{{#Wiki_filter:MINIMUM TEMPERATURE OF MULTI-ASSEMBLY SEALED BASKET SHIELD LID PLATE AFTER 20 YEARS AND 50 YEARS . REC'D W/1,TR DTD 9/29/95.*.  

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* ** ATTACHMENT 1 CONSUMERS POWER COMPANY PALISADES PLANT DOCKET 50-255 MINIMUM TEMPERATURE OF MULTI-ASSEMBLY SEALED BASKET (MSB) SHIELD LID PLATE AFTER 20 YEARS AND 50 YEARS 69 Pages miiu#S l'Hlllal PALIS ADES NUCLEAR PLANT EA-SC-93-083-22 ENGINEERING ANALYSIS COVER SHEET Total Number of Sheets t:.5 Minimum Tem12erature of MSB Shield Lid Plate After 20 years and 50 years INITIATION AND REVIEW Calculation Status Preliminary Pending Final Superseded D D Oll D Initiated InJt Review Method Technically Reviewed Revr ev Appd App CPCo # Descripdon By Detail Qual d Appd By Date Alt Cale Review Test By Date By P. Hoang 8/l819S (J1t* e>-2..1-'tt 0 Original Issue  

-**-(/ J *

* I PALIS ADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 1.0 OBJECTIVE The objective of this engineering analysis is to calculate the minimum temperature of Multi-Assembly Sealed Basket (MSB) shield lid plate of CMSB-01 through 04 after 20 years and 50 years of service when the ambient temperature is at 0°F. This analysis was performed to reinforce the 10°F movement restriction on CMSB-01 through 04.  

Per the requirements of Section 1.2.13 of the Certificate of Compliance Number 1007 under 1 OCFR72, movement of a loaded MSB when it is inside the Ventilated Concrete Cask (VCC) is only permitted at an ambient temperature of 0°F or above. This limitation is based on the MSB shell material having a minimum Charpy impact energy of 15 ft-lbs at -50°F. The temperature limit for MSB movement, therefore, is established by adding a margin of 50°F to the above test temperature.

The MSB shield lid plate material of CMSB-01 through 04 was not initially considered to be a structural component by the vendor; therefore, a Charpy impact test was not required.

Subsequent Charpy testing indicated that the shield lid plate material of the above CMSBs exhibited at least 15 ft-lbs of impact energy at a test temperature of -40°F. The minimum temperature at which the MSBs can be moved is 50°F above the Charpy test temperature of -40°F. Based on the test data, the future movement of those CMSBs is limited to ambient temperature of 10°F or above to prevent brittle failure. In this analysis, a calculation similar to those in Chapter 4 of the Safety Analysis Report (SAR) is performed to determine the minimum temperature of the MSB shield lid plate of CMSB-01 through 04 after 20 years and 50 years of operation and with ambient temperature of 0°F. The analysis will first calculate the decay fuel heat generation rate of all four loaded MSBs after 20 years and 50 years of operation.

Sheet _2_ Rev # 0 Reference/Comment 2.0 ANALYSIS INPUT PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET 2.1 GOVERNING DESIGN PRINCIPLES AND DOCUMENTS 2.1.1 Safety Analysis Report (SAR) for the Ventilated Storage Cask System, PSN-91-001, Rev. O 2.1.2 Safety Evaluation Report (SER) for the SAR, dated April 28, 1993 2.1.3 NUREG/CR-2397, "Fuel Inventory and afterheat Powers Studies of Uranium-Fueled Pressurized Water Reactor Fuel Assemblies Using the SAS2 and ORIGEN S Modules of Scale with an ENDF/8-V Updated Cross section Library", September 1982. 2.1.4 ANSYS Computer Program and Users Manual Volume I & II, Version 4.4A 2.1.5 Procedure No 4.43, Attachment 6, Revision 3, 3A (Fuel Data) 1.6 E-HAR-94-01, Attachment 9 (Heat Load) 2.2 DESIGN DRAWINGS 2.2:1 MS8 Drawings Dwg. No.: VEN-C-136C:

