 Y1 X1 Yi X6 Y4 X2 6

X12 Y62 X71 Y30 X01 Y19 U21 Y33 U17 Y35 X02 Y39 X65 Y61 X26 X3 Y5 Y4 U5 Y1 U11 Y U2 Y1 U11 Y u5 Y4 Y5 X3 5

X38 Y89 Y78 U65 Y04 U01 Y38 U31 Y05 U07 YIl U50 Y77 Y90 X44 X2 X4 Y4 X6 Y2 X5 Y2 X5 Y2 X6 Y4 X4 X2 4

X32 X46 Y73 X72 Y49 X61 Y46 X49 Y47 X67 Y80 X45 X30 X2 xli Y5 Y85 Y4 Y72 IY Y06 X5 X58 T1 T02 X5 X55 Y1 Y12 Y4 Y69 Y5 Y87 X2 X16 1 3 X3 X2 I U5 I Y5 I Y3 IY5 U5 X2 X3 2 X34 X19 U58 Y81 Y56 Y93 U51 XI5 X35

_________- a a ~ ~

Xl IX2 IX2 IX3 1 X06 X27 X13 X42 1800 LEGEND R Region Identifier

[jD] Fuel Assembly Identifier

Attachment 2 L-2010-278 ST. LUCIE UNIT 2, Representative Second Uprate Cycle REFERENCE CORE LOADING PATTERN Y x w V T S R P N M L K J H G F E D C B A Y33IY73 YO Y13 21 L-6 T-4 E-4 N-13 I I Y36 S-7 Y70 Y34 ] A59 N-15 E-13 FEED FEED FEED A03 ] A62 ] Y38 N-5 Y41 I Y07 V-lI F-7

_ _ Fi 20 Y30 A64 A21 A24 Y88 Y96 Y94 A38 A40 A70 Y02 i - 19 T-6 FEED FEED FEED T-19 X-13 E-19 FEED FEED FEED F-17 Y37 A73 Y56 Y79 A86 Y49 A53 Y65 A88 Y59 Y593 A74 Y18 i 18 T-16 FEED L-2 W-16 FEED R-4 FEED G-9 FEED S-19 J-2 FEED 5-17 Y24 A71 Y84 YI5 A02 X08 A49 Y03 A10 X41 A33 Y16 Y54 A58 Y08 i- 17 G-16 FEED B-13 G-19 FEED A-8 FEED R-19 FEED Y-8 FEED C-7 X-ii FEED R-16 Y46 A34 Y62 A29 X30 A78 X34 A31 X35 A80 X1i A20 Y64 A23 Y68

-- 16 L-4 FEED W-6 FEED C-4 FEED T-2 FEED E-2 FEED V-3 FEED F-iS FEED 0-13 Y31 A01 A89 X42 A81 X16 A37 Y51 A18 X32 A82 X06 A90 A12 Y05

-- 15 Y25 E-9 FEED FEED H-I FEED D-3 FEED D-15 FEED W-4 FEED P-I FEED FEED J-S Y3 2

- 14 N-9 A72 Y95 Y71 A45 X36 A43 X48 A36 X47 A52 X33 A35 Y50 Y82 A60 5-11

- 13 Y5 8 FEED W-17 J-15 FEED B-17 FEED V-18 FEED D-18 FEED X-17 FEED V-15 C-17 FEED Y76

- 12 D-17 A32 Y81 A54 Y09 A42 Y42 All U67 A47 Y47 A09 Y01 ASS Y86 A22 V- 17 2700 -11 Y7 7 FEED N-2 FEED W-7 FEED R-18 FEED J-6 FEED G-4 FEED C-15'FEED J-20 FEED Y78

- 10 D-5 A67 Y89 Y48 A41 X44 A27 X46 A44 X45 A46 X38 A51 Y57 Y90 A68 V-S

-9 Y26 FEED W-5 D-7 FEED B-S FEED V-4 FEED D-4 FEED X-5 FEED N-7 C-S FEED Yl10

-8 F-li Y28 A04 A91 X07 A83 X18 A50 Y43 A05 X24 A77 X40 A85 AlE Y27 J-13

-7 N-17 FEED FEED H-21 FEED C-18 FEED V-7 FEED V-19 FEED P-21 FEED FEED T-13 Y63 A08 Y72 A17 X21 A84 X43 A26 X39 A79 X10 A25 Y60 A13 Y44 6

R-9 FEED S-3 FEED D-19 FEED T-20 FEED E-20 FEED W-18 FEED C-16 FEED L-18 Y35 A65 Y55 Y21 A39 X37 A30 Y12 A48 X04 A28 Y06 Y9i ASS Yl9 S-G-6 FEED B-lI W-15 FEED A-14 FEED G-3 FEED Y-14 FEED R-3 X-9 FEED H-6 YII A75 Y83 Y69 A92 Y67 A56 Y45 A87 Y61 Y53 A76 Y39 4

F-5 FEED N-20 F-3 FEED R-13 FEED G-18i FEED C-6 L-20 FEED E-E Y04 A61 A14 AIS Y85 Y92 Y87 A07 A06 A63 Y20 3

S-5 FEED FEED FEED T-3 B-9 E-3 FEED FEED FEED E-161

• from Cycle 17 Y14 Y52 Y29 A57 A5I A69 Y40 Y74 YI7 2

S-15 D-11 J-17 FEED FEED FEED T-9 J-7 F-15

[7] Assembly Identifier Y22 Y66 IY75 IY23 1

J-9 T-18 E-18 L-16 j Previous Cycle Location 1800 REGION Al REGION U5 REGION Yl (4. 2 0 0 W/o) ( . 2W/o) ( 4 . 2 0 0 W/o)

