{{#Wiki_filter:CC-AA-309-1001 Revision 3 ATTACHMENT I Design Analysis Major RevIimon Cover Sh-eer Design Analysis (Major Revision)Analysis No.: I S-C-SF-MDC-1810 Title: 3 Decay Heat-up Rates and Curves ECJECR No.: 4  80091615 M01RO Station(s):

13 Last Page No. 6 Attachment 5 page 1 of 1 Revision:

16 Yes [] No [ If yes, see SY-AA-101-106 Does this Design Analysis contain Unverified Assumptions?

17 Yes El No Z If yes, ATI/AR#This Design Analysis SUPERCEDES:

19 The purpose of this calculation is to provide heat-up times, temperatures and curves for the Salem Generating Station (SGS) Unit I Spent Fuel Pool (SFP) for Refueling Outage IRI 8, as directed by Reference 4.7. The calculation is being revised to analyze the spent fuel pool temperature as a result of additional spent fuel transferred to the pool during the upcoming refueling outage.Affected pages -See page revision index on page 2.'--e'04AJ)-

25 N/A N/A N/A Print Name Sign Name Date Independent 3 Party Review Reqd?2 6  Yes[:I No Exelon Approver:

2 7  Alan Johnson L S t)Print Name -Sign Name Date (NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 1) CALCULATION COVER SHEET Page Ia of 12 CALCULATION NUMBER: S-C-SF-MDC-1810 REVISION:

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 REVISION HISTORY Revision Issue Date Revision Description 0 4/6/99 Initial Issue.1 1/20/00 Revision 1 provides heat-up times for the Unit 1 Fuel Pool as of 12/31/99 to support heat exchanger service and valve repairs to provide realistic heat-up times based on the present conditions of the Fuel Pool.2 3/2/01 The calculation is being revised to analyze the spent fuel pool temperature as a result of additional spent fuel transferred to the pool during the upcoming refueling outage.3 9/6/02 The calculation is being revised to analyze the spent fuel pool temperature as a result of additional spent fuel transferred to the pool during the upcoming refueling outage.4 10/2/02 The calculation is being revised to provide additional heat-up curves for Component Cooling (CC) temperatures of 70°F and 75 0 F, to better represent expected CC temperatures during the upcoming 1 R1 5 refueling outage. This is to support LCR S02-03 to revise the minimum time from shutdown before fuel offload can begin from 168 hours to 100 hours.5 2/24/04 The calculation is being revised to analyze the spent fuel pool temperature as a result of additional spent fuel transferred to the pool during the upcoming refueling outage.6 9/8/05 The calculation is being revised to analyze the spent fuel pool temperature as a result of additional spent fuel transferred to the pool during the upcoming refueling outage.7 See cover The calculation is being revised to analyze the spent fuel pool temperature as a sheet result of additional spent fuel transferred to the pool during the upcoming 1 R1 8 refueling outage.PAGE REVISION INDEX PAGE REV PAGE REV PAGE REV PAGE REV 1 7 Attachment 1 7 la 7 Attachment 2 7 2 7 Attachment 3 7 3 7 Attachment 4 7 4 7 Attachment 5 7 5 7 6 7 7 7 8 7 9 7 10 7 1 11 7 12 7 (NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 3 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

6 5.3 SFP Inventory Data Files ............................................................................................

==6.0 CONCLUSION==

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10 7.0 IMPACT TO STATION PROCEDURES:  

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12 8.0 DOCUMENTS AFFECTED:  

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12 9.0 DESIGN MARGIN: ...................................................................................................................

12 10.0 CROSS  

12 ATTACHMENT 1 -1R18 Schedule-"Executive Summary" ATTACHMENT 2 -Nuclear Fuels Letter NF0600209 "Salem 1 RFO18 Assembly Burnup Data for SFP Heat Load Analyses, Rev 0" ATTACHMENT 3 -SFP Heat-up Curves ATTACHMENT 4 -CROSSTIE Input and Output Files (Electronic files on CD)ATTACHMENT 5 -Salem Verification of Decay Heat Removal for Core Off-load (NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 4 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

DATE: REVIEWER:

DATE: VERIFIER:

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 1.0 PURPOSE The purpose of this calculation is to provide heat-up times, temperatures and curves for the Salem Generating Station (SGS) Unit 1 Spent Fuel Pool (SFP) for Refueling Outage 1 R1 8, as directed by Reference 4.7.2.0 SCOPE This calculation is being performed for the SFP Cooling System for SGS Unit 1. The following cases are analyzed: Case 1: Crosstie Operation with one SFHX unavailable Case 2: Normal SFP cooling with no crosstie operation Case 3: Loss of SFP cooling in Unit 1 Case 4: Loss of SFP cooling in Unit 1 -Post Outage 3.0 ASSUMPTIONS

/ INPUTS / CONDITIONS 3.1 The computer program CROSSTIE is used in this analysis to predict the SFP temperatures (when the unit 1 or unit 2 heat exchanger is out of service) and to evaluate the SFP heat-up rates and equilibrium temperatures without forced cooling. The CROSSTIE program is critical software as defined by ND.DE-AP.ZZ-0052(Q), designated CROSSTIE, Reference 4.1.3.2 The Crosstie program does not use the first two digits of the year to specify the date (i.e., 1980 uses"80", 1995 uses "95"). In order to manipulate the program such that a "delta time" from initial spent fuel discharge through 1R18 discharge could be determined, year 2000 is represented as year"100", and years following are represented sequentially from "100". This format for the year is changed in the input files, and ".dcy" files that document spent fuel discharged to the SFP.3.3 The Fuel Handling Building (FHB) ambient temperature is assumed to be the design value of 105 0 F (Reference 4.4, Section 9.4.3.1) for the "bounding" cases, and the estimated ambient temperature during the outage time period of 75 0 F for the "best estimate" cases. The FHB humidity is assumed to be the design value of 100% (Reference 4.4, Section 9.4.3.1).

To maintain an ambient temperature of 105 0 F with the SFP temperature over 150°F, the Fuel Handling Ventilation (FHV)system must be operating.

The basis for this assumption was analyzed in Reference 4.6, Attachment 8.3.4 The Component Cooling (CC) supply temperature is assumed to be the maximum procedural limit of 99 0 F for the "bounding" cases, and the estimated values of 70°F, 75 0 F, and 80°F during the outage time period for the "best estimate" cases.3.5 The net water volume (55896 ft 3) includes the SFP and transfer pool volumes (minus the volume displaced by the fuel assemblies and racks, see Section 5.4). The volume is assumed to be that for Unit 1, since this is the Unit of concern (CROSSTIE automatically applies the water volume to both unit pools). The net volume is valid for Refueling Outage (1R18) only, as the volume displaced by the fuel assemblies is dependent on the total number of fuel assemblies in the SFP. The post outage volume will be slightly greater due to the two-thirds core fuel assemblies being reloaded into the vessel. However, the difference would have a minor impact on the heat-up rate, and will conservatively be ignored.3.6 The surface area of the SFP water volume includes the surface area of the transfer pool in the program code.3.7 Service Water (SW) temperatures determine CC temperatures.

For conservatism, the difference between the CC and SW temperatures is assumed to be 9 0 F as determined in Reference 4.10, which is based on a higher SFP heat load. It is also assumed that only one CCHX is available, and there is no parallel SFHX operation (i.e., the Unit 1 SFP is not aligned to both SFHXs). Therefore, the corresponding SW temperatures for CC temperatures of 70°F, 75 0 F, 80°F and 99 0 F, are 61°F, 66 0 F, 71OF and 90°F respectively.

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 3.8 The Technical Specification states that fuel cannot be moved for a minimum of 100 hours from October 15 through May 15 through the year 2010 (Reference 4.3 Section 3.9.3). Since core offload begins on April 1, the core offload start of 121 hours (as stated in the current schedule included as Attachment

: 1) is acceptable.

3.9 The duration of core offload is assumed to be the current schedule of 41 hours (see Attachment 1).3.10 The core reload is scheduled to start 116 hours after the offload is completed, and be completed in 45 hours (see Attachment 1).3.11 Crosstie operation, with one SFHX unavailable, is assumed to begin immediately after core offload is completed.

A nominal minimum value of 1 hour after core offload is used for the analysis.3.12 The CC flow to the SF Heat Exchanger (SFHX) is assumed to be the design value of 3000 gpm (Reference 4.9).3.13 The SF flow to the SFHX is assumed to be 2500 gpm (Reference 4.2).3.14 The current scheduled reactor shutdown date and time for Unit 1 is 3/27/07 at 2000 hours (see Attachment 1). However, for the Crosstie "Rfile" Reactor shutdown date as stated in Section 5.5 Line 2, a shutdown date and time of 3/28/07 at 0000 hours will be used.3.15 The current SFP inventory (i.e., pre-offload) for Units 1 and 2 are contained in files "Unit1 .dcy" and"Unit2.dcy" for Units 1 and 2, respectively.

-fuel assembly burnups and average assembly Uranium weight -are included in Attachment 2.3.17 The SFP cooling system maintains pool temperature at or below 1491F provided one SFP heat exchanger is available for each pool, and at 180°F if only one hx is available between both pools (Reference 4.4, Section 9.1.3.2).

These design base limits are used as acceptance criteria in the model.3.18 There are -1137 fuel assemblies in the Salem Unit 1 SFP prior to the start of the 1 R1 8 outage (per Salem Reactor Engineering and Reference 4.12), and is used to calculate the SFP net water volume after core offload. The actual number may vary slightly, but would not impact the calculation results.3.19 The Core Rated Thermal Power has been increased from 3411 MWt to 3459 MWt (due to the 1.4%power uprate) per Reference 4.3 Section 1.25. This new value applies to all fuel assemblies transferred to the SFP after June 2001 (for both Units 1 & 2), and is conservative for the fuel assemblies that have been radiated at both power levels.