Sht. 4, Rev. A Sht. 7, Rev. A Sht. 8, Rev. A Sht. 9, Rev. A 2.2.2 VCC Drawings Dwg. No.: VEN-C-1368, Sht. 2, Rev. 3A Sht. 3, Rev. 3A Sht. 4, Rev. 3A Sht. 5, Rev. 2A Sht. 6, Rev. 2A Sht. 7, Rev. 2A Sht. 8, Rev. 2A Sht. 9, Rev. 3A Sht. 11, Rev. 2A Sht. 12, Rev. 2A Sht. 13, Rev. 32A Sht. 14, Rev. OA EA-SC-93-083-22 Sheet _3_ Rev # 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 2.3 EXISTING ANALYSIS 2.3.1 E-SC-93-083-10, "Heat Transfer Analysis of the Ventilated Storage Cask (VSC)", Rev 0 2.4 REFERENCE 2.4.1 ANSYS 4.4 A Verification, E-CRW-91-03 2.4.2 ANSYS Verification Manual Version 4.4A 2.4.3 ANSYS Theoretical Manual Version 4.4.A 2.4.4 Graphics Supplement for ANSYS Revision 4.A on Personal Computers, Swanson Analysis Systems, Inc UpdO DN-G103:44A December 1, 1990 2.5 SOURCE DOCUMENTS  

.1 Principles of Heat Transfer by Frank Kreith, Third Edition 2.6 PROCEDURES 2.6.1 FHS-M-32, "Loading and Placing the VSC Into Storage" 2.7 GEOMETRY AND MATERIALS The geometry and the materials used in the analysis were the same VSC model established in the Heat Transfer Analysis of the Ventilated Storage Cask (VSC) (Ref. 2.3.1) which is the same as the model used in SAR (Ref. 2.1.1 ). 2.8 PHYSICAL PROPERTIES All physical properties of the model are from the generic VSC model established for Heat Transfer Analysis of the Ventilated Storage Cask (Ref. 2.3.1 ). For 0°F ambient temperature, the density, thermal conductivity and specific heat of air were modified from the generic VCC model. Sheet _4_ Rev # 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 2.9 HEAT GENERATION RATES For the purpose of the calculation, the heat generation rates of CMSB-01, -02, -03 and -04 were calculated based on the "typical" tabulated data given the Appendix C of NUREG/CR-2397.

The "conservative" data from the same reference was used in the SAR (Ref. 2.1.1  

). 2.10 AMBIENT TEMPERATURE Ambient temperature of 0°F is considered in the analysis.

3.0 ASSUMPTIONS 3.1 MAJOR ASSUMPTIONS None 3.2 MINOR ASSUMPTIONS The typical heat generation data given in the NUREG CR-2397 Appendix C is applied in this EA. This typical tabulated data may not be the lower bound of the heat generation.

Nonetheless, the impact due to the variation of heat generation should not be of any significance.

4.0 ANALYSIS APPROACH 4.1 HEAT LOAD CALCULATION Afterheat power or heat generation rate of uranium-fueled PWR fuel computed by the SAS2/0RIGEN-S method for typical and conservative irradiation histories are provided in Appendix C of NUREG/CR-2397 (Ref. 2.1.3). A simple procedure for afterheat power calculation by linear interpolation of the tabulated data is also provided. (Pg. 71, Ref. 2.1.3). The conservative data in Appendix C of NUREG/CR-2397 was used in the SAR to calculate maximum heat load for the VSC-24 system. The typical data which provides lower heat rate is used for the purpose of calculating the minimum temperature of the MSB shield lid plate. Sheet _5 _ Rev # 0 Reference/Comment 

PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22  

.....,,,., .. 4.2 THERMAL HYDRAULIC CALCULATION The dry spent fuel assemblies inside the MSB generate heat that is transferred to the MSB outer shell. When the MSB is placed inside a VCC, heat from the MSB shell is convected to the air in the gap between the MSB shell and the VCC inner liner, and radiated to the VCC internal liner. The heat from the VCC internal liner is also convected to the air and a small amount is conducted through the VCC shell to the exterior.