F1(

REGION A2 4.200w/o) fl (

4 20 REGION X1 W/o) fl REGION Y2 3 9 00 ( 4 . 2 0 0 W/ 0 )

SREGION A3 F7 (4.2 0Ow/o) fl *REGION X2

( . W/o)

- REGION Y3

( 4.400W/o) 3 900 I REGION A4 fl REGION X3

( . W/o)

• REGION Y4 F (4.200/o ) 3 900 ( 4.2ROW/N)

SREGION AS F 7 ( 4.200w/o)

LI REGION X4

( 4.100W/o)

-]REGION Y5

( 4.400w/0)

Attachment 2 L-2010-278 ST. LUCIE UNIT 2, Representative Second Uprate Cycle REGION AND FUEL ASSEMBLY LOCATIONS y x w V T S R P N M L K J H G F E D C B A IYl Y4 Y4 Yl 21 Y33 Y73 Y80 Y13; Y1 Y4 Yl A3 Al A3 Yl Y2 Y1 Y36 Y70 _-- 20 Y34 A59 A03 A62 Y38 Y41 Y07

____ ____ ~

yl A3 Al Al Y5 Y5 Y5 Al Al A3 Vi i -- 19 Y30 A64 A21 A24 Y88 Y96 Y94 A38 A40 A70 Y02 Yl I A3 Y3 Y4 A5 Y2 A2 Y4 A5 Y4 Y5 A3 Ir i-- 18 Y37 A73 Y56 Y79 A86 Y49 A53 Y65 A88 Y59 Y93 A74 Y18 YY A3 Y5 Vi Al Xl Al Y1 Al X3 Al Yl Y3 A3 YY

-- 17 Y24 A71 Y84 YI5 A02 X08 A49 Y03 A10 X41 A33 Y16 Y54 A58 Y08 Y2 Al Y4 Al X2 A4 X3 Al X3 A4 X2 Al Y4 Al Y4

-- 16 Y46 A34 Y62 A29 X30 A78 X34 A31 X35 A80 XlI A20 Y64 A23 Y68 Vi Al AS X3 A4 X2 Al Y2 Al X2 A4 X1 A5 Al Vi

- 15 Vi Y31 A0l A89 X42 A81 X16 A37 Y51 A18 X32 A82 X06 A90 A12 Y05 Vi

- 14 Y25S A3 VS Y4 Al X3 Al X4 Al X4 Al X3 Al Y2 YS A3 Y3 2

- 13 Y4 A72 Y95 Y71 A45 X36 A43 X48 A36 X47 A52 X33 A35 Y50 Y82 A60 Y4

- 12 Y5 8 Al Y5 A2 Y1 Al Y2 Al U5 Al Y2 Al Yl A2 VS Al Y76 2700 -11 Y4 A32 Y81 A54 Y09 A42 Y42 All U67 A47 Y47 A09 Y01 ASS Y86 A22 Y4

- 10 Y7 7 A3 VS Y2 Al X3 Al X4 Al X4 Al X3 Al Y4 VS A3 Y78

-9 Vi A67 Y89 Y48 A41 X44 A27 X46 A44 X45 A46 X38 A51 Y57 Y90 A68 Vl

-8 Y26 Vi Al AS Xl A4 X2 Al Y2 Al X2 A4 X3 AS Al Vi Y10

-7 Y28 A04 A91 X07 A83 X18 A50 Y43 A05 X24 A77 X40 A85 A16 Y27 Y4 Al Y4 Al X2 A4 X3 Al X3 A4 X2 Al Y4 Al Y2 6

Y63 A08 Y72 A17 X21 A84 X43 A26 X39 A79 X10 A25 Y60 A13 Y44 Vi A3 Y3 Yi Al X3 Al Y1 Al Xl Al Y1i VS A3

-- S 5

Y35 A65 Y55 Y21 A39 X37 A30 Y12 A48 X04 A28 Y06 Y91 A66 Y19 Y1i A3 VS5 Y4 IAS IV4 IA2 IV2 AS IY4 IY3 A3 Y1 4 Vii A75 Y83 Y69 A92 Y67 A56 Y45 A87 Y61 Y53 A76 Y39 1

YI A3 Al Al Y5 2 YV Al Al A3 Y3 Y04 A61 A14 A19 Y85 Y92 Y87 A07 A06 A63 120 3 YV Y2 YI A3 Al A3 Y1 Y4 IY 2

Y14 Y52 Y29 A57 AI5 A69 Y40 Y74 Y17 Vi IV4 I 4 IY1 1 Y22 Y66 Y75 Y23 1800 LEGEND 7TR Region Identifier Fuel Assembly Identifier

Attachment 2 L-2010-278 ST. LUCIE UNIT 2, Representative Third Uprate Cycle REFERENCE CORE LOADING PATTERN Y x w V T S R P N M L K J H G F E D C B A A30 A33 A28 A35I I ~ + ~ 21 N-5 F-17 F-5 E-13 I I A91 A81I A52 B67 B03 B70 A46 A78 A85

__ -- 20 V-7 S-15 G-13 FEED FEED FEED G-9 R-16 D-7 1 B72 Bl0 B12 A68 A73 A59 B21 B22 B78 A56 FA3 ----- 19 FEED FEED FEED B-9 V-18 N-20 FEED FEED FEED L-4 A55 B81 A70 A21I B86 A07 B29 A19 B88 A40 A64 B82 A09

--- 18 D-11 FEED E-19 S-19 FEED G-3 FEED R-3 FEED F-19 T-19 FEED F-I A88 B79 A65 A32 B35 X09 B42 A44 B45 X29 B55 A03 A66 B66 A86