==4.0 REFERENCES==

4.1 Critical Software, S-C-SF-MCS-0113, "CROSSTIE" A. Sheet 1, Critical Software Document, Revision 1 B. Sheet 1, Software Media, Revision 0 4.2 Calculation S-C-SF-MDC-1 780, "Capability Of Salem SPENT Fuel Pool Heat Exchanger To Maintain 1491F Pool Temperature", Revision 0 4.3 Salem Technical Specifications 4.4 Salem Updated Final Safety Analysis Report (UFSAR)4.5 Vendor Document, 316748, "Pool Layout -(Region I & II) for Spent Fuel Pool Storage Racks, Revision 1 4.6 Calculation S-1-FHV-MDC-0705, "FHV Sys Htg/Clg Load and Airflow Determination Calcs Unit 1", Revision 4 4.7 Administrative Procedure SC.OM-AP.ZZ-0001 (Q), "Shutdown Safety Management Program -Salem Annex", Revision 1 4.8 Engineering Evaluation S-C-SF-MEE-1 302, "Evaluation to Determine the Equilibrium Temperature for the SFP Without Forced Cooling", Revision 0 4.9 Westinghouse's Letter PSE-89-744 (11/8/89) to M. F. Metcalf (PSE&G), "Salem CCW Calculation Summaries" 4.10 Engineering Evaluation S-C-SF-MEE-1 679, "Spent Fuel Pool Cooling System Capability with Core Offload Starting 100 Hours After Shutdown", Revision 1 4.11 Exelon Procedure OU-AA-103, "Shutdown Safety Management Program", Revision 6 4.12 Nuclear Fuels Calculation DN2.6-0018, "Salem 2 Scoping Study", dated 5/17/2005 4.13 Alarm Response Procedure, S2.OP-AR.ZZ-0003, "Overhead Annunciators Window C, Alarm C-1 9", Rev. 13 (NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 6 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 5.0 ANALYSIS 5.1 Methodology The purpose .of this calculation is to provide heat-up times, temperatures and curves for the SGS Unit 1 Refueling Outage #18 (1R18). This analysis is required by Reference 4.7. The calculation is performed using Holtec's computer program CROSSTIE (Reference 4.1), for the following cases: Case 1: Crosstie Operation with one SFHX unavailable (see note 1)Case 2: Normal SFP cooling with no crosstie operation Case 3: Loss of SFP cooling in Unit 1 (see note 2)Case 4: Loss of SFP cooling in Unit 1 -Post-Outage Note I Removing a SFHX from service is a manual action, and would never be scheduled during or following a core offload. The one exception where this could occur is a tube leak in one of the SFHXs, and would be a management decision.

(NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 8 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

Line 2: Reactor shutdown date.* Cases 1 & 2: 3/28/07 (Actual shutdown @ 20:00 on 3/27/07; rounded forward to next day)* Case 3: 4/3/07 (Actual shutdown @ 20:00 on 3/27/07; rounded forward to next day)* Case 4: 5/1/07, 6/1/07, 7/1/07, 8/1/07, then quarterly beginning on 9/1/07 through 9/1/08 Note: For loss of cooling (case 3), this is actually the start date of Crosstie run. The total elapsed time is just 6 days and 18 hours; however, Crosstie cannot model time into the shutdown date, and an elapsed time of 6 days will conservatively be used.Line 3: Unit in outage.* Cases1&2:

(NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 9 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

DATE: REVIEWER:

DATE: VERIFIER:

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 3 rd, 4 th & 5 th #'s: Average burnups for 3 batches in line 4 -51109, 45234, 24740 (based on Attachment 2)6 th #: Average uranium weight -456.3 (Attachment 2)The input lines, then, are:* Cases 1 & 2: 3459,1.0,51109,45234,24740,456.3

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 5.8 Run the Crosstie Program The model was run for the following scenarios.

The output files "result.tem", "unit1 .htl" and "plot.dat" are included as electronic files on CD in Attachment 4 (bounding and best estimate sub-cases).

Case 1: Crosstie Operation with one SFHX unavailable Case 2: Normal SFP cooling with no crosstie operation Case 3: Loss of SFP cooling in Unit 1 Case 4: Loss of SFP cooling in Unit 1 -Post-outage 5.9 Import the Output Files The PLOT.DAT file for each unit was imported into EXCEL, and a temperature vs. time graph was plotted for each unit. The graphs can be found in the Attachment 3.

==6.0 CONCLUSION==

S The Unit 1 SFP analysis for 1 R1 8 was performed for the following cases, with one heat exchanger available and Crosstie swapover at 180°F: Case 1 -Crosstie Operation Case 2 -Normal SFP Cooling to Unit 1 Case 3 -Loss of Unit 1 SFP Cooling Case 4 -Loss of Unit 1 SFP Cooling -Post Outage For each of these cases, a bounding case with design inputs and best estimate cases based on estimated input parameters for the current 1 R1 8 schedule were run. All cases were run with CC supply temperatures of 99°F and 80°F, which correlate to maximum SW temperatures of 90°F and 71'F, respectively.

Cases 2 and 3 were also run with CC supply temperatures of 75°F and 700F1, which correlate to maximum SW temperatures of 66 0 F and 61°F, respectively.

Plots showing "SFP temperature vs time" for each case are included in Attachment

: 3. A summary of the results is as follows: Case 1: For crosstie operation with the Unit 1 SFP aligned to the Unit 2 SFHX, a summary of the results is included in the table below. Bounding:

The isolated Unit 2 peak SFP temperature hits the licensing basis limit of 180'F with one SFHX isolated, and swapping of SFPs is required.

Best Estimate:

The isolated Unit 2 peak SFP temperature is below the licensing basis limit of 180'F with one SFHX isolated, and thus no swapping of SFPs is required.

In addition, the time at which the peak temperature is reached is after the scheduled core reload, by which time crosstie operation would most likely have been suspended and normal cooling restored.Case Unit Offload- Hx in Peak Temp (OF) Time to reach (hr) Heatup (°F/hr)Start (hr) Service 99 80 99 80 99 80 1 1 121 yes 180 135 4 (1) 50(2) 7.8 1.2 1 2 121 no 180 178 60_M 140 k77 1.2 1.3 (1 Time from Crosstie swapover (2) Time from "start of off-load" The new CC temperature cases of 75°F and 70'F were not performed for Case 1, since the results for the previously performed temperature cases indicate the Unit 2 SFP never reaches 180'F. Thus no swapover between the SFPs occurs, and the Case 1 results for the Unit 1 SFP are the same as for Case 2. The new CC temperature cases of 75°F and 70°F were not performed for Case 4 since these are post-outage cases with low heat load conditions; also, the CC temperature would likely be set between 80'F and 99°F.

(NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 11 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

DATE: REVIEWER:

DATE: VERIFIER:

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 Case 2: A summary of the results is included in the table below. For normal SFP cooling, the licensing basis limit of 149 0 F is exceeded for the bounding case with 99°F CC temperature.

However, interpolating between the 80°F CC temperature case and bounding case results, a peak SFP temperature of 149°F is reached with a CC temperature of about 94 0 F, correlating to a maximum SW temperature of 85 0 F. Since this will be higher than the SW temperature at the time of core offload, the SFP temperature limit of 149 0 F will not be exceeded.Case Offload Peak Temp (OF) Time to 125 0 F (hr)* Heatup (°F/hr)Start (hr) 99 80 75 70 99 80 75 70 99 80 75 70 2 121 154 135 131 126 20.5 36.1 40.3 47.4 1.2 1.2 1.2 1.2*Time from "start of off-load" Also, through linear interpolation of the results, the SFP high temperature alarm setpoint of 125°F will be reached with a CC temperature of 69°F for an offload start time of 121 hours. Alarm Response Procedure S2.OP-AR.ZZ-0003 allows the setpoint to be increased to allow refueling activities to continue.

Temporary alarm setpoints as a function of CC temperature, if required, are provided in the table below. The setpoints are set to a value 5 0 F higher than the calculated peak SFP temperature.

This accounts for a 2.5 0 F instrument uncertainty (Reference SAP ICD screen for FLOC S2SF -2TIC651) plus provides a 2.5 0 F margin above the peak temperature." CC temperature (F) Alarm Setpoint (OF)80 140 75 136 70 131 Case 3: A summary of the results is included in the table below. On a loss of cooling to the Unit 1 SFP, the maximum design limit of 180'F will be reached in a range of 2.2 hours to 4.9 hours after core offload is complete.

This is the time operators have to take contingency actions to re-establish forced cooling. The Unit 1 SFP will not boil if cooling is not restored.Case Offload Peak Temp (OF) Time to reach 180°F (hr)* Heatup (°F/hr)Start (hr) 99 80 75 70 99 180 75 70 99 80 75 70 3 121 205 205 205 205 2.2 4.0 4.5 4.9 9.4 9.9 10.0 10.1*Time from "loss of cooling" after core offload complete Case 4: Heat-up rates in the event of Unit 1 SFP loss of cooling post-outage.

See curves for details.Case 5: Maximum CC/SW Temperatures for 100-hr Limiting Core Offload The maximum river temperature is based on a maximum CC supply temperature, to ensure that the SFP will not exceed the licensing basis limit of 149 0 F. For the Tech Spec minimum offload start time of 100 hours, the maximum SW and CC temperatures are 82°F and 91°F, respectively (see Attachment 5).

(NC.DE-AP.ZZ-0002(Q), Rev. 11, Form 2) CALCULATION CONTINUATION SHEET SHEET: 12 of 12 CALC NO.: S-C-SF-MDC-1810 REV: 7 REF: CONT'D ON SHEET: ORIGINATOR:

DATE: REVIEWER:

DATE: VERIFIER:

DATE: R. Down 2/21/07 K. King 2/22/07 K. King 2/22/07 7.0 IMPACT TO STATION PROCEDURES:

None 8.0 DOCUMENTS AFFECTED: None 9.0 DESIGN MARGIN: This calculation is used to determine heat-up rates for the SFP during refueling outages. It provides a planning tool for the Central Outage Group (COG) and Operations to plan fuel moves to ensure SFP temperature are manageable, and allows contingency planning in the event that a pump and/or heat exchanger is lost. Design margin is not applicable to this calculation.

10.0 CROSS  

Cross-References  

-Critical Software S-C-SF-MCS-01 13 and Design calculation S-C-SF-MDC-1 780 were used as input for development of this calculation.

There are no output documents resulting from this calculation.