The heated air in the gap between the MSB shell and VCC inner liner rises and exits through the top vents and is replaced by the 0°F ambient air entering through the bottom vents (natural convection).

On a sunny day additional heat enters the exterior surfaces of the VCC as solar radiation and is convected and radiated to the environment from the VCC surfaces.

However, for the purpose of this EA, the solar energy is conservatively neglected.

5.0 ANALYSIS .1 HEAT LOAD CALCULATION The detailed heat load calculation is provided in Attachment A*and the following is a summary of the Analysis.

However, a plot of afterheat power as a function of bumup (Figure A.1 , Attachment A of this report) shows that the heat load is nearly linear with respe_ct to the burnup when the burnup level is low. Therefore, an approximate data for a lower bound burnup value of 1 O GWD/MTU could be generated by a linear extrapolation.

Plots of afterheat curves of many burnup levels are shown in Figure A.2 of Attachment A of this report 5.1.2 Heat Load Rate lnteroolation Functions for a Given Burnup Value at a Given Time A two dimensional (burnup and time) linear interpolation function for the above afterheat power data is setup using a MATHCAD linear interpolation function.

The function KW(t,b)in the attachment A is the afterheat powers of burnup level b (GWD/MTU) at time t (days). Sheet _6_ Rev # 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 Im' 5.1.3 Check the Heat Load Rate Interpolation Functions Against the Input Data A check for the heat load rate function KW(t,b) with the input data was performed in section 4.0 of the Attachment A to verify that the interpolation function reproduces the data given in Appendices C of NUREG/CR-2397.

The result indicates that the interpolation function successfully reproduce the input data. 5.1.4 Check the Heat Load Rate Interpolation Functions With the Heat Load of CMBS-04 Provided in Reference 2.1.5 Heat load 'of CMSB-04 calculated in Reference 2.1.6 is 9.34 KW. This value was based on the conservative data in the Appendix C of NUREG/CR-2397.

The total heat load of CMSB-04 calculated in Section A.5 of Attachment A using the interpolation function KW(t,b) is 9.023 KW. The total calculated heat load is 3.8% lower than the total heat load reported in Reference 2.1.6. The deviation is the about the same deviation of the "typical" and "conservative" data in NUREG/CR 2397, Table C.2, Case 3 at cooling time=10 years. This result is an additional validation of the interpolation function.

5.1.5 Heat Generation Rate Calculation Fuel data of each fuel cell of each loaded CMSB is available in Reference 2.1.5 and is included in the Attachment B of this EA. Data used in heat generation rate calculation includes:

Initial weight of Uranium (MTU) Bum-up (MWD/MTU)

Discharge date MSB loading date The total cooling time t (day) is the sum of time from the fuel bundle discharge date to the date of loading into MSB plus the storage time period of 20 years and 50 years. The evaluation period of 20 years and 50 years are based on the minimum design life requirements specified in 1 OCFR72,236(g) and the design life stated in SAR, respectively.

The total cooling time t (day) and the,burn-up b (MWD/MTU) are substituted into the interpolation function KW (t,b) to obtain the afterheat power per unit weight of Uranium. The heat generation rate for each cell is the afterheat power times the initial -Uranium weight Sheet _7_ Rev # 0 Reference/Comment  

-@>:.: emwn* &ii PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEIT EA-SC-93-083-22 and converted to Kilowatt.

The total heat generation is the sum of heat generation of each of 24 cells of the MSB. From the fuel data in Attachment B, the total heat load of CMSB-03 is the lowest heat rate of the four CMSBs. The total heat generation rates of CMBS-03 and -04 after 20 years and 50 years in storage are calculated and presented in Tables A.1 through A.4 respectively.

The result shows that CMSB-03 has the lowest heat generation rate which is 5.97 KW and 3.883 KW after 20 years and 50 years of storage respectively.

5.2 THERMAL HYDRAULIC CALCULATION 5.2.1 Analysis Models A detailed description of the heat transfer mechanism inside a MSBNCC assembly (VSC-Ventilated Storage Cask}, applicable heat transfer models and the governing equations are included in the SAR Section 4.4.1 (Ref. 2.1.1 ). The SAR Figure 1.1.1 (Ref. 2.1.1) illustrates the VSC and its components.