-- 17 G-18 FEED W-5 X-11 FEED A-10 FEED L-9 FEED Y-10 FEED L-20 C-5 FEED R-18 A83 B02 A34 B56 Y78 B34 Y14 B27 Y17 B63 Y66 B37 A23 B05 A80 i- 16 S-7 FEED W-16 FEED A-10 FEED T-2 FEED E-2 FEED M-I FEED C-16 FEED G-16 A18 Bi6 B89 X13

• B50 Y73 B51 Y33 B47 Y76 B48 X27

• B90 B17 A05

- 15 A49 J-15 FEED FEED K-1 FEED M-21 FEED P-21 FEED A-12 FEED M-1 FEED FEED J-7 A45S

- 14 N-17 EB8 A67 A16 B41 Y08 B44 B13 Y13 B14 B33 Y24 B54 A04 A57 B68 T-13

- 13 A20 FEED X-9 C-7 FEED B-17 FEED FEED H-21 FEED FEED X-17 FEED W-7 N-2 FEED A25S

- 12 E-16 B09 A75 B30 A47 Bll Y26 Y25 U57 Y10 Y32 B01 All B31 A74 B20 E-S -- ii 2700 A2 9 FEED V-4 FEED J-11 FEED Y-8 Y-14 S-9 A-8 A-14 FEED N-Il FEED D-18 FEED A17

- 10 T-16 B75 A62 A12 B40 Y19 B39 B08 Y22 B07 B61 Y35 B59 A01 A60 B76 T-6

-9 A5 1 FEED J-20 C-1S FEED B-5 FEED FEED P-1 FEED FEED X-5 FEED W-15 B-13 FEED A4 8

-8 E-9 A37 B25 B91 X25 B53 Y77 B64 Y23 B52 Y75 B49 X31 B85 B24 A50 ,J-S

-7 N-iS FEED FEED K-21 FEED Y-10 FEED H-1 FEED K-1 FEED M-21 FEED FEED N-7 A84 B19 A08 B58 Y80 B38 Y36 B28 Y07. B62 Y58 B36 A13 B18 A82 6

R-6 FEED W-6 FEED K-21 FEED T-20 FEED E-20 FEED Y-12 FEED C-6 FEED F-15 A87 B73 A71 Ai5 B43 X28 B57 A36 B46 X23 B60 A22 A58 B74 A92 5

G-4 FEED W-i7 L-2 FEED A-12 FEED L-13 FEED Y-12 FEED B-11 C-17 FEED R-4 A42 B83 A63 A14 B92 A38 B32 A24 B87 A06 A61 B84 A54 4

S-li FEED E-3 S-3 FEED G-19 FEED R-19 FEED F-3 T-3 FEED V-Il

____ + + + 4 + +-+-+-+-+-+-+-

A53 B69 i5 B23 A69 A76 A72 B06 B26 B71 A26 3

L-i8 FEED FEED FEED J-2 D-4 X-13 FEED FEED FEED

• from Cycle 18 A89 A79 A43 B65 B04 B77 A27 A77 A90

• • from Cycle 17 2 V-15i G-6 R-13 FEED FEED FEED R-9 F-7 D-15 MY ] Assembly Identifier A41I A02 IA39 IAi0 1 Previous Cycle Location T-9 S-17 S-S J-17 1800 REGION Al REGION Bl REGION U5

( 4 . 2 0 0 W/o) ( . 2 0Ow/o) ( 4. 2 0 4 2 W/o)

• REGION A2

• REGION B2 REGION X2 F1( 4.200W/o) ( 4.200W/o) ( 3 .90 0W/o)

• ] REGION A3 - REGION B3 REGION Y1 F7 ( 4.200W/o) ( 4 . 2 0OW/o) ( 4.200W/o)

SREGION A4 SREGION B4 flREGION

-- Y4

( 4.20Ow/0) ( 4 . 2 0OW/o) ( 4.200W/o)

REGION A5 [ REGION B5

( 4. 200W/o) 1 ( 4. 2 0 0 W/ 0 )

Attachment 2 L-2010-278 ST. LUCIE UNIT 2, Representative Third Uprate Cycle REGION AND FUEL ASSEMBLY LOCATIONS Y x w V T S R P N M L K J H G F E D C B A Al Al Al 21

[ýA:30A3 A28 A35 I I E4 Al A4 A5 AS A4 A4 Al A5 B4 B4 El B1 B4 A4 A4 A5 A81 A52 B67 B03 B70 A46 A78 A85 ----- F -- - 20 A91 Al B4 Bl Bi A3 A3 A3 Bl B1 B4 A2 L B10 _ - -- -- -- 19 A31 B72 B12 A68 A73 A59 B21 B22 B78 A56 B4 A3 t B5 B2 Al B5 Al A3 B4 Al A2 Al Al

-- 18 A55 B81 A70 A21 B86 A07 B29 A19 B88 A40 A64 B82 A09 AS B4 A3 Al B3 X2 B3 Al B3 X2 B3 Al A3 B4 AS

--_ 17 A88 B79 A65 A32 B35 X09 B42 A44 B45 X29 B55 A03 A66 B66 A86 A4 Bl Al B3 Y4 B3 Yl Bl Yl B3 Y4 B3 Al BI A4

--_ 16 A83 B02 A34 B56 Y78 B34 Y14 B27 Y17 B63 Y66 B37 A23 B05 A80 Al Bl B5 X2 B3 Y4 B3 Yl B3 Y4 B3 X2 B5 BI Al

- 15 Al A18 BE6 B89 X13 B50 Y73 B51 Y33 B47 Y76 B48 X27 B90 B17 A05 Al

- 14 A4 9 B4 A3 Al B3 Yl B3 Bl Yl Bl B3 Yl B3 Al A3 B4 A45

- 13 Al B80 A67 A16 B41 Y08 B44 B13 Y13 B14 B33 Y24 B54 A04 A57 B68 Al

- 12 A2 0 Bl A3 B2 Al Bl Yl Yl U5 Yl Yl Bl Al B2 A3 Bl A25 2700 - 11 Al B09 A75 B30 A47 Bll Y26 Y25 U57 Y10 Y32 B01 All B31 A74 B20