ActIft Oriq Total Early Early ID Dur Float? Start Finish 2007 MIARAP l.fl~l9~MkATMf`YaA0W 126 i 12 19 116 123 0 fe o 2N;U 2D aqO1f-"P-TRIPRREAC-TORP&_TURBINE

" PROCEDURE HOLE 4j-(AME DDE:R D 01 IN7 7, /."' ,-/7;0Q SDA/U-OLD&#xfd;&#xfd;R&#xfd;P 72 2 0 27An 0 2nv2DM&#xfd;154PF71559 DL J-E-,- 77, Tt-//7/2'/7 0 27MWRJ2DOj 1911FR7 1751 I ~ II ~ lED W~ I U I '~H-SIAM 3' 1 27M&#xfd;21W 2nVN?7M3i5RJ SD-&TS~D 10 34 21772ffl 01APR07015 RHtEvMcE4 2&#xfd; 0 A~~72ff2vKtJU7O1S ACDPEDJE 26 0 2%4D 9A O H-PI1-VD 411t 2 Zl&#xb6;R&#xfd;=X 144PR;U7 C5$~E~20 0 *W~J0159 H19YAXE5 -7D1 21 MMV MXJc 3144RJ723S HAUDECFS 78* 14 J~aMN;0=L 31M'*RJ7075 l-HlDEM&#xfd; 2' 31 4J)77f 31M14RJ72159 EV60 87 vAJE a~n~o~~( Z~ 9 AV&#xfd;4&#xfd;173M 29V'I4R72159 HFO0XORJD 4?* 24 Mv&#xb6;RJ72303 3CMv1RJ72 HPRXDGASS 29 2 31vlRI717D0 31M4V~21-T SAVLUXP1 0 2 3UVFU2D0 I MODE 3 TO MODE 4 -SHU"_ _ TECH SPEC HC 1 MODE 4 TO MODE 5 -SHU" f- ENTER RCS ACID REDU OFRCS* ENTER MODE 5 DESCENE_MODE 5 to 6 -Rx I_ HAMMOCK FOR M.MODE 5 TO HE)CONDENSER VACUUM BF SMGSF IDOC j CRUD BURST WINDO FORCED OXIDATI-REACTOR DISA z STA RT DRAINEE* ENTER MODE 6 1 W/IN JN~0 F CC 0'7/Ijlf W lo\7-////i.7/7/,-iRr 31-1 PF At"//,X/,i..i;/b TAL OUTAGE DURATION -PRIMARY PU OPENTO HEAT UPTO MODE4 TOTAL OUTAGE DURATION Sp?Y SYSTEMS WORK WINDOW -INCL. Fl d)-=T &#xfd;E777///7"I 7,7;/7/I/1N 7,7z SE (R):em ANI 7/IAL'-MC BL)11IDL ENE V/1<=C)EL cJhON;I"'', M1C K, Ir , PS)NED TAND......... ...... ..........  

........ ..0 31M 70303 HESYMOcE 45 15 31MNW (000 COAPR)71)39 H-SvDM3E W 73 31 mA7 0)3NW113PF 9 13/SMODE OR O l 0 231MAR17 165 FINISH DRAINE MI Fxfl41 11 oH210 03I4F713,9

..L R SUNLOA RE. .Start Date 03DEC06 00:00 Early1Bar 800 Sheet1 oIf 10 L2- LEVEL 2 WINDOW SCHEDULE Finish Date 31 MAY07 18:59 EG NUCLEAR LLC -SALEM Shaded Areas: Data Date 25MAR07 00:00 Progress Bar 1st area -Midloop LEVEL 2 SCHEDULE 2nd area -Core Offload Run Date 21NOV06 08:18 Critical Activity 3rd area -Core Reload&#xa9; Primavera Systems, Inc. 4th area -Midloop/Y1 /9/0 Re V 7/81t:37 -rev' c7 /ArT-, -~, 7 ~

ID Orig Total Dur Float Early Start Early Finish 2007 MAR APR.12f 12'9 A16 112'3 41*1 1W07 1AQ&#xb6;&#xfd;U210 03APF&#xb6;UI359 HDHU=E 116' 133 03PRO7 14D ORAPFV07959 StL,13D 0 9&#xfd; OB4PF7 100D H-FS3AD 451 21 M*W~ 100M 10AF1P 70315 RX-034 45 ZD cMtPRY 1003 1BAPR37C0E5 R&#xfd;SJMDDE 11t 22 tAFU7 10.00 134FZ7 D5 H-EFE#6' 1AR97 07ff0 124j4U 703-, H-CRTVWDO 5? 36 1OAFRJ 0703 12APW 1059 H4R~WD~12 104PR77 0700 134PFU7 ODJ5 H-REFUEL-5 83 22 10APV(7f070 134PFUW593 4VESSE W 27 12ARDJ71l03 13'NRFJ77D5 1-4-IIXNTcM4 77' 0 12APR;07 1100 15NDFU 1559 S-1VIDLXOP2 0 2 134PF07=00 SLMXDE5 0 22 134PFJ7 0103 HMD5TCFV 0t 13 136PFW-0100 14AR071703 H-MX5T0R 41* 13 136PFR70IJ00 14APFU7 17039 HSJK4vDE5 63' 0 13PRI70103 15W.U711503 SLWc 0 2 48RI 10 CORE 0. A[/7'7/////'/7/AMI LE OF ER DO/r7r-'.TO CORE RELOADED -HAMMOCK SDING z START DRAINED TO MIDLOOP.. .... ... ...... .........

.. ..... .....<7///////6/7-7<7/7t'7,/6/ll/7/77///~6'7/.//7;72j//4 7 77//77/7'7>7/'7.7;7/'/6.7;7</7 9</4/6/'77/*MOCK MODE 5 ASCENDING REFUEL WINDO HEAD ON VESSEL ADED TO HEAD ON VESSEL WINDOW REASSEMBLY to MODE 5 (Rx Hd Tens TO MODE S -HAMMOCK fESSEL TO MODE 5 ON VESSEL TOI MODE 4 WINDOW ODE 5 ASCENDING 5 TO RCS FILL & VENT COMPLETE 5 TO 13 RCP STARTED WINDOW ENSER VACUUM ESTABUSHED PTO MODE 4 MODE5 7 0 MODE 4 AX HH-l-UvY4 15 1 144PR1714M0 154PF)71559 i 6 I 0 37 ~144FRJ71503 I-IHTCPTO 4 z 0 1wolaw 80 15*WJ71503 H-l4LPtODE4 Zr 15 114PFU71&U 154PU7 1553 EV70 0 154PFU7150 I-{SJME4 15' 0 15NFR37 1603 1&'PFW5&sect;030 H-STARRPF3 e' 0 154PR)71603 198PFU7 1703 ling 3 Ifu/A FUF RT H/U TO MODE 4 WINDOW RCP STARTED TO MODE 4 WINDOW J TO MODE 4 -HAMMOCK NTER MODE 4 ASCENDING MODE 4 TO MODE 3 MODE thru SYNCH ENTER MODE 3 ASCENDING NEV18 0 0 16J&%D 07JOD I I f f f f fl .. ..-,c- I &#xfd; / 8 /0 kle 7 h~2fu A77A C/V ,!5,U -T / //?a-y e 2 f -pz NUCLEAR FUELS TRANSMITTAL OF DES-SGN INFOR--MATON 0 SAFETY RELATED Originating Organization NF ID# NF0600209 E] NON-SAFETY RELATED [ Nuclear Fuels Revision 0 17 REGULATORY RELATED El Other (specify)

Page 1 of 6 Station: Salem Unit: 1 Cycle: 19 Generic: To: Alan Johnson (Design Engineering Supervisor)

Salem 1 RFO1 8 Assembly Burnup Data for SFP Heat Load Analyses, Rev 0 Joe Dascanio 8/2/06 Prepared by (igna(re Date Keith Robinson 8/2/06 Reviewed by Signature Date Bob Tsai Aw-) 812/06~ (W ~ ~ ~ 4 Approved by Signature Date Status of Information:

[ Verfied El Unverified C] Engineering Judgement Action Tracking # for Method and Schedule of Verification for Unverified DESIGN INFORMATION:

The atta.c.hed data is being provided as requested input into the CROSSTIE computer code (or equivalent) used in performing decay heat analyses.Description of Information:

The data Is based upon a conservative EOCI8 bumup assumption of 19,900 MWD/MTU. That bumup covers a capacity factor of over 100% from 08/01/2006 to the start of the IR18 refueling outage on 3/27/2007.

The following pages contain the assembly identifiers (IDs), projected assembly burnups at EOC1 8, the assemblies to be discharged to the spent fuel pool at EOC1 8, and the assemblies to be reinserted into Cycle 19 from the spent fuel pool. In addition, the total core loading and core average assembly loading are provided.Source of Information:

Westinghouse Letter, NF-PSE-06-34, "Salem Unit 1 Core Follow Models for The Cycle 19 Design," July 5, 2005.Output File: 12slci8 ancqcjrev.3837.out Supplemental Distribution:

EM-0l: Hard Cop R. Down Salem Records Management I-) &#xfd;v/9r-rc ,f116A-,'(5 7- 2-y e/ oIQ&#xfd; NUCLEAR FUELS TRANSMITTAL OF DESIGN INFORMATION NF0600209, Revision 0 Page 2 of 6 Assumed Capacity Factor of 100% from 08/01/06 to 3/27/07.Total Core Loading = 88.058 MTU. Therefore, Core Average Assembly Loading is 456.3 KgU/Assembly.

The following is the list of Cycle 18 assembly identifiers (total of 193), their corresponding EOC18 projected assembly burnups in units of MWD/MTU, and the assemblies discharged to the SFP at E0C18, where EOC18 = 19,900 MWD/MTU.Assembly ID AF01 AF02 AF03 AF04 AF05 AF06 AF07 AF08 AF10 AF1 1 AF12 AF17 AF1 8 AF1 9 AF20 AF21 AF24 AF25 AF26 AF27 AF28 AF31 AF32 AF33 AF39 AF41 AF47 AF50 AF51 AF52 AF54 AF56 AF57 AF58 AF59 AF60 AF61 AF62 AF63 EOC18 Assembly Burnup (MWD/MTU)44799 44773 44773 44799 44799 44773 44773 44799 51035 50304 50844 50391 50844 51035 50304 51035 52638 50391 52638 50844 50381 50844 50391 51035 50391 50381 52638 50381 50304 50381 52638 50304 52588 52464 52464 52588 52588 52464 52464 Assemblies Discharged to SFP x x x x X*x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x X S-C--F -I),)bc- /9/0 S~c<F,~1bC

/8/0,eev -7 /9 Tq-?67-&#xfd;q Z 2'q , -

NUCLEAR FUELS TRANSMITTAL OF DESIGN INFORMATION NF0600209, Revision 0 Page 3 of 6 Assembly ID AF64 AF65 AF66 AF67 AF68 AF69 AF70 AF71 AF72 AGO1 AG02 AG03 AG04 AG05 AGO6 AG07 AGO8 AG09 AG10 AG11 AG12 AG13 AG14 AG15 AG16 AG17 AG18 AG19 AG20 AG21 AG22 AG23 AG24 AG25 AG26 AG27 AG28 AG29 AG30 AG31 AG32 AG33 AG34 AG35 AG36 AG37 AG38 AG39.EOC18 Assembly BurnuD (MWD/MTU)52588 51714 54741 54741 51714 51714 54741 54741 51714 47296 47296 46867 48756 46826 46867 48756 46826 47296 46826-48756 47304 47304 48756 47304 46867 47304 46867 46826 47296 43511 43496 43496 43511 43511 43496 43496 43511 45038 44096 45118 45118 44044 45038 44096 44096 44096 44044 45118 Assemblies Discharged to SFP x x x x x x x x x x x x x x x x x x x x x x x x x x x x x-sp-MiDc- /8 /0 W,5v '~v'7 I~TT,9C,141L~>J7 Z 3 ~y2 ~