The MSB contains dry fuel assemblies that generates heat which is transferred to the MSB shell. The heat from the MSB shell is transferred to the air in the gap between the MSB Shell and the concrete cask liner, and to the concrete cask. The hot air in the gap between the MSB shell and the concrete cask liner rises and exits through the aif outlet at the top and is replaced by the air entering at the bottom air inlet duct. Most of the heat is transferred to the environment by the* above natural convection and a small amount is transferred through the concrete cask. The heat rate generated by the fuel inside the MSB, any applicable solar radiation, ambient temperature and temperature of the air flowing through the gap between the MSB shell and the concrete cask liner are the main parameters affecting the temperature distribution in the MSB and the VCC. The air temperature in the gap at various elevations is a function of the heat generation rate, the ambient temperature and the convective mass flow rate. The mass flow rate is dependant on the amount of heat removed by natural convection, the flow resistance ill the natural convection flow path Sheet _8 _ Rev # 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 and the ambient temperature.

The relationship among the above variables is defined the SAR Equation 4.1 (Ref. 2.1.1, Section 4.4.1.1 ). 5.2.2 Convective Air Flow and Temperature Calculations The air flow up the annular gap between the MSB shell and the VCC inner liner is calculated by determining the sum of the flow pressure losses due to all entrances, bends, straight sections, expansions, contractions and exits and equating to the pressure differential caused by heating the air( i.e. stack or furnace effect). The governing equations are defined in the SAR Section 4.4.1.1 (Ref. 2.1.1 ). The equation can be iteratively solved by assuming a VCC air outlet temperature and checking to see whether the left hand side of SAR Equation 4.2 (stack pressure) is equal to the right hand side (flow pressure loss): If the left hand side is lower, then the assumed outlet temperature should be increased and if it is higher then the outlet temperature should be reduced. Once the value of air outlet temperature is determined, the air mass flow rate and the air temperature at various elevations of the annular air gap can be easily calculated.

Attachment C of Reference 2.1.2 contains the details of the calculation procedure.

The final iteration of the air flow and temperature calculation is included in the VCC Body and MSB Exterior Thermal Model discussed below. 5.2.3 VCC Body and MSB Exterior Thermal Model The heat transfer model of the VSC (including the simplified model of the MSB) is explained in the SAR Section 4.4.1.2 (Ref. 2.1.1 ). The heat transfer analysis of the VSC is performed using the ANSYS computer program and the applicable VSC ANSYS Thermal Model is shown on the SAR Figure 4.4-2 (Ref. 2.1.1 ). The generic ANSYS input data for the above model and the instructions for using the ANSYS model for performing a thermal analysis of the VSC is included in Attachment D of Reference 2.3.1. The above can be* used to perform a steady state or transient analysis of the VSC. The final iteration of the Convective Air Flow and Temperature Calculations, similar to those in References 2.3.1 is also included in the ANSYS model. Therefore there is no need for a separate spread sheet calculations to document the convective air flow and bulk air temperature calculations.

The ambient temperature, the MSB heat generation rates at the end of 20 years and 50 years of storage, air flow loss coefficient, average specific heat of air (CPAI), average air density(DENA) and the Sheet _9_ Rev # 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 assumed VCC outlet air temperature (TOAS) are the input to this ANSYS input deck. The ANSYS output must be reviewed to ensure that the flow pressure loss (DP FLOW) is equal to the pressure change due to air heating (DP STACK) and that the calculated air outlet temperature (TOCA) matches to the assumed value (TOAS). The formulas for average specific heat (CPAI) and average density (DENA) are modified to the air properties at 0°F. The temperature distribution in the VCC and the MSB shell outside surface are the output from this analysis.

5.2.4 Computer Input Deck The ANSYS thermal hydraulic analysis for a VSC is performed in two parts. They are: 1. the iterative air flow calculations for determining the air mass flow rate and bulk air temperatures, 2. the computer analysis of MSBNCC using the ANSYS program. The iterative air flow calculations are explained in Attachment C of EA-SC-93-83-10 (Ref. 2.3.1). The calculations are used to calculate the assumed value of the VCC air outlet temperature for input into the VCC ANSYS Model. The applicable formulas are included in the VCC ANSYS model. However, ANSYS program cannot perform the iterative calculations.