_ 10 A29 B4 A3 Al B3 Yl B3 BE Yl Bl B3 Yl B3 Al A3 B4 Al

-9 Al B75 A62 A12 B40 Y19 B39 BOB Y22 B07 B61 Y35 B59 A01 A60 B76 -- 8 A5 1 Al Bl B5 X2 B3 Y4 B3 Yl B3 Y4 B3 X2 B5 Bl Al A4 8 -- 7 A37 B25 B91 X25 B53 Y77 B64 Y23 B52 Y75 B49 X31 B85 B24 A50 A4 Bl Al B3 Y4 B3 Yl Bl Yl B3 Y4 B3 Al Bl A4 A84 B19 A08 B58 Y80 B38 Y36 B28 Y07 B62 Y58 B36 A13 B18 A82 AS E4 A3 Al B3 X2 B3 Al B3 X2 B3 Al A3 B4 AS 5

A87 373 A71 A15 B43 X28 B57 A36 B46 X23 B60 A22 A58 B74 A92 Al B4 A3 Al B5 Al B2 Al B5 Al A3 B4 A2 4

A42 B83 A63 A14 B92 A38 B32 A24 B87 A06 A61 B84 A54 A2 B4 Bl Bl A3 A3 A3 Bl Bl B4 Al 3

A53 B69 BE5 B23 A69 A76 A72 B06 B26 B71 A26 AS A4 Al B4 BE B4 Al A4 AS 2

A89 A79 A43 B65 B04 B77 A27 A77 A90 Al IAl IAl Al 1 A41 A02 A39 A10 1800 LEGEND Region Identifier

[jD]-R Fuel Assembly Identifier

Attachment 2 L-2010-278 Representative First Uprate Cycle Exposure Map (BOC - 100 EFPH)

• • ANC 8.10.5 ** REF BU= 145. REF TIME= 100.0 DATE: 04/03/08 USER: rnorring JOB: anc nw JOB NUMBER: 5876 MACHINE: HP-UX - jbxsa306 100 EFPH CASE-0002 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 35064 35058 24280 186 24280 182 34935 189 20210 2 35058 171 183 25244 187 17346 17973 171 20071 3 24280 183 35621 184 33837 185 175 37328 4 186 25165 184 18011 188 19489 169 20137 5 24280 188 33849 188 35107 182 159 19938 6 182 17436 186 19463 183 16468 18927 7 34935 17959 178 171 160 18926 8 189 172 36423 20129 19963 9 20216 20246 Maximum Max Loc Minimum Min Loc 37328 ( 3, 8) 159 ( 5, 7)

E-END

Attachment 2 L-2010-278 Representative First Uprate Cycle Exposure Map (MOC - 7000 EFPH)

• • ANC 8.10.5

• REF BU= 10182. REF TIME= 7000.0 DATE: 04/03/08 USER: rnorring JOB: anc nw JOB NUMBER: 5876 MACHINE: HP-UX - jbxsa306 7000 EFPH CASE-0011 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 42644 43623 34468 13187 34770 12623 43604 12057 25323 2 43623 12604 13404 35580 13085 28764 28692 11198 23696 3 34468 13391 45457 13022 43253 13167 12318 43229 4 13187 35519 13015 29318 13219 31029 12214 25621 5 34770 13132 43272 13224 44931 13031 11281 24068 6 12623 28874 13225 31050 13068 25661 24084 7 43604 28727 12440 12301 11333 24094 8 12057 11250 42446 25677 24126 9 25333 23851 Maximum Max Loc Minimum Min Loc 45457 ( 3, 3) 11198 ( 2, 8)

E-END

Attachment 2 L-2010-278 Representative First Uprate Cycle Exposure Map (EOC - 12360 EFPH)

• • ANC 8.10.5 ** REF BU= 17979. REF TIME= 12360.1 DATE: 04/03/08 USER: rnorring JOB: anc nw JOB NUMBER: 5876 MACHINE: HP-UX - jbxsa306 12360 EFPH CASE-0017 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 48945 50551 42440 23493 43015 22675 50224 20566 29251 2 50551 22610 23732 43667 23396 37543 36719 19285 26624 3 42440 23714 53193 23227 50781 23648 22018 47968 4 23493 43614 23214 37892 23413 39741 21608 30080 5 43015 23456 50794 23411 52411 22651 19521 27379 6 22675 37647 23707 39764 22690 32484 28047 7 50224 36765 22170 21705 19575 28058 8 20566 19345 47252 30158 27446 9 29257 26736 Maximum Max Loc Minimum Min Loc 53193 ( 3, 3) 19285 ( 2, 8)

E-END

Attachment 2 L-2010-278 Representative Second Uprate Cycle Exposure Map (BOC - 100 EFPH)

• • ANC 8.10.5 ** REF BU= 146. REF TIME= 100.0 DATE: 05/06/08 USER: rnorring JOB: anc nw JOB NUMBER: 6153 MACHINE: HP-UX - jbxsa306 100 EFPH CASE-0002 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 35086 167 23860 183 22333 173 19461 174 22765 2 167 32616 175 27589 185 23892 19696 171 22665 3 23860 176 28196 179 26882 184 181 23502 4 183 27523 180 28189 185 21868 167 22754 5 22333 185 26770 185 22181 19511 151 23283 6 173 23807 183 21770 20729 161 23488 7 19461 19750 180 165 150 23485 8 174 171 23561 23791 23269 9 22725 23547 Maximum Max Loc Minimum Min Loc 35086 ( ,1 ) 150 ( 7, 5)