NUCLEAR FUELS NF0600209, Revision 0 TRANSMITTAL OF DESIGN INFORMATION Page 4 of 6 EOC18 Assemblies Assembly Discharged Assembly ID Burnup (MWD/MTU) to SFP AG40 45038 AG41 45118 AG42 44044 AG43 44044 AG44 45038 AG45 40739 AG46 46860 X AG47 46278 AG48 46278 AG49 45059 AG50 45059 AG51 46278 AG52 46870 X AG53 46860 X AG54 40739 AG55 40739 AG56 45059 AG57 46278 AG58 46870 X AG59 49280 X AG60 49280 X AG61 49280 X AG62 46860 X AG63 45059 AG64 46860 X AG65 49280 X AG66 49280 X AG67 49280 X AG68 49280 X AG69 49280 X AG70 40739 AG71 46870 X AG72 46870 X AH01 25030 AH02 26700 AH03 26319 AH04 26700 AH05 26319 AH06 26777 AH07 26706 AH08 26266 AH09 26282 AH10 26700 AH11 25180 AH12 26389 AH13 26700 AH14 25180 AH15 26266 S- ---/n;D d- / b, /0/Ls v '7 /q'7-/T, C /Y Z-?,4.AOY I "i NUCLEAR FUELS TRANSMITTAL OF DESIGN INFORMATION NF0600209, Revision 0 Page 5 of 6 Assembly ID AH16 AH17 AH18 AH19 AH20 AH21 AH22 AH23 AH24 AH25 AH26 AH27 AH28 AH29 AH30 AH31 AH32 AH33 AH34 AH35 AH36 AH37 AH38 AH39 AH40 AH41 AH42 AH43 AH44 AH45 AH46 AH47 AH48 AH49 AH50 AH51 AH52 AH53 AH54 AH55 AH56 AH57 AH58 AH59 AH60 AH61 AH62 AH63 EOC18 Assembly Burnup (MWD/MTU)26706 26706 26282 26389 26266 26389 26706 25180 26073 26266 25180 26073 26792 26777 26792 26389 26792 26073 26073 26777 26282 26282 26319 26792 26319 26777 20807 22669 20790 20790 22622 20807 22669 22669 22669 22622 20790 20807 20790 22622 22622 20807 23309 24062 24062 23309 24117 23309 Assemblies Discharged to SFP-S -be --/6 -7 A TT/q c H fl FIV 7 lo -7, NUCLEAR FUELS TRANSMITTAL OF DESIGN INFORMATION NF0600209, Revision 0 Page 6 of 6 Assembly ID AH64 AH65 AH66 AH67 AH68 AH69 AH70 AH71 AH72 AH73 EOC18 Assembly Burnup (MWD/MTU)23395 23395 24062 24117 23309 23395 24062 24117 24117 23395 Assemblies Discharged to SFP No Assemblies will be reinserted from the Spent Fuel Pool into Cycle 19.5 --C --5117' -In b C -/8 /0 pEv -7 A -1,- -/ -i /0--Y 4 " -4&#xfd; Attachment 3 page / of Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Unit I -Crosstie Operation Swapover at 180TF (CCW 3000 gpm, SF 2500 gpm)Plant Shutdown (3/27/07)

-20:00 hr, Offload Start -121 hr, Offload Complete -162 hr 200 180 160 CL 140 E I--U-120 100 80 60 4-100 150 200 250 300 350 400 450 time (hrs)500 Case 1a -Bounding Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Attachment 3 page I- of 11 Unit I -Crosstie Operation Swapover at 180&deg;F (CCW 3000 gprn, SF 2500 gpm)Plant Shutdown (3127107)  

-20:00 hr, Offload Start -121 hr, Offload Complete -162 hr 200D, a-unit 2 -SFP ambient air @7 &deg;F and 100% RH, 80F CCW ar~d 71F SW 180 -__160 _': 140 E U.-L 120.unit 1 -SFP mbient air@7 Fand 100% RH, 80F CCW and 71F SW 100 80 60 100 150 200 250 300 350 400 450 500 time (hrs)Case lb -Best estimate i 57;Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Attachment 3 page 3 of Unit I -Normal Cooling -No Crosstie (CCW 3000 gpm, SF 2500 gpm)Plant Shutdown (3/27107)

-20:00 hr, Offload Start -121 hr, Offload Complete -162 hr 160 150 140 130 ,, 120 E 110 a.LL-7 100 unit 1-SFP ambient ir @105F a nd 100% RV-I, 99F CCW and 90F SW unit 1- SFP ambient ai @75&deg;F an 2 100% RH, 80F COW and 71F SW unit 1 -SFI ambient aii @75&deg;F and 100% RH, 75F CCW and 66F SW unit 1 -SFI ambient ai&#xfd; @75&deg;F and 100% RH, 70F CCW a d 61F SW_ _1 90 80 70 60 0 50 100 150 200 250 time (hrs)300 350 400 450 500 Case 2 Design Calculation S-C-SF-MDC-1 810, Rev. 7 Final Attachment 3 page I of /5 Unit 1 -Loss of Cooling Based on 4/3107 Start Date at 00:00 hr -With Core Offloaded 210 I I I 200 1 unit 1- SFP ambient air @105'Fad 100%oRl 99FCCWand 90FSV\/V apd 10 R W I 1901-1/x 180 170 I--0.S160 150 140 130 unit 1 -SF ambient air @750F and unit 1 -SFP ambient ai 1 @75'F anc unit 1 -SEP ambient ai 1@75&deg;F and 100% RH, 100% RH, 100% RH, 80F CCW aj 75F CCW ai 70F CCW ai id 71F SW id 66F SW id 61F SW-j A-I---,' 4 4 I ____________________

___________________-f 4 -b 120 0.0 F- F- F- 4 -F F- F-0O 2.00 4.00 6.00 8.00 10.00 time (hrs)Case 3 12.00 14.00 16.00 18.00 20.00 Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Unit 1- Loss of Cooling Based on loss of cooling on 5/11/07 Attachment 3 page cf /5-0.E CL I-U.-1, 210 -200 190 180 170 160 150 140 130 120 110 100 90 80 0 10 20 30 40 50 time (hrs)60 case 4a Design Calculation S-C-SF-MDC-1 810, Rev. 7 Final Attachment 3 page&#xfd;f , S-Unit 1- Loss of Cooling Based on loss of cooling on 6/1/07 C.I-0..L-(n 210 200 190 180 170 160 150 140 130 120 110 100 90 80 0 10 20 30 40 50 60 70 time (hrs)80 case 4b

.Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Attachment 3 page 7 of I Unit 1- Loss of Cooling Based on loss of cooling on 7/1/07 E q-U-Cl)210 200 190 180 170 160 150 140 130 120 110 100 90 80 0 10 20 30 40 50 60 70 80 90 time (hrs)100 case 4c Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Attachment 3 page 8 of 15 Unit 1- Loss of Cooling Based on loss of cooling on 8/1/07 200 190 _180 _____170 _ _ _ _ _ ____160 h C. 150 /_ _ _ _E 105'F SFP ambient air @ 100% RH -99TF CCW C- 140 -CC-1 0...... 75TF SFP ambient air @ 100% RH -80TF CCW 7- 130 -_ _ __/120 ---_110 -, 100 --90" 80 , 2 i 4 0 10 20 30 40 50 60 70 80 90 100 time (hrs)case 4d Final Attachment 3 page 9 of 1.Design Calculation S-C-SF-MDC-1810, Rev. 7 Unit 1- Loss of Cooling Based on loss of cooling on 9/1/07 E (L1 U.200 190 180 170 160 15O 140 130 120 110 100 90 80 0 10 20 30 40 50 60 70 80 90 time (hrs)100 case 4e Attachment 3 page 10 of 1 Design Calculation S-C-SF-MDC-1810, Rev. 7 190 180 170 160 150 E 140 I--1.1 LL Cn 130 120 .110 100 /90 80 Final Unit 1- Loss of Cooling Based on loss of cooling on 12/1/07 0 20 40 60 80 100 time (hrs)120 case 4f I Final Attachment 3 page 11 of 1 :Design Calculation S-C-SF-MDC-1810, Rev. 7 Unit 1- Loss of Cooling Based on loss of cooling on 3/1/08 C.E a)U-U.190 180 170 160 150 140 130 120 110 100 90 80 0 20 40 60 80 100 120 time (hrs)140 case 4g I Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Attachment 3 page 12 of 15 Unit 1- Loss of Cooling Based on loss of cooling on 611/08 190 180 170 160 150 iZZ E 140 a.I-i 130 120 110 100 90 80 0 20 40 60 80 100 120 140 time (hrs)160 case 4h

,Design Calculation S-C-SF-MDC-1810, Rev. 7 Final Attachment 3 page 13 of 1 Unit 1- Loss of Cooling Based on loss of cooling on 9/1108 U-E I-.n LL.U,.75 CO 190 180 170 160 150 140 130 120 110 100 90 80 I -i- -.~////105TF SFP ambient air @ 100% RH -99TF CCW.75TF SFP ambient air @ 100% RH -80 0 F CCW t -1/1* I 0 20 40 60 80 time (hrs)100 120 140 160 case 4i Design Calculation S-C-SF-MDC-1 810, Rev. 7 Final Attachment 3 page 14 of Unit 1 -Normal Cooling -No Crosstie (CCW 3000 gpm, SF 2500 gpm)Plant Shutdown (3/27/07)  

-20:00 hr, Offload Start -100 hr, Offload Complete -141 hr 160-140 _130 _--- _._.___ ._______ -___ __G 120 -C. un t 1 -SFP ambient air @ 75&deg;F and 10 0% RH, 80F CCW and 1F SW E 110 IL U.S100 90 _80-70 _60 0.0 50.0 100.0 150.0 200.0 250.0 300.0 350.0 400.0 450.0 500.0 time (hrs)Case 5a -100-hr limiting Design Calculation S-C-SF-MDC-1 810, Rev. 7 Final Attachment 3 page 15 of 1 i Unit I -Normal Cooling -No Crosstie (CCW 3000 gpm, SF 2500 gpm)Plant Shutdown (3127107)  