The air flow calculations should be manually performed to calculate the value of the VCC air outlet temperature and the value should be input into the VCC ANSYS model. The VCC ANSYS analysis documents the final iteration of the air flow calculation and therefore there is no need to document the air flow calculations The ANSYS computer model of the VCC includes the final iteration of the air flow calculation is provided in Attachment C of this EA (File MSB3-20 and MSB3-50 dated 08/02/95).

These two files are modified from the generic model provided in Attachment C of Reference 2.3.1. The modification includes:

The heat generation rates -5.97 KW for MSB-03 after 20 years of storage -3.885 KW for MSB-03 after 50 years of storage Sheet 10 Rev# 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 and the following air properties which are applicable for 0°F ambient condition:  

-Air specific heat CPAI = 0.239 -Air density: DENA= 0.081+ 0.005*(32-TAKE)/32 These values are from SAR (Ref. 2.1.1, page 4-5 ) 5.3 ANALYSIS PERFORMED The steady state thermal analysis of a loaded VSC was performed for the combinations of following operating conditions:

: a. Heat Gen. 5.97 KW, Amb O °F, No Solar Load b. Heat Gen. 3.885 KW, Amb O °F, No Solar Load 5.3.1 List of Computer Input Files Input Name Date MSB3-20 MSB3-50 Computer Input Files (No File Extension)

* Analysis Description 08/02/95 08/02/95 Heat Gen. 5.97 KW, Amb o °F Heat Gen. 3.885 KW, Amb o °F 5.3.2 List of Computer Output Files Output Name . MSB3-20.0UT MSB3-50.0UT Table 5.3.2 Computer Output Files Date 08/02/95 08/02/95 Analysis Description Heat Gen. 5.97 KW, Amb o °F Heat Gen. 3.883 KW, Amb o °F 5.3.3 Summary of MSB Shell Temperatures The steady state temperature distribution of the MSB shell outside surface are included in the computer output files listed in Section 5.3.2 (Attachment D of this E). The temperature distribution resulted from the above analyses is presented in Figure 1 and 2. The lowest temperature of the MSB shield lid is 22°F after 20 years and 16°F after 50 years when the ambient temperature is 0°F. ' I Sheet 11 Rev # 0 Reference/Comment PALISADES NUCLEAR PLANT ANALYSIS CONTINUATION SHEET EA-SC-93-083-22 5.3.4 Warning Massages The ANSYS/PREP contain warning messages related to the shape of the Element No. 29 which represents the gap between the MSB bottom plate and the fuel assembly.

The effect of these warning messages, if there is any, should only pertain to the Element 29. These warning messages have been reviewed and determined to be inconsequential to the results of this EA. There should be no impact on the predicted temperature of the shield lid. 6.0 RESULTS AND CONCLUSIONS CMSB-03 had the lowest heat generation rates among CMSB-01 through CMSB-04. The heat generation rates were 5.97KW and 3.883KW after 20 years and 50 years in storage with 0°F ambient temperature.

The result of the ANSYS thermal hydraulic analysis indicates that the lowest temperature of the MSB shield lid plate is 22°F for the case of 20 years and 16°F for the case of 50 years of storage. The typical tabulated data used in this analysis may not be the lower bound of the heat generation.

As stated in Subsection 5.1.3, the deviation of the "typical" and "conservative" data in NUREG/CR2397 is about 3.8%. The lower bound of heat generation and the lowest temperature of the MSB shield lid plate can be predicted by using the deviation between the typical and conservative (3.8%). The impact due to the variation of the heat load data presented in NUREG/CR2397 is not significant.