E-END

Attachment 2 L-2010-278 Representative Second Uprate Cycle Exposure Map (MOC - 7000 EFPH)

• • ANC 8.10.5 ** REF BU= 10188. REF TIME= 7000.0 DATE: 05/06/08 USER: rnorring JOB: anc nw JOB NUMBER: 6153 MACHINE: HP-UX - jbxsa306 7000 EFPH CASE-0011 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 44191 12410 34617 13195 33592 12568 30984 11749 27950 2 12410 42116 12837 37672 13256 34806 31133 11565 26567 3 34617 12873 38083 13131 37026 13136 12635 30760 4 13195 37638 13163 38126 12943 32746 11655 28333 5 33592 13260 36953 12963 32856 30210 10319 27231 6 12568 34687 13088 32626 31277 10700 28525 7 30984 31180 12561 11561 10246 28500 8 11749 11538 30754 29251 27182 9 27900 27374 Maximum Max Loc Minimum Min Loc 44191 ( 1, 1) 10246 ( 7, 5)

E-END

Attachment 2 L-2010-278 Representative Second Uprate Cycle Exposure Map (EOC - 12360 EFPH)

• • ANC 8.10.5 ** REF BU= 17990. REF TIME= 12360.1 DATE: 05/06/08 USER: rnorring JOB: anc nw JOB NUMBER: 6153 MACHINE: HP-UX - jbxsa306 12360 EFPH CASE-0017 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 51721 22506 43004 23503 42301 22861 39490 20578 32054 2 22506 49798 23011 45564 23598 43225 39584 19946 29694 3 43004 23062 45846 23211 44952 23569 22505 36409 4 23503 45545 23253 45806 22867 40992 20829 32917 5 42301 23597 44897 22896 40700 37916 17941 30445 6 22861 43051 23495 40865 38885 18247 32318 7 39490 39623 22394 20688 17836 32282 8 20578 19905 36362 33721 30373 9 31999 30446 Maximum Max Loc Minimum Min Loc 51721 ( 1, 1) 17836 ( 7, 5)

E-END

Attachment 2 L-2010-278 Representative Third Uprate Cycle Exposure Map (BOC - 100 EFPH)

• • ANC 8.10.5 ** REF BU= 146. REF TIME= 100.0 DATE: 06/03/08 USER: rnorring JOB: anc nw N JOB NUMBER: 6439 MACHINE: HP-UX - jbxsa306 100 EFPH CASE-0002 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 35060 29811 30576 176 22667 173 18422 175 22971 2 29811 163 170 30511 181 22667 20075 171 23652 3 30576 171 32133 171 29395 185 185 23119 4 176 30584 172 32192 185 20999 175 23335 5 22667 182 29389 186 20748 18009 160 23627 6 173 22558 186 20858 18113 169 22940 7 18422 20117 185 175 160 23582 8 175 171 23169 23292 23554 9 22942 23653 Maximum Max Loc Minimum Min Loc 35060 ( 1, 1) 160 ( 7, 5)

E-END

Attachment 2 L-2010-278 Representative Third Uprate Cycle Exposure Map (MOC - 7000 EFPH)

I ** ANC 8.10.5 ** REF BU= 10187. REF TIME= 7000.0 DATE: 06/03/08 USER: rnorring JOB: anc nw N JOB NUMBER: 6439 MACHINE: HP-UX - jbxsa306 7000 EFPH CASE-0011 PAGE-0018 C- -BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 42705 38636 40106 13002 33813 12594 29944 12080 28239 2 38636 12508 12683 40342 13023 33730 31340 11705 27550

-3 40106 12721 41721 12386 39016 13218 13083 30577 4 13002 40437 12435 41667 12756 32215 12259 29087 5 33813 13059 39041 12764 31622 28894 10678 27691 6 12594 33686 13253 32089 28970 10906 28114 7 29944 31409 13079 12258 10671 28733 8 12080 11677 30603 29044 27621 9 28206 27539 Maximum Max Loc Minimum Min Loc 42705 ( 1, 1) 10671 ( 7, 5)

E-END

Attachment 2 L-2010-278 Representative Third Uprate Cycle Exposure Map (EOC - 12360 EFPH)

• • ANC 8.10.5 ** REF BU= 17988. REF TIME= 12360.1 DATE: 06/03/08 USER: rnorring JOB: anc nwN JOB NUMBER: 6439 MACHINE: HP-UX - jbxsa306 12360 EFPH CASE-0017 PAGE-0018 C-BU AVERAGE ASSEMBLY BURNUP 1 2 3 4 5 6 7 8 9 1 49262 46068 47974 23380 42586 22935 38323 20828 32285 2 46068 22829 23175 48359 23446 42264 39519 19958 30586 3 47974 23230 49700 22601 46810 23626 22848 36171 4 23380 48461 22670 49369 22730 40563 21410 33577 5 42586 23491 46846 22740 39621 36601 18286 30862 6 22935 42250 23669 40445 36660 18449 31914 7 38323 39601 22840 21408 18278 32518 8 20828 19917 36182 33533 30794 9 32250 30569 Maximum Max Loc Minimum Min Loc 49700 ( 3, 3) 18278 ( 7, 5)

E-END

Attachment 2 L-2010-278 Representative First Uprate Cycle Radial Power Distribution (BOC - 100 EFPH)