-20:00 hr, Offload Start -100 hr, Offload Complete -141 hr 150 149 140 130 r T -/mit 1-SFP bmbient air 75&deg;F and I i ?O 00% RH, 9,F CCW andt 83F SW Unit ICOWand 1 -SFP ambient air @W5&deg;F and 109:% RH, 91F ZF~&0.E a.I-U.(1-120/110 100 90 1 350.00 400.00 450.00 500.00 0.00 50.00 100.00 150.00 200.00 250.00 300.00 time (hrs)Case 5b -100-hr limiiting Attachment 4 pa.-e I of I S-C-SF-MDC-1810 Revision 7 Attachment 4 CROSSTIE Input and Output Files (Electronic files on CD)Input files SFP inventory data files" Unitl-17.dcy

* Unitl-18FC.dcy 0 Unitl-18POST.dcy" Unit2.dcy Input Data File "Rfile".* 1R18clgl(2).dat

& 5-1-07a(b).dat

..................--  

-....g---1--08a(b)-dat--

--. --- -.. ... .. .. ......... ... .. .... ..Output files -The output files are included for each case for both the bounding and best-estimate sub-case with the following hierarchy:

Cases 1, 2, 3 and 5> Bounding> Plot.dat> Result.temp

> Unitl.htl> Unit2.htl> Best estimate> Plot.dat> Result.temp

> Unitl.htl> Unit2.htl Case 4> 5-1-07 (typical for each date)> Bounding> Plot.dat , Result.temp

> Unitl.htl> Unit2.htl> Best estimate> Plot.dat> Result.temp

> Unitl.htl> Unit2.htl SC.OM-AP.ZZ-0001(Q)

REVISION I ATTACHMENT 5 SALEM VERIFICATION OF DECAY HEAT REMOVAL FOR CORE OFF-LOAD Ref Order/Notification:

Calculation Number: S-C-SF-MDC-1810.

Rev. 7 Attachments:

Calculation cover sheet, conclusion and heatup curves Required maximum river inlet temperature to support core off load at 100 hours after sub-criticality is 82 0 F The minimum time in which core off load could be conducted and adequate decay heat removal would exist in the spent fuel pool is 100 hours after sub criticality.

Engineer: Robert Down Engineering Supervisor:

Alan Johnson k \4\ A Date: 2/14/07 Date: z]l'!7 IJ Copy to: Control Room Supervisor Outage Control Center -Shift Outage Manager RAT Notes: 1. Max river temperature based on a max CC supply temperature of 91TF, to ensure SFP will not exceed licensing basis limit of 149_&deg;F, For current scheduled offload start of 121 hours, max SW and CC temperatures are 85TF and 94TF, respectively.

: 2. SFP high temperature alarm setpoint of 125&deg;F will be reached with a CC temperature 69 0 F, for the scheduled offload start of 121 hours (corresponding.SW temperature m 60TF). If the alarm setpoint is reached, Alarm Response Procedure S2.OP-AR.ZZ-0003 (Alarm C-1 9) allows the setpoint to be temporarily increased to allow refueling activities to continue.

If necessary to reset, the temporary alarm setpoint is 140 0 F, conservatively based on a CC temperature of 800F.3. Calculation results assume one SFHX and one CCHX in service...S-xCwSF--MDC-i-181-0 Revision-7

-Attachment 5 Page 1 of I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 PSEG Internal Use Only Page 1 of I PSEG NUCLEAR L.L.C.SC.OM-AP.ZZ-0001(Q)  

-REV. 1 SHUTDOWN SAFETY MANAGEMENT PROGRAM -SALEM ANNEX SPONSOR ORGANIZATION:

Outage Management REVISION  

: Biennial Review Required:

Yes __ No 4i The following changes are;1. Changed the definition of "Available" to be consistent with OU-AA-103, Shutdown Safety Management Program.2. Editorial changes to text throughout for preferential wording as instructed by sponsor.Implementation Requirements Effective Date: 5- ] (h~lGW-At wihCU. 03, Shutdevn Safety MmangacmoPfgnt Przgzdrue Paid roplaezs NC.M- A, p Zz ..0. , Rz- , auLagr kwtao &#xfd;en

* uocde.,e... "V Approved: Outage Manager Date USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

==4.0 BACKGROUND==

.........................................................................................................

3 5.0 PROCEDURE  

.............................................................................................................

4 5.1 Outage Risk Assessment Process ........................................................................

4 5.2 ORAM Contingency Planning .............................................................................

5 5.3 Outage Risk Assessment and Management (ORAM) Software ........................

5 5.4 ORAM Software and M odel Changes ................................................................

6 5.5 Risk Assessment during Outage Execution  

.......................................................

6 5.6 Forced Outages ..................................................................................................

8 5.7 Salem Integrated Decay M anagement  

.................................................................

8 6.0 RECORDS ........................................................................................................................

9 7.0 DEFINITIONS  

............................................................................................................

9  

==8.0 REFERENCES==

10 Page 1 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-OOO1(Q)

Section ATTACHMENT Attachment 1 Attachment 2 Attachment 3 Attachment 4 Attachment 5 Attachment 6 Attachment 7 Attachment 8 Attachment 9 Attachment 10 T S itle Salem Risk Assessment Review Guidelines  

...............................................

12 Salem Shutdown Safety Considerations  

....................................................

15 ORAM Contingency Planning ...................................................................

25 ORAM Contingency Plan Content .............................................................

27 Salem Verification of Decay Heat Removal for Core off Load ..................

30 Decay Heat Load and Heat up Curves/Tables  

-Development Time Line ....... 31 Salem Shutdown Safety Assessment Worksheet  

........................................

34 Salem Shutdown Risk Status Sheet ...........................................................

39 Transitional Modes Guidelines (TMG) -Salem I and 2 ...........................

41 Cross-Unit Heightened Awareness Equipment List ...................................

47 Page 2 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 1.0 PURPOSE 1.1 This manual defines the PWR key safety functions and provides guidance for the deterministic status assessment for each function.1.2 On a case by case basis, the station may dictate a specified set of component(s) resulting in a different assessment than prescribed in this manual. If a variation from the guidance specified in this manual is deemed appropriate, the rationale and the Shutdown Safety Review Board (SSRB)approval shall be documented on form OU-AA-103 Attachment 1, Shutdown Safety Approval form.The SSRB has the final authority to determine what constitutes compliance specified herein.2.0 SCOPE NOTE This procedure should be implemented in conjunction with OU-AA-103, Shutdown Safety Management Program 2.1 This procedure applies to the planning, scheduling, and execution of work on a unit already in or expected to be in a shutdown mode of operation.

==4.0 BACKGROUND==

4.1 Shutdown Safety Management Programs (SSMP)* The SSMP uses as its basis the philosophy and recommendations stated in NUMARC 91-06,"Guidelines for Industry Actions to Assess Shutdown Management".

* The SSMP is also designed to meet the applicability requirements of 1OCFR50.65a(4) and NUMARC 93-01, "Industry Guidance for Monitoring the Effectiveness of Maintenance at Nuclear Power Plants".* This procedure is not intended to meet the requirements specified in the SAR or Technical Specifications.

Page 3 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 5.0 PROCEDURE 5.1 Shutdown Safety Review Process 5.1.1 Outage risk assessments in preparation for planned/refueling outage execution are performed by analyzing the outage schedule in the ORAM software or manually using hard copies of the Safety Function Assessment Trees (SFAT) in the modes where the ORAM computer model is applicable as well as Attachments 1 and 2. During transition modes, the applicable guidance of this procedure is used.5.1.2 The SSRB should assess the adequacy of the DEFENSE-IN-DEPTH provided for the duration of the outage. This assessment should also include a detailed examination of the outage schedule, including system interactions, support system availability, logic ties and the impact of temporarily installed equipment.

When entry into Mode 5 is planned, the ORAM software should be used to assist in the risk assessment.

The SSRB members should first use paper copies of the SFAT logic in order to study the schedule and to form an opinion about the resulting risk, and then the ORAM computer tool should be used to validate the results. Discrepancies will either be the result of improper schedule coding or human error in the risk assessment.

Once these discrepancies are resolved, there will be a high degree of confidence in the accuracy of the risk assessment.

The assessment should include consideration of the guidance in Attachments 1 & 2 -Salem Risk Assessment Review Guidelines  

& Salem Shutdown Safety Considerations.

5.1.3 For planned/refueling outages, the SSRB membership quorum requires 3 members to conduct business.

The Shutdown Safety Manager chairs the SSRB. One member must hold a current operating license. One member must be a nuclear engineer (NE)/Reactor Engineer (RE) for issues involving reactivity Control Key Safety Function.

Other members could also include knowledgeable representatives from the following departments: " Operations" Engineering" Maintenance" Radiation Protection

* Chemistry a Work Management" Training 5.1.4 Continuity of SSRB membership is highly desirable and consideration should be given to not changing team members once assigned.5.1.5 The SSRB should not include those directly involved in the development of the outage schedule.5.1.6 The Shutdown Safety Manager shall document all reviews, recommendations, approvals, and other actions taken by the SSRB using OU-AA-103, Attachment 1.Page 4 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 5.1.7 The SSRB chair is responsible to deliver a pre-outage Risk Assessment to the Outage Manager. The report should include the following elements;* Overall risk profile for the outage" Planned entries into Yellow/Orange/Red conditions

* Contingency plans* Controls in place to prevent inadvertent entry into a decrease defense in depth color change 5.1.8 The final SSRB pre-outage assessment report and associated contingency plans should be reviewed and approved by the SORC.5.1.9 The risk assessment should be validated after final schedule issuance (integrated reviews).

The Shutdown Safety Manager is responsible for coordinating this validation to ensure safety function logic ties are maintained by reviewing the Level 2 schedule.

Any problems identified from the validation would be presented to the Outage Manager for resolution.

1700159841 5.2 ORAM Continaency Plannin[5.2.1 Any required ORAM contingency plans shall be developed and processed in accordance with Attachment 3, ORAM Contingency Planning, and Attachment 4, ORAM Contingency Plan Content.The use of PRA and ORAM information should be considered when developing ORAM contingency plans.5.2.2 ORAM contingency plans are returned to the Outage Manager for development of the post-outage critique.

Retention of ORAM contingency plans is not required.5.3 Outage Risk Assessment and Management (ORAM) Model 5.3.1 ORAM determines the level of "DEFENSE-IN-DEPTH" for the following KEY SAFETY FUNCTIONS: " Shutdown Cooling

* Containment" Electrical Power Availability

* Service Water" Inventory Control

* Swgr Penetration Area Ventilation" Reactivity Control

* CREACS" Spent Fuel Pool Cooling 5.3.2 Outage schedules are analyzed by the ORAM software and colors assigned to designate the risk level to each of the safety functions.