Sheet 12 Rev# 0 Reference/Comment

* VCC THERMAL CHARACTERISTICS FOR S-* 11 A,'ok: VSC:tl 3; !>.<t1 kW .... *,\ KW HEAT LOAD {v.sc.:#-jJ MTEfl.. 2D f*ars . *,+u  

= o EA-SC_ q; -083-22 13 /]------------------------------------.

l 'l '&#xa5; I LEGEND: Node lxxx! Temperature xxx FIG-VR..E t ... I TE 4# Pe B_A Tuj.,&#xa3; Page 1 , DIS TR.I !JUTiON .z.o /'EA-"1-S

* l1/\}) () R.G:su.1-rs vcc THERMAL CHARACTERISTICS FOR g.ggs-KW HEAT LOAD {vsc.:#" ..3) Alo fe : VSC:# 3 =-3. '2 s-!< w Mi e1t s-o Y*CU .s ...

i11>> /'( 0 lr'+ s I fij] . *= f 'flo 2o 0 . ",\ il:&#xa3;I] /0 0 ... :* /]._ __________________________________

* Discharge Date ,Cell Wt(MTU) .month Day ,Year ,i + 1 ,Initial_

U i 0.415 30.26 2 0.415 33.027 3 0.415 33.027 4 0.387 35.117 5 0.4 12.99 6 0.386 35.333 7 0.385 35.333 8 0.387 31.414 9 0.402 13.366 IO 0.402 13.911 11 0.401 12.99 12 0.416 28.128 13 0.416 28.824 14 0.387 35.117 15 0.402 13.626 16 0.401 13.626 17 0.387 35.117 18 0.415 30.26 19 0.416 28.128 20 0.386 35.173 21 0.387 35.173 22 0.416 33.027 23 0.416 30.26 24 0.415 30.353 .Total Heat Load .DDatei,O .DDatei, l 8 29 8 29 8 29 8 12 6 8 29 8 29 8 12 6 6 6 8 29 8 29 8 12 6 6 8 12 8 29 8 29 8 12 8 12 8 29 8 29 8 29 23 ,TotalHeat

:= L HeatLoadi i=O ,TotalHeat

= 9.034 Kw .DDatei 2 81 81 81 83 78 81 81 83 78 78 78 81 81 83 78 78 83 81 81 83 83 81 81 81 EA-SC-93-083-22 ATIACHMENTA PAGE7 File Name: NUREG.MCD ,Cooling Time (Days) ,timei JieatLoadi 4677 0.425 4677 0.475 4677 0.475 3964 0.497 6005 0.133 4677 0.471 4677 0.47 3964 0.433 6005 0.134 6005 0.147 6005 0.134 4677 0.396 4677 0.411 3964 0.497 6005 0.147 6005 0.147 3964 0.497 4677 0.425 4677 0.396 3964 0.496 3964 0.497 4677 0.477 4677 0.426 4677 0.425 .The total heat load for MSB-04 calculated in EA-HAR-94-01, Attachment 9 is 9.38. The deviation of the two calculated value is (9.38-9.034)  

/ 9.034= 3.8%. Note that the conservative data from Appendix C of NUREG/CR-2397 was used in EA-HAR-94-01.

2397, Table C.2, case 3, 10 years cooling time. Therefore, the heat load calculation is verified .

* * * ,7 .0 Heat load *after 20 years in storage for VCC number 3 ,timei *= timei + 20* 365 Kw(time. ,BumUp.)*Initial U. JleatLoad.

:= ---1---1 ----1 I 1000 EA-SC-93-083-22 ATIACHMENTA PAGES File Name: NUREG.MCD ,Table A. 1 Heat Load of MSB-3 after 20 years in storage Discharge Date ,Cell ,Wt(MTU) month Day ,Year .Cooling Time (Days) .i + l Jnitial_Ui