• • ANC 8.10.5 ** REF BU= 145. REF TIME= 100.0 DATE: 04/03/08 USER: rnorring JOB: anc nw JOB NUMBER: 5876 MACHINE: HP-UX - jbxsa306 100 EFPS CASE-0002 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.713 0.821 0.997 1.273 1.068 1.244 0.916 1.299 0.538 2 0.821 1.176 1.258 1.032 1.278 1.186 1.141 1.176 0.367 3 0.997 1.257 0.965 1.258 0.940 1.261 1.201 0.591 4 1.273 1.034 1.258 1.155 1.283 1.157 1.160 0.524 5 1.068 1.284 0.942 1.284 0.979 1.246 1.091 0.390 6 1.244 1.190 1.269 1.164 1.251 0.914 0.499 7 0.916 1.148 1.217 1.172 1.099 0.501 8 1.299 1.184 0.606 0.533 0.395 9 0.539 0.366 Maximum Max Loc Minimum Min Loc 1.299 ( 1, 8) 0.366 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative First Uprate Cycle Radial Power Distribution (MOC - 7000 EFPH)

• ANC 8.10.5 ** REF BU= 10182. REF TIME= 7000.0 DATE: 04/03/08 USER: rnorring JOB: anc nw JOB NUMBER: 5876 MACHINE: HP-UX - jbxsa306 7000 EFPH CASE-0011 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.785 0.881 1.034 1.334 1.052 1.264 0.820 1.074 0.471 2 0.881 1.295 1.367 1.043 1.319 1.122 1.014 1.017 0.347 3 1:034 1.366 1.001 1.316 0.959 1.344 1.227 0.579 4 1.334 1.045 1.315 1.115 1.322 1.136 1.222 0.552 5 1.052 1.323 0.959 1.321 0.972 1.277 1.085 0.412 6 1.264 1.123 1.348 1.139 1.279 0.892 0.504 7 0.820 1.017 1.235 1.227 1.087 0.505 8 1.074 1.019 0.589 0.557 0.414 9 0.471 0.342 Maximum Max Loc Minimum Min Loc 1.367 ( 2, 3) 0.342 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative First Uprate Cycle Radial Power Distribution (EOC - 12360 EFPH)

• • ANC 8.10.5 ** REF BU= 17979. REF TIME= 12360.1 DATE: 04/03/08 USER: rnorring JOB: anc nw JOB NUMBER: 5876 MACHINE: HP-UX - jbxsa306 12360 EFPH CASE-0017 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.834 0.900 1.015 1.287 1.049 1.276 0.879 1.131 0.549 2 0.900 1.256 1.285 1.026 1.293 1.121 1.050 1.077 0.414 3 1.015 1.284 0.982 1.276 0.967 1.312 1.239 0.643 4 1.287 1.027 1.275 1.078 1.277 1.101 1.194 0.599 5 1.049 1.293 0.966 1.276 0.957 1.215 1.060 0.446 6 1.276 1.120 1.311 1.100 1.215 0.890 0.528 7 0.879 1.051 1.241 1.194 1.060 0.528 8 1.131 1.077 0.650 0.601 0.447 9 0.548 0.406 Maximum Max Loc Minimum Min Loc 1.312 ( 3, 6) 0.406 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative First Uprate Cycle Axial Power Distribution BOC MOC EOC (100 EFPH (7000 EFPH) (12360 EFPH)

HEIGHT POWER POWER POWER ROW (cm) (RPF) (RPF) (RPF) 24 341.5 0.414 0.426 0.528 23 328.09 0.742 0.728 0.859 22 314.95 0.851 0.863 0.997 21 300.17 0.941 0.962 1.056 20 285.4 1.001 1.02 1.065 19 270.62 1.043 1.055 1.056 18 255.85 1.075 1.075 1.044 17 241.07 1.1 1.088 1.033 16 226.29 1.12 1.097 1.026 15 211.52 1.135 1.103 1.022 14 196.74 1.147 1.107 1.021 13 181.97 1.155 1.111 1.022 12 167.19 1.159 1.116 1.025 11 152.41 1.159 1.12 1.03 10 137.64 1.156 1.124 1.037 9 122.86 1.148 1.129 1.047 8 108.09 1.136 1.132 1.06 7 93.31 1.118 1.133 1.077 6 78.53 1.092 1.127 1.099 5 63.76 1.057 1.107 1.119 4 48.98 1.004 1.06 1.127 3 34.21 0.921 0.964 1.087 2 21.07 0.815 0.816 0.958 1 7.66 0.455 0.477 0.6

Attachment 2 L-2010-278 Representative Second Uprate Cycle Radial Power Distribution (BOC - 100 EFPH)

• • ANC 8.10.5 ** REF BU= 146. REF TIME= 100.0 DATE: 05/06/08 USER: rnorring JOB: anc nw JOB NUMBER: 6153 MACHINE: HP-UX - jbxsa306 100 EFPH CASE-0002 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.860 1.153 1.052 1.253 1.119 1.180 1.210 1.186 0.518 2 1.153 0.916 1.204 0.982 1.266 1.098 1.198 1.177 0.385 3 1.052 1.209 0.954 1.229 0.999 1.254 1.237 0.731 4 1.253 0.986 1.232 0.979 1.265 1.118 1.144 0.545 5 1.119 1.267 1.006 1.268 1.119 1.142 1.043 0.386 6 1.180 1.094 1.249 1.116 1.125 1.110 0.517 7 1.210 1.198 1.230 1.134 1.034 0.514 8 1.186 1.174 0.724 0.535 0.382 9 0.517 0.377 Maximum Max Loc Minimum Min Loc 1.268 ( 5, 4) 0.377 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative Second Uprate Cycle Radial Power Distribution (MOC - 7000 EFPH)