The risk levels (colors) assigned represent the DEFENSE-IN DEPTH that is AVAILABLE for each safety function.

ORAM determines the appropriate risk level by analyzing the availability of selected individual pieces of equipment that are necessary to support the safety function.Page 5 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 5.3.3 The following plant conditions correspond to the ORAM assigned risk levels (colors): GREEN Based on the combination of available pathways and activity types, a failure or error could be easily mitigated without presenting a significant challenge in that Key Safety Function.YELLOW Based on the combination of available pathways and activity types, a failure or error can still be mitigated but might present a challenge in that Key Safety Function.ORANGE Based on the combination of available pathways and activity types, a failure or error would potentially lead to the loss of the Key Safety Function.RED Based on the combination of available pathways and activity types, the Key Safety Function is potentially not maintained.

5.3.4 As a backup, printed copies of the SFATs and Fault Trees from the ORAM model can be used to perform manual risk assessment.

5.4 ORAM Software and Model Changes 5.4.1 The ORAM Program Administrator maintains configuration management of the ORAM Software and Model. The Operations Manager, or licensed designee provides guidance on revisions or enhancements to the ORAM model, in accordance with the ORAM Software and Model Quality Assurance Plan.5.4.2 Proposed revisions to the ORAM Model should be processed using the Notification process in SAP to create a NUTS Order. The Notification should be assigned to the ORAM Program Administrator.

5.4.3 When necessary due to ORAM model changes, the ORAM Program Administrator shall issue a revision request (Notification) to Operations to update the Safety Assessment Worksheet, Attachment 7.5.4.4 The ORAM Program Administrator shall retain a record of all implemented ORAM model changes.5.4.5 The Operations Manager shall assign an actively-licensed SRO to verify that changes have been programmed correctly.

When a change has been satisfactorily validated, the SRO shall sign, date and return the change request to the ORAM Program Administrator, who should issue the change in accordance with the Software Quality Assurance Plan. At this point, the ORAM model is considered updated.5.5 Risk Assessment during Outage Execution 5.5.1 Outage risk assessments during outage execution are performed by analyzing the outage schedule in the ORAM software or manually using hard copies of the SFATs in the modes where the ORAM computer model is applicable.

During transition modes, the applicable guidance of this procedure is used.5.5.2 The Shutdown Safety Manager or designee should perform a risk assessment once per shift following each schedule update, as well as when significant changes in plant conditions or outage schedule occur which could potentially impact the risk assessment.

Page 6 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION.

STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 5.5.3 Assessments should be performed for significant change in plant configuration prior to a planned evolution or scope change which has the potential to impact one of the KEY SAFETY FUNCTIONS, and for which it has not been previously analyzed.5.5.4 During cold shutdown and refueling modes, a Shutdown Risk Status Sheet Attachment 8 or similar, provided the similar forms contain the same required information, should be generated that includes the following as a minimum: A. Designated ORAM color code for each KEY SAFETY FUNCTION.B. Overall shutdown risk potential (color). (Overall safety is equal to the "worst" color of any Key Safety Function.)

C. Important protected systems, equipment, instrument channels and/or protected areas.D. Active ORAM contingency plans.E. Time to boil/design limit for fuel located in reactor vessel and/or Spent Fuel Pool." Should track time to boil for reactor vessel whenever fuel is in the vessel" Track time to boil when core is completely offloaded.

F. Shutdown condition (i.e., mid-loop, loops not full, loops full, etc.).5.5.5 Emergent high-risk activities should not start until a risk assessment takes place. However, any activities that require immediate attention may commence prior to the completion of the assessment.

5.5.6 If the unplanned need to establish containment integrity is identified during a forced or refueling outage, the SOM may consider the following:

* Actions needed to assist Operations in implementing required operating procedures and abnormal operating procedures, e.g., S l/S2.OP-AB.CONT-0001(Q)" Closing larger containment penetrations first" Utilizing the outage schedule and SAP to identify containment breeches" Performing walk downs to determine actual penetration status" Utilizing containment coordinators or shop personnel to obtain work status and identify closure options.Page 7 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 5.5.7 Manual risk assessment when required is to be conducted as follows: A. Obtain a copy of the outage schedule B. Review what the change is; system and/or equipment, start/stop time, duration C. Determine if the schedule meets the requirements for shutdown safety D. Determine if the system/equipment affects the risk assessment.

Compare the Plant Configuration Definitions with the system/equipment being changed.E. If the selected item affects risk assessment, review the SFAT to determine the risk.F. Trace the logic tree to determine if a color (risk) change has occurred for each Key Safety Function.G. Notify the SM/CRS and the SOM if any changes affect the risk assessment.

5.5.8 During outages there should be a heightened awareness on cross-unit equipment that supports the DEFENSE-IN-DEPTH of the outage unit. See Attachment 10 for a list of cross-unit equipment.

5.6 Forced Outa2es 5.6.1 For planned and unplanned forced outages, the initial risk assessment shall be performed as soon as the outage schedule is available.

5.6.2 The risk assessment for a forced or unplanned outage must consider the impacts of on-line work in progress in addition to the work that will be performed during the outage.5.6.3 While in the transition mode, the risk assessment should be performed in accordance with Attachment 9 once per shift or whenever a configuration change occurs.5.6.4 The Forced Outage Risk Assessment Report may be submitted to SORC as determined by the Forced Outage Manager, based upon outage complexity and length.5.6.5 With the plant in the transition mode the Forced Outage Manager may convene a SSRB to address specific issues, configurations or evolutions.

5.7 Salem Intearated Decay Heat Manaeement 5.7.1 Prior to each refueling a calculation shall be performed to ensure that the decay heat load expected and river water temperature are adequate to meet the required heat removal capability for core offload after the reactor has been subcritical for 100 hours. Completion of this calculation should be documented on Attachment 5 and provided to the CRS as documentation that the Tech Spec Hold time is valid for the refueling.

[Ref. LCR S02-03]5.7.2 Decay heat load management should be accomplished by reactor vessel and spent fuel pool decay heat load and heat-up calculations which are essential input to effectively assessing outage risk during schedule development.

This information is required to establish appropriate controls over spent fuel pool heat exchanger operation in the cross connected mode of operation to assure that both Units' Spent Fuel Storage Pools are adequately cooled. Calculations also provide the means to identify the proper time frames for taking major systems out of service for maintenance (i.e., CCW, SW, Electric Power, Other Unit's FPC Heat Exchanger, CCW, SW systems).Page 8 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q) 5.7.3 Attachment 6 provides the necessary timeline for developing decay heat loads and heat-up curves/tables to allow the stations to assess the time available to implement SFP heat exchanger cross connect operations, time available for other mitigating actions. Finalized decay heat load and heat-up curves shall be provided to the on-duty Ops Shift Manager prior to the start of refueling outages by the Outage Superintendent.

6.0 RECORDS 6.1 The calculation and supporting documentation for Attachment 5 are to be kept as life of plant records IAW the records management process.6,2 The Risk Assessment Report is not a quality record and need only be retained as long as necessary to support Post-Outage Critiques.

7.0 DEFINITIONS 7.1 Available  

-A system, structure, or component along with its necessary auxiliary systems, controls, instrumentation, and power supplies is capable of performing its intended function and can be placed in service by manual or automatic means. Recognizing that in this condition all applicable technical specification requirements or licensing/design basis assumptions may not be maintained.

This does not infer the system or component is OPERABLE in accordance with Technical Specifications, or available as defined in SH.SE-DG.ZZ-0017(Z), Unavailability Log Keeping Guidelines.

NOTE An ECCS injection source may be considered available irrespective of the Reactor Cavity being flooded, when its breaker is racked down and Cleared & Tagged (C/T) for the SM/CRS 7.2 Key Safety Functions  

-For shutdown and refuel conditions, these are functions that provide Shutdown Cooling (Decay Heat Removal), Fuel Pool Cooling, Vessel and Spent Fuel Pool inventory control, electrical power availability, reactivity control, vital support systems: Containment, Control Air, Service Water, and CREACS.7.3 Reduced Inventory is the condition of the reactor coolant system when fuel is in the reactor vessel and the RCS level has been drained to less than or equal to 101 ft elevation.

7.4 Risk Management  

-Process of assessing and reducing the likelihood and/or consequence of an adverse event.7.5 Protected Equipment  

-Minimum amount of equipment required to maintain planned DEFENSE-IN-DEPTH.

No work should be allowed on or around this equipment, without, operations approval.Operating personnel would install/remove barricades, flags, etc. to protected equipment or areas as specified in the contingency plans and operating procedures.

7.6 Transitional Modes -Modes 3, and 4.7.7 ORAM Translation Matrix -The software table that relates the schedule to the ORAM software.Page 9 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

==8.0 REFERENCES==

+ INPO 97-005, Guidelines for the Management of Planned Outages at Nuclear Power Stations+ INPO AP-925, Outage Process Description

+ NUMARC 91-006, Guidelines for Industry Actions to Assess Shutdown Management, December 1991+ NUREG-1449, Shutdown and Low-Power Operations at Commercial Nuclear Power Plants in the United States+ NUREG-1410, Loss of Vital AC Power and the Residual Heat Removal System during Mid-loop Operations at Vogtle Unit # 1+ NSAC-173, Survey of BWR Plant Personnel on Shutdown Safety Practices and Risk Management Needs+ SOER 98-1, Safety System Status Control+ Salem Technical Specifications

+ NRC Bulletin 93-03, Resolution of Issues Related to Reactor Vessel Water Level Instrumentation in BWRs+ Salem LCR S02-03+ 1 OCFR50.65(a)(4) 8.1 Cross-References

* NC.LR-DG.ZZ-0007, Desk Top Guide for ORAM* OU-AA- 103, Shutdown Safety Management Program 8.2 Commitments

* None Page 10 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-.0001(Q)

ATTACHMENT 1 SALEM RISK ASSESSMENT REVIEW GUIDELINES Page 1 of 4 1.0 The purpose of the initial risk assessment review by the SSRB is to perform an independent assessment of the outage schedule and ORAM contingency plans with the intent of ensuring the proper scheduling and availability of the safety systems needed at various stages of the outage.This review should ensure that the schedule: " Clearly identifies High Risk and required ORAM Contingency Plans" Identifies Infrequently Performed Tests or Evolutions and the required additional management oversight and controls* Identifies the systems, structures and components needed to provide DEFENSE-IN-DEPTH for Key Safety Functions for the different plant conditions that will be experienced during the outage" Sequence outage activity such as integrated testing to ensure continued operability of required systems per the Mode.1.1 Review the outage schedule and associated logic ties for activities or combinations of activities that could possibly present a challenge to the shutdown safety functions.