!>Date. 0 DDate. 1 l, 1, DDatei,l ,timei JleatLoadi 0.415 30.26 8 29 81 11977 0.282 2 0.415 33.027 8 29 81 11977 0.314 3 0.415 33.027 8 29 81 11977 0.314 4 0.387 35.117 8 12 83 11264 0.322 5 0.4 12.99 1 6 78 13305 0.093 6 0.386 35.333 8 29 81 11977 0.311 7 0.385 35.333 8 29 81 11977 0.31 8 0.387 31.414 8 12 83 11264 0.281 9 0.402 13.366 6 78 13305 0.093 10 0.402 13.911 6 78 13305 0.102 11 0.401 12.99 1 6 78 13305 0.093 12 0.416 28.128 8 29 81 11977 0.263 13 0.416 28.824 8 29 81 11977 0.273 14 0.387 35.117 8 12 83 11264 0.322 15 0.402 13.626 1 6 78 13305 0.102 16 0.401 13.626 l 6 78 13305 0.102 17 0.387 35.117 8 12 83 11264 0.322 18 0.415: 30.26 8 29 81 11977 0.282 19 0.4'16' 28.128 8 29 81 11977 0.263 20 0.386 35.173 8 12 83 11264 0.321 21 0.387 35.173 8 12 83 11264 0.322 22 0.416 33.027 8 29 81 11977 0.315 23 0.416 30.26 8 29 81 11977 0.283 24 0.415 30.353 8 29 81 11977 0.282 

* *

* Total Heat Load after 20 years T ota!Heat : = 23 I: HeatLoad.

I i = 0 Tota!Heat

= 5.97 Kw 8.0 Heat load after 50 years in storage for MSB number 3 time. :=time.+ 30-365 I I Kw(time.,BumUp.)*Initial U. HeatLoad. : = 1 1 -1 I 1000 EA-SC-93-083-22 ATTACHMENT A PAGE9 File Name: NUREG.MCD Table A.2 Heat Load of MSB-3 after 50 years in storage Discharge Date Cell Wt(MTU) (MWDIMTU) month Day Year Cooling Time (KW) (Days) i + 1 Initial U. -I BumUp. I 0.415 30.26 2 0.415 33.027 3 0.415 33.027 4 0.387 35.117 5 0.4 12.99 6 0.386 35.333 7 0.385 35.333 8 0.387 31.414 9 0.402 13.366 10 0.402 13.911 11 0.401 12.99 12 0.416 28.128 13 0.416 28.824 14 0.387 35.117 15 0.402 13.626 16 0.401 13.626 17 0.387' 35;117 18 0.415 30.26 19 0.416 28.128 20 0.386 35.173 21 0.387 35.173 22 0.416 33.027 23 0.416 30.26 24 0.415 30.353 DDate. 0 I, DDate. 1 I, 8 29 8 29 8 29 8 12 6 8 29 8 29 8 12 6 6 6 8 29 8 29 8 12 . 1 6 6 8 12 8 29 8 29 8 12 8 12 8 29 8 29 8 29 DDate. 2 I, 81 81 81 83 78 81 81 83 78 78 78 81 81 83 78 78 83 81 81 83 83 81 81 81 time. HeatLoad.

I I 22927 22927 22927 22214 24255 22927 22927 22214 24255 24255 24255 22927 22927 22214 24255 24255 22214 22927 22927 22214 22214 22927 22927 22927 0.185 0.205 0.205 0.208 0.06 0.202 0.202 0.183 0.06 0.066 0.06 0.173 0.179 0.208 0.066 0.066 0.208 0.185 0.173 0.207 0.208 0.205 0.185 0.185 

* *

-L i = 0 HeatLoad.

l Total.Heat

= 3.885 Kw 9.0 Heat load after 20 years in storage for MSB number 4 dd : = READPRN( rnsbn4) . . dd<o> Initial U : = ---106 <o> <2> DDate :=dd DDate<2> :=dd<4> dd<l> BUi:nUp : = --1000 time. :=num.day(DDate.

0 ,DDate. 1 ,DDate. 2) + 20*365 l l, l, 1, Heat load per cell an loading Kw(time.,BumUp.)*Initial U. HeatLoad.