• • ANC 8.10.5 ** REF BU= 10188. REF TIME= 7000.0 DATE: 05/06/08 USER: rnorring JOB: anc nw JOB NUMBER: 6153 MACHINE: HP-UX - jbxsa306 7000 EFPH CASE-0011 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.953 1.290 1.091 1.352 1.137 1.312 1.098 1.108 0.499 2 1.290 0.988 1.324 1.030 1.354 1.089 1.092 1.074 0.379 3 1.091 1.327 1.015 1.346 1.027 1.344 1.254 0.702 4 1.352 1.032 1.348 1.001 1.283 1.056 1.144 0.554 5 1.137 1.354 1.033 1.284 1.005 0.987 0.965 0.388 6 1.312 1.082 1.339 1.053 0.974 0.966 0.470 7 1.098 1.090 1.246 1.135 0.959 0.468 8 1.108 1.071 0.696 0.542 0.384 9 0.499 0.372 Maximum Max Loc Minimum Min Loc 1.354 ( 2, 5) 0.372 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative Second Uprate Cycle Radial Power Distribution (EOC - 12360 EFPH)

• • ANC 8.10.5 ** REF BU= 17990. REF TIME= 12360.1 DATE: 05/06/08 USER: rnorring JOB: anc nw JOB NUMBER: 6153 MACHINE: HP-UX - jbxsa306 12360 EFPH CASE-0017 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.962 1.263 1.047 1.276 1.088 1.285 1.092 1.151 0.562 2 1.263 0.979 1.266 0.993 1.284 1.065 1.084 1.093 0.430 3 1.047 1.268 0.982 1.256 1.005 1.305 1.255 0.749 4 1.276 0.995 1.257 0.980 1.257 1.061 1.190 0.621 5 1.088 1.283 1.009 1.257 1.016 1.013 1.010 0.443 6 1.285 1.053 1.303 1.061 1.000 1.003 0.517 7 1.092 1.083 1.251 1.185 1.007 0.516 8 1.151 1.091 0.744 0.606 0.440 9 0.561 0.423 Maximum Max Loc Minimum Min Loc 1.305 (3, 6) 0.423 (9, 2)

E-END

Attachment 2 L-2010-278 Representative Second Uprate Cycle Axial Power Distribution BOC MOC EOC (100 EFPH (7000 EFPH) (12360 EFPH)

HEIGHT POWER POWER POWER ROW (cm) (RPF) (RPF) (RPF) 24 341.56 0.435 0.43 0.525 23 328.15 0.781 0.734 0.856 22 315.01 0.897 0.866 0.994 21 300.24 0.989 0.959 1.053 20 285.46 1.045 1.012 1.062 19 270.68 1.081 1.043 1.054 18 255.9 1.106 1.063 1.043 17 241.12 1.123 1.076 1.033 16 226.34 1.135 1.087 1.027 15 211.56 1.143 1.096 1.024 14 196.78 1.147 1.103 1.023 13 182 1.148 1.111 1.025 12 167.22 1.146 1.118 1.028 11 152.45 1.141 1.124 1.033 10 137.67 1.132 1.13 1.04 9 122.89 1.12 1.134 1.05 8 108.11 1.105 1.137 1.062 7 93.33 1.085 1.136 1.079 6 78.55 1.059 1.129 1.099 5 63.77 1.026 1.108 1.119 4 48.99 0.976 1.063 1.126 3 34.21 0.896 0.971 1.085 2 21.08 0.792 0.827 0.955 1 7.66 0.441 0.485 0.597

Attachment 2 L-2010-278 Representative Third Uprate Cycle Radial Power Distribution (BOC - 100 EFPH) 1 ** ANC 8.10.5 ** REF BU= 146. REF TIME= 100.0 DATE: 06/03/08 USER: rnorring JOB: anc nw N JOB NUMBER: 6439 MACHINE: HP-UX - jbxsa306 100 EFPH CASE-0002 PAGE-001 7 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.686 0.812 0.900 1.209 1.102 1.182 1.204 1.199 0.520 2 0.812 1.126 1.168 0.953 1.243 1.i11 1.170 1.180 0.381 3 0.900 1.173 0.924 1.176 0.949 1.262 1.263 0.746 4 1.209 0.957 1.182 0.949 1.268 1.166 1.199 0.564 5 1.102 1.248 0.953 1.269 1.168 1.191 1.099 0.403 6 1.182 1.120 1.266 1.168 1.187 1.162 0.544 7 1.204 1.174 1.263 1.199 1.098 0.543 8 1.199 1.176 0.743 0.564 0.403 9 0.519 0.380 Maximum Max Loc Minimum Min Loc 1.269 ( 5, 4) 0.380 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative Third Uprate Cycle Radial Power Distribution (MOC - 7000 EFPH)

• • ANC 8.10.5 ** REF BU= 10187. REF TIME= 7000.0 DATE: 06/03/08 USER: rnorring JOB: anc nwN JOB NUMBER: 6439 MACHINE: HP-UX - jbxsa306 7000 EFPH CASE-0011 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.827 0.946 1.006 1.359 1.133 1.312 1.093 1.141 0.505 2 0.946 1.347 1.346 1.020 1.337 1.100 1.070 1.081 0.376 3 1.006 1.349 1.006 1.282 0.981 1.345 1.290 0.716 4 1.359 1.021 1.286 0.960 1.258 1.074 1.195 0.565 5 1.133 1.340 0.984 1.259 1.013 0.988 0.981 0.392 6 1.312 1.106 1.347 1.076 0.986 0.965 0.471 7 1.093 1.073 1.290 1.195 0.981 0.471 8 1.141 1.079 0.714 0.566 0.392 9 0.505 0.375 Maximum Max Loc Minimum Min Loc 1.359 ( 1, 4) 0.375 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative Third Uprate Cycle Radial Power Distribution (EOC - 12360 EFPH)