1.2 Review industry experience relative to shutdown events.NOTE Shutdown Safety Considerations are provided as a reference for the SSRB Review (Attachment 2).1.3 As a minimum, the following shall be reviewed when evaluating risk level in the outage schedule.1.3.1 Reactivity Control" Number of charging pumps available" RWST/BAST availability, including the ability to cross-tie BASTs between units" Number of source range instruments available" Periods with fuel movement" Fuel Status (prior to refueling, defueled, post refueling).

Page 11 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 1 SALEM RISK ASSESSMENT REVIEW GUIDELINES Page 2 of 4 1.3.2 Shutdown Cooling* RCS condition (i.e. loops full, loops not full, mid-loop, cavity full, etc.)" Number of steam generator loops available with associated Aux Feedwater pumps (applies in Transition Modes ONLY)" Number of RHR loops available* Number of Service Water headers available" Number of ECCS injection pumps available" Equipment required available to support decay heat removal, including backup and alternate methods.1.3.3 Spent Fuel Pool heat removal capability" Number of SFP pumps w/heat exchanger(s) available to maintain 1491F pool temperature under normal conditions, and 180OF under abnormal conditions" Component cooling water availability" FHB Ventilation exhaust fan availability" Activities during high decay heat periods" Availability of SFP make up systems" Opposite unit SF cooling available for cross-tie.

1.3.4 Inventory Control* Periods when RCS inventory is less than 10% in the pressurizer but greater than 101'." Periods at Reduced Inventory (less than 101')." Periods at mid-loop (less than 99')." Number of level instruments available." Availability of ECCS Inventory Makeup systems." Fuel Status (prior to refueling, defueled, post refueling).

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ATTACHMENT 1 SALEM RISK ASSESSMENT REVIEW GUIDELINES Page 3 of 4 1.3.5 Electrical Availability" Availability of Emergency Diesel Generators." Number of available offsite power sources." Maintenance work in the switchyard." Vital AC Bus status." DC battery/status.

* Fuel Oil transfer pumps." Gas turbine." Availability of power sources required to support Key Safety functions" Likelihood of maintaining offsite sources, i.e., weather conditions, ice, snow, temperature, etc. to the extent practical (Daily review, not pre-outage).

1.3.6 Control Air System Availability" Number of station air compressors." Number of Emergency Air Compressors." Control Air headers." Station blackout compressor available." Temporary Air Compressors 1.3.7 Containment Requirements for" Periods of containment status where integrity or modified integrity is required." Periods when Equipment Hatch/Outage Equipment Hatch is required." Containment closure be achieved prior to fuel damage." Core alteration requirements." CFCUs available Page 13 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 1 SALEM RISK ASSESSMENT REVIEW GUIDELINES Page 4 of 4 1.3.8 Control Room Emergency Requirements" Number of CREACS available." Number of CAACS available." Number of chillers available," Number of chilled water pumps available." CAV alignment and the opposite units ability to support maintenance mode." Power availability to CAV components (460VAC, 230VAC and 125VDC).1.3.9 Switchgear Penetration Area Ventilation (SPAV)" Switchgear return and exhaust fans." Electrical penetration exhaust fans." Switchgear supply fans." Emergency diesel generator backup for SPAV fans.1.3.10 Service Water* Number of Service Water headers available.

* Number of Service Water pumps available fed from different power supplies.e The decay heat load of the reactor.1.3.11 Potential Fire Hazards" Review of all scheduled outage hot work* Review focused on hot work in areas that contain equipment required for decay heat removal.Page 14 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS Page 1 of 9 1.0 STATION PHILOSOPHIES 1.1 Electrical Power Vital AC and DC power to KEY SAFETY FUNCTIONS is required during shutdown conditions to maintain cooling to the reactor core and spent fuel pool, to transfer heat to the ultimate heat sink, to restore containment integrity, if required, and to support other important safety functions.

The outage schedule should be reviewed to ensure that periods of plant vulnerability do not coincide with periods where significant sources of Vital power are not available." All sources of Offsite power should remain AVAILABLE if possible during HIGHER RISK EVOLUTIONS.

If a source of Offsite power is made unavailable (due to maintenance, for example) the remaining available sources of Offsite power should be protected during HIGHER RISK EVOLUTIONS.

In MODE 5 or 6, if only one Offsite AC power source is OPERABLE during HIGHER RISK EVOLUTIONS, three diesel generators should be maintained AVAILABLE with two maintained OPERABLE as defined in Technical Specifications.

Exceptions to this shall be approved by the (Station)Operations Manager and OSM." Electrical power availability during non-higher risk evolutions should be consistent with Technical Specifications and at no time should a planned removal of all Offsite power sources be scheduled." Plant personnel should be kept aware of the status of safety-related electrical systems and unusual configurations/electrical lineups (i.e., buss cross-ties, emergency breakers closed) created due to outage work requirements." Control should be maintained over switchyard work to minimize the possibility of personnel error causing a loss of power. Particular care should be taken to ensure that work that could potentially affect the availability of Offsite Power is reviewed for its effect on the DEFENSE-IN-DEPTH of the electrical power system during critical plant evolutions or during periods of high decay heat load." There should be no delays in returning critical electrical equipment to service.1.2 Diesel Generators Equipment relied upon for DEFENSE-IN-DEPTH should be evaluated for Emergency Power Supply Requirements.

Attention should be given to structures, systems and components requiring Diesel Generator backup for OPERABILITY. (Examples include Charging Pumps, Fuel Handling Building Exhaust Fans and CREACS fans, and Source Range Nuclear Instruments.)

Page 15 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS Page 2 of 9 1.3 Shutdown Cooling 1.3.1 Maintaining core/reactor cavity flooding capability and providing an alternate means of decay heat removal is a key safety function during shutdown conditions.

1.3.2 Emergency Core Cooling Systems (ECCS) and decay heat removal systems AVAILABILITY should be maximized during periods of high decay heat or minimum coolant inventory.

Equipment outages which impact shutdown cooling systems should be scheduled during periods of low decay heat and/or maximum coolant inventory (i.e., while the Reactor Cavity is flooded) or while the core is off-loaded, whenever practical).

1.3.3 The suitability of a system as a decay heat removal system does not directly relate to its Tech Spec operability status. Since decay heat generation will vary with core power history, the decay heat removal capability required will also vary. During defueled conditions the spent fuel cooling safety function is utilized.

A system is considered to be AVAILABLE if it can be used to maintain core temperature below the temperature limit imposed by Operating Procedures.

DEFENSE-IN-DEPTH is met for the Shutdown Cooling Safety Function when a primary and a backup decay heat removal system is AVAILABLE, each being capable of removing decay heat and the ECCS Tech Specs are met. The systems available to meet this object are: " RHR Loop -11 (21) RHR Pump and RHR Heat Exchanger, 11 (21) Service Water Header, 11 (21) Component Cooling Header and support components (associated control air, electrical power supplies, etc.)." RHR Loop -12 (22) RHR Pump and RHR Heat Exchanger, 12 (22) Service Water Headers, 12 (22) Component Cooling Header and support components (associated control air electrical power supplies, etc.).The ability to cross-tie these trains exists and is effective in providing for adequate shutdown cooling.Page 16 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS Page 3 of 9 1.3.4 The following Core Cooling measures are provided by Operating procedures S 1(2).OP-AB.RHR-0001 (Q), Loss of RHR; or S 1(2).OP-AB.RHR-0002(Q), Loss of RHR at Reduced Inventory: " Hot Leg Injection using the designated AVAILABLE Safety Injection Pump." Cold Leg Injection using the designated AVAILABLE Charging Pump.* Spent Fuel Pool Cooling (only when Reactor Head is removed).* Steam Generator Reflux Cooling with Gravity Feed from RWST (applies when RCS is depressurized and Reactor Coolant Pumps are not available)." Cold Leg Recirculation.

1.4 Inventory Control 1.4.1 Control of reactor coolant system inventory is essential in maintaining the overall decay heat removal function.

During reduced inventory operations, boiling and potential fuel damage can occur in a relatively short time period if decay heat removal is not restored.1.4.2 Regardless of the amount of ECCS Equipment available to support this safety function, the ORAM risk color shall be determined as no better than ORANGE'with the RCS at reduced-inventory conditions.

This is due to the reduced time to core boiling with reduced mass in the RCS.1.4.3 The reactor coolant boundary expands during shutdown periods to include the RHR piping, Spent Fuel Pool, Refueling Cavity and other connected support systems.1.4.4. Special plant configurations during outages increase the possibility of a valve misalignment or other plant problem, which could cause a loss of reactor vessel or Refueling Cavity inventory.

Plant configurations where a single active failure or personnel error can result in a rapid loss of reactor water should be identified and minimized to the greatest extent possible.1.4.5 Reduced Inventory is the condition of the reactor coolant system when fuel is in the reactor vessel and the RCS level has been drained to less than or equal to 101 ft elevation.

1.4.6 No changes should be made in the refueling cavity or reactor vessel level without adequate level instrumentation.

During any reactor vessel level changes, proper instrumentation response should be verified.

Where possible, redundant level instrumentation shall be used.Page 17 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS Page 4 of 9 1.4.7 The following additional measures should be considered to maintain RCS inventory control capabilities:

* Hot side Steam Generator manways should be removed first and installed last." Cold side Steam Generator nozzle dams should be installed first and removed last.1.4.8 Containment closure should be maintained or monitored at all times during reduced inventory conditions with fuel in the vessel, or during fuel movement activities.

Schedules should ensure that when the RCS level is less than 104 feet but greater than 101 feet in the RCS, that either the Equipment Hatch remains INSTALLED or the Outage Equipment Hatch is instafled and the ability to close it in a timely manner exists.1.4.9 When the RCS is not intact, both containment sump pumps and a flowpath to the in-service waste holdup tank should be maintained AVAILABLE to the maximum extent possible.

Local Leak Rate Testing of the sump lines should be performed as efficiently as possible and the system returned to service expeditiously.

1.4.11 Systems AVAILABLE FOR Spent Fuel Pool makeup are: " Refueling Water Storage Tank (RWST)" Primary Water Storage Tank (PWST)" Demineralized Water System" CVCS Holdup Tanks" Emergency fill from RWST (Portable Pump)" Emergency Fill from PWST (Portable Pump)Page 18 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS (Page 5 of 9)1.4.12 DEFENSE-IN-DEPTH is met for the Inventory Control Safety Function when a primary and a backup core flooding system is AVAILABLE and the Technical Specifications for the ECCS are met. At least one of the systems must be capable of being powered from its emergency power source. A system is considered to be AVAILABLE when it is capable of providing makeup flow commensurate with the present plant conditions and activities.

When plant conditions are being controlled such that a potential to drain the vessel does not exist, the required makeup capability can be significantly reduced. The primary or the backup system must have an AVAILABLE source of emergency power.1.5 Spent Fuel Pool Cooling 1.5.1 When the core has been off-loaded to the Spent Fuel Pool, the guidelines that apply to core cooling also apply to the Spent Fuel Pool.1.5.2 A primary and a backup means of cooling the Spent Fuel Pool should be AVAILABLE.

At least one of these systems, and its required support systems, must be powered from an emergency power supply. Each system must be capable of maintaining Spent Fuel Pool temperature at the Design/Licensing basis limits under the worst anticipated heat load. Primary means must be capable of maintaining the Spent Fuel Pool temperature at 1497F or less under the worst anticipated heat load with two SFPC pumps and two SFPC heat exchangers in parallel operation.

The duration of parallel/single Spent Fuel Pool Cooling Heat Exchanger operation is limited to maintain Spent Fuel Pool temperature limits at both units.Page 19 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS (Page 6 of 9)1.5.4 Systems available for Spent Fuel Pool Cooling are:* 11 (21) Spent Fuel Pool Pump* 12 (22) Spent Fuel Pool Pump* 11 (21) Fuel Handling Building Exhaust Fan* 12 (22) Fuel Handling Building Exhaust Fan* Spent Fuel Pool cross-connect from opposite unit* Spent Fuel Pool Pit Heat Exchangers and associated pumps with component cooling and service water available for Heat Sink 1.5.5 Caution must be exercised when utilizing alternate feeds to power the Spent Fuel Pool Pumps and fuel Handling Building Ventilation Fans to ensure that electrical separation criteria are met.1.5.6 DEFENSE-IN-DEPTH is met for Spent Fuel Pool Cooling when a Primary and a Backup means of Spent Fuel Pool Cooling is AVAILABLE.

Each system must be capable of maintaining the spent Fuel Pool temperature at the Design/Licensing basis limits under the worst anticipated heat load.Backup means must be capable of maintaining the Spent Fuel Pool temperature at 180*F or less under worst anticipated heat load.1.6 Reactivity Control 1.6.1 An important element of shutdown safety is maintaining reactivity control. Boron dilution events during shutdown conditions have resulted in reductions in reactivity shutdown margin. Uncontrolled or inadvertent criticalities that occur while the plant is shut down could lead to unplanned radiation exposure of plant personnel and possible fuel damage.1.6.2 Sufficient instrumentation should be available to monitor critical parameters.

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ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS (Page 7 of 9)1.7 Containment Control 1.7.1 Containment closure is a preliminary action that immediately and effectively reduces the likelihood of a release while providing flexibility to have the containment building open under appropriate conditions.

The containment building provides the last integral barrier to the release of radioactive material to the general public.1.7.2 The ability to establish containment integrity or closure should be maintained during HIGHER RISK EVOLUTIONS.

1.7.3 Containment closure should be maintained at all times during reduced inventory conditions with fuel in the vessel, or during fuel movement activities.

Schedules should ensure that either the Equipment Hatch remains INSTALLED or the Outage Equipment Hatch is installed and the ability to close it in a timely manner exists.1.7.4 Activities planned and scheduled during periods requiring containment closure (i.e., during fuel movement) should be carefully reviewed to ensure that neither the work activity nor its tagout will cause a breach of containment integrity: " Example: Opening a high point vent (inside) and a low point drain (outside around a containment isolation valve)." Prior to opening systems inside containment, ensure that containment breaches are considered that are not readily apparent (e.g., steam generator secondary side manway removed with an associated main steam safety valve removed)." With fuel in the reactor vessel, any penetration with maintenance or testing in progress should have the redundant isolation valve closed; or for penetrations without redundant isolation valves (including electrical penetrations), appropriate plugs or sealing material should be installed, unless specifically controlled by approved procedure(s)." Expedited containment closure capability, including staging of required tools, should be maintained when there is fuel in the reactor vessel. This should include contingencies for the loss of AC power.Page 21 of 46 Rev. I USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS (Page 8 of 9)1.8 Service Water 1.8.1 The Service Water System serves as the ultimate heat sink for various key safety-related heat loads which are vital for safe operation of the plant. The Service Water System must operate during all phases of plant operations including startup normal operation, shutdown, safety injection and recirculation phases.1.8.2 Two independent Service Water loops are required OPERABLE in MODE 4.1.8.3 Removal from service and return to service of a Nuclear Header should be accomplished in accordance with approved Operations procedures to preclude the loss of any Key Safety Functions supplied by service water.1.8.4 With one Nuclear Header out of service, work activities which have the potential to affect the operable Service water Header should be deferred.1.8.5 Ensure that work activities on Service Water piping do not create an unmonitored flooding path to an operable Service Water Bay.1.8.6 Systems/equipment that provide support functions for other activities should be maintained AVAILABLE with their associated electrical/water/air sources available commensurate with the activity being supported.

Among those providing support functions are: " Auxiliary Demineralizer Transfer Pump available* Primary Water Storage Tank* Demineralized Water Pumps" Fresh Water Storage Tank & Pumps Page 22 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 2 SALEM SHUT DOWN SAFETY CONSIDERATIONS (Page 9 of 9)1.9 Control Air 1.9.1 In order to ensure an adequate air supply to vital safety-related equipment and to support plant outage activity needs, only one of the below listed compressors should be out of service at a time:* Station Air Compressors" Emergency Control Air Compressors

* Station Blackout Compressor 1.9.2 Air Headers associated with the above should be maintained commensurate with plant conditions and needs.1.10 Fire Protection 1.10.1 All scheduled outage hot work should be reviewed to ensure that Fire Protection measures are adequate.1.10.2 Special emphasis should be given to hot work in areas that contain equipment required for maintenance of Key Safety Functions (i.e., decay heat removal).1.10.3 At least one Diesel Driven Fire Pump should be maintained AVAILABLE.

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ATTACHMENT 3 ORAM CONTINGENCY PLANNING (Page I of 2)These guidelines are to help ensure appropriate considerations are used when developing Contingency Plans.It is not intended to be all inclusive.

1.0 Additional monitoring required to minimize the potential for unplanned equipment unavailability should be considered." Additional operator rounds or need to perform walk downs once per shift" Additional log taking" Dedicated operator" Other additional measures 2.0 Protection of monitoring equipment/minimum essential equipment; location and placement should be specified." Use of barricades (include Protected Equipment/Protected Areas)" Caution flags/roped off (include Protected Equipment/Protected Areas)" Other controls/measures (include Protected Equipment/Protected Areas)3.0 Alternate Equipment/power supplies AVAILABLE?

4.0 Temporary equipment/power supplies AVAILABLE?

5.0 Special procedure required?

Should Infrequently Performed Tests or Evolution's briefings be applied? Are 50.59 evaluations required?6.0 Reference mitigating procedures (existing procedures with compensatory action)7.0 Any additional limits needed? ... Pressure, temperature, etc.8.0 Actions to minimize time in the condition requiring the ORAM contingency plan.9.0 Applicability of abort criteria 10.0 Required actions to restore KEY SAFETY FUNCTIONS.

Walk through required?" Additional training required?" Personnel on station?Page 24 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 3 ORAM CONTINGENCY PLANNING (Page 2 of 2)11.0 Identification of who is required to take action" Qualification requirements of personnel" Familiarize personnel with required actions" Notification of personnel supervision

* Personnel should be adequately trained and prepared to take actions 12.0 If personnel off site are required to implement the plan, this should be documented in the plan.13.0 Determine what equipment is necessary (if any) to complete compensatory actions" Have equipment staged" Ensure equipment is clearly marked to prevent removal" Equipment is tested and ready to be used 14.0 Any restrictions needed on plant conditions or other activities?

Are other activities on-going or planned which could further degrade the plant's DEFENSE-IN-DEPTH?

15.0 Determine briefing requirements factoring in lessons learned and industry experience.

16.0 Compare with other Contingency Plans for conflicts/consistency.

17.0 Consider scheduled work planned or in progress which could possibly affect key safety system power supplies during a HIGH RISK EVOLUTION.

18.0 If freeze seals are used, consider providing protection for surrounding equipment in the event the seal fails. Immediate actions to correct the failed seal should be identified.

19.0 If the Contingency Plan cannot provide comparable equipment  

/measures to provide the original DEFENSE-IN-DEPTH, then the evolution should be identified as HIGH RISK.20.0 Consider time to saturation or temperature limits under the following conditions: " Spent Fuel Pool Cooling lost" Total loss of RHR (Shutdown Cooling)21.0 Identify when protective measures specified in 2.0 may be discontinued/removed.

22.0 Use risk informed tools, when possible, for help in deciding on ORAM contingency plans.Page 25 of 46 Rev. 1 USER RESPONSIBLE FOR VERIFYING REVISION, STATUS AND CHANGES PRINTED 20070305 SC.OM-AP.ZZ-0001(Q)

ATTACHMENT 4 ORAM CONTINGENCY PLAN CONTENT (Page 1 of 3)Contingency plans are required for ORAM-ORANGE conditions.

They may also be utilized during transitional modes when minimum DEFENSE IN DEPTH is identified.

Cover Sheet -Cover sheet which includes the title of the ORAM contingency plan, scheduled implementation date and time, scheduled completion date and time, planned duration and the following required signatures:

PRE-SORC Required Signatures: " Initiator" Shutdown Safety Manager" A person cognizant of ORAM from the Nuclear Safety and Licensing Group" Outage Manager or designee" Operations Manager or designee Entry into the ORAM ORANGE condition required signatures: " Lead shop owner" SM/CRS authorization Entry into the ORAM RED condition required signatures:

* Shift Manager Authorization" Plant Manager Approval" Site Vice President Notification Scope: A brief description of the scope of work to be undertaken and objective during the period covered by the ORAM contingency plan.Justification:

Justification for entering the condition including a discussion of the overall benefit to plant safety that will be achieved by performing the maintenance.

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ATTACHMENT 4 ORAM CONTINGENCY PLAN CONTENT (Page 2 of 3)Prerequisites:

A listing of prerequisite activities for entering the ORAM-ORANGE condition:

* Applicable work packages in a "task ready" status.* Troubleshooting plans complete and approved by Operations.