: = 1 1 -1 l 1000 r * --:-93-083-22

." ' ' '\CHMENT A PAGE10 File Name.: NUREG.MCD 

* EA-SC-93-083-22 A TT AC HM ENT A PAGE 11 File Name: NUREG.MCD Table A.3 Heat Load of MSB-4 after 20 years in storage Cell Wt(MTU) (MWD/MTU) i + 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Initial U. -I BurnUp. I 0.415 30.343 0.415 30.26 0.416 30.585 0.387 35.117 0.402 13.626 0.416 30.585 0.415 30.343 0.387 35.117 0.401 13.626 0.404 13.366 0.401 13.11 0.415 30.353 0.414 33.629 0.388 33.517 0.401 13.366 0.387 35.333 0.387 34.93 0.415 33.629 0.415 31.787 0.387 33.517 0.387 35.173 0.415 30.26 0.416 30.26 0.401 12.99 Total Heat Load after 20 years Discharge Date month Day Year DDate. 0 I, DDate. 1 I, DDate. 2 l, 8 29 81 8 29 81 8 29 81 8 12 83 1 6 78 8 29 81 8 29 81 8 12 83 6 78 6 78 6 78 8 29 81 8 29 81 8 12 83 6 78 8 29 81 8 12 83 8 29 81 8 29 81 8 12 83 8 12 83 8 29 81 8 29 81 6 78 23 T otalHeat : = L HeatLoad.

= 6.035 Kw Cooling Time (KW) (Days) time. I 11977 11977 11977 11264 13305 11977 11977 11264 13305 13305 13305 11977 11977 -11264 13305 11977 11264 11977 11977 11264 11264 11977 11977 13305 HeatLoad.

0.282 0.282 0.293 0.322 0.102 0.293 0.282 0.322 0.102 0.094 0.093 0.282 0.324 0.313 0.093 0.312 0.322 0.324 0.303 0.312 0.322 0.282 0.283 0.093 l 

* 1 a.a Heat load after 50 years in storage for MSB number 4 time. :=nwnday(DDate.

0 ,DDate. 1 ,DDate. 2) + 50*365 l 1, l, l, Heat load per cell on loading Kw(time., Burn Up.)* Initial U. HeatLoad.

: = 1 1 -1 I 1000 EA-SC-93-a83-22 ATIACHMENTA PAGE12 File Name: NUREG.MCD Table A.4 Heat Load of MSB-4 after sa years in storage Cell Wt(MTU) (MWD/MTU) month Burn Up. I DDate. 0 1, i + l Initial U. -I 0.415 30.343 8 2 0.415 30.26 8 3 0.416 30.585 8 4 0.387 35.117 8 5 0.402 13.626 1 6 0.416 30.585 8 7 0.415 30.343 8 8 0.387 35.117 8 9 0.401 13.626 l 10 0.404 13.366 1 11 0.401 13.11 1 12 0.415 30.353 8 13 0.414 33.629 8 14 0.388 33.517 8 15 0.401 13.366 16 0.387 35.333 8 17 0.387 34.93 8 18 0.415 33.629 8 19 0:415. 31.787 8 20 0.387 33.517 8 21 0.387 35.173 8 22 0.415 30.26 8 23 0.416 30.26 8* 24 0.401 12.99 Discharge Date Day Year DDate. 1 I, DDate. 2 1, 29 81 29 81 29 81 12 83 6 78 29 81 29 81 12 83 6 78 6 78 6 78 29 81 29 81 12 83 6 78 29 81 12 83 29 81 29 81 12 83 12 83 29 81 29 81 6 78 Cooling Time (KW) (Days) time. HeatLoad.

I 22927 22927 22927 22214 24255 22927 22927 22214 24255 24255 24255 22927 22927 22214 24255 22927 22214 22927 22927 22214 22214 22927 22927 24255 0.185 0.185 0.192 0.208 0.066 0.192 0.185 0.208 0.066 0.061 0.06 0.185 0.211 0.202 0.06 0.203. 0.208 0.211 0.198 0.202 0.208 0.185 0.185 0.06 I 

* *

* Total Heat Load after 50 years 11.0 Result Summary 23 Tota!Heat

:= 2: HeatLoad.

= 3.925 Kw Table A.5 : Heat Generation Rate of MSB-03 and MSB-04 20 years 50 years MSB-03 5.97-KW 3.885-KW MSB-04 6.035-KW 3.925-KW EA-SC-93-083-22 ATTACHMENT A PAGE13 File Name: NUREG.MCD 

* Attachment B (4 pages) FUEL DATA EA-SC-