• • ANC 8.10.5 ** REF BU= 17988. REF TIME= 12360.1 DATE: 06/03/08 USER: rnorring JOB: anc nwN JOB NUMBER: 6439 MACHINE: HP-UX - jbxsa306 12360 EFPH CASE-0017 PAGE-0017 C-POW AVERAGE ASSEMBLY POWER 1 2 3 4 5 6 7 8 9 1 0.852 0.949 0.993 1.286 1.097 1.294 1.077 1.134 0.552 2 0.949 1.280 1.302 1.012 1.299 1.079 1.051 1.076 0.418 3 0.993 1.303 1.012 1.286 0.998 1.304 1.235 0.740 4 1.286 1.013 1.287 0.992 1.270 1.071 1.174 0.604 5 1.097 1.300 0.999 1.270 1.039 1.014 1.005 0.434 6 1.294 1.082 1.304 1.072 1.012 1.004 0.517 7 1.077 1.052 1.235 1.174 1.005 0.517 8 1.134 1.075 0.738 0.604 0.434 9 0.552 0.417 Maximum Max Loc Minimum Min Loc 1.304 ( 6, 3) 0.417 ( 9, 2)

E-END

Attachment 2 L-2010-278 Representative Third Uprate Cycle Axial Power Distribution BOC MOC EOC (100 EFPH j7000 EFPH) (12360 EFPH)

HEIGHT POWER POWER POWER ROW (cm) (RPF) (RPF) (RPF) 24 341.61 0.422 0.43 0.526 23 328.2 0.759 0.736 0.858 22 315.06 0.874 0.873 0.996 21 300.28 0.966 0.97 1.053 20 285.5 1.025 1.024 1.062 19 270.72 1.064 1.054 1.053 18 255.93 1.093 1.072 1.042 17 241.15 1.114 1.083 1.032 16 226.37 1.13 1.091 1.026 15 211.59 1.142 1.097 1.023 14 196.81 1.149 1.102 1.022 13 182.03 1.154 1.106 1.024 12 167.25 1.154 1.111 1.027 11 152.47 1.151 1.116 1.032 10 137.69 1.145 1.121 1.039 9 122.9 1.135 1.126 1.049 8 108.12 1.12 1.13 1.061 7 93.34 1.101 1.131 1.078 6 78.56 1.075 1.125 1.098 5 63.78 1.039 1.108 1.119 4 49 0.987 1.064 1.127 3 34.22 0.904 0.971 1.088 2 21.08 0.797 0.822 0.959 1 7.67 0.443 0.48 0.6

Attachment 4 to L-2010-278 ATTACHMENT 4 AFFIDAVIT FOR WITHHOLDING Following 3 pages

AFFIDAVIT COMMONWEALTH OF VIRGINIA )

) ss.

CITY OF LYNCHBURG )

1. My name is Gayle F. Elliott. I am Manager, Product Licensing, for AREVA NP Inc. and as such I am authorized to execute this Affidavit.

2. I am familiar with the criteria applied by AREVA NP to determine whether certain AREVA NP information is proprietary. I am familiar with the policies established'by AREVA NP to ensure the proper application of these criteria.

3. I am familiar with the AREVA Document Number 38-9145099, Revision 000, entitled "St. Lucie Unit 2 K-Factors and Other General Results in EPU Power Conditions,"

dated June 2010 and referred to herein as "Document." Information contained in this Document has been classified by AREVA NP as proprietary in accordance with the policies established by AREVA NP for the control and protection of proprietary and confidential information.

4. This Document contains information of a proprietary and confidential nature and is of the type customarily held in confidence by AREVA NP and not made available to the public. Based on my experience, I am aware that other companies regard information of the kind contained in this Document as proprietary and confidential.

5. This Document has been made available to the U.S. Nuclear Regulatory Commission in confidence with the request that the information contained in this Document be withheld from public disclosure. The request for withholding of proprietary information is made in accordance with 10 CFR 2.390. The information for which withholding from disclosure is

requested qualifies under 10 CFR 2.390(a)(4) "Trade secrets and commercial or financial information."

6. The following criteria are customarily applied by AREVA NP to determine whether information should be classified as proprietary:

(a) The information reveals details of AREVA NP's research and development plans and programs or their results.

(b) Use of the information by a competitor would permit the competitor to significantly reduce its expenditures, in time or resources, to design, produce, or market a similar product or service.

(c) The information includes test data or analytical techniques concerning a process, methodology, or component, the application of which results in a competitive advantage for AREVA NP.

(d) The information reveals certain distinguishing aspects of a process, methodology, or component, the exclusive use of which provides a competitive advantage for AREVA NP in product optimization or marketability.

(e) The information is vital to a competitive advantage held by AREVA NP, would be helpful to competitors to AREVA NP, and would likely cause substantial harm to the competitive position of AREVA NP.

The information in the Document is considered proprietary for the reasons set forth in paragraphs 6(b), 6(c) and 6(e) above.

7. In accordance with AREVA NP's policies governing the protection and control of information, proprietary information contained in this Document have been made available, on a limited basis, to others outside AREVA NP only as required and under suitable agreement providing for nondisclosure and limited use of the information.

8. AREVA NP policy requires that proprietary information be kept in a secured file or area and distributed on a need-to-know basis.

9. The foregoing statements are true and correct to the best of my knowledge, information, and belief.

SUBSCRIBI before me this day of.N:

Kathleen Ann Bennett NOTARY PUBLIC, COMMONWEALTH OF VIRGINIA MY COMMISSION EXPIRES: 8/31/11 Reg. # 110864 slow w *mmm*mm,,*...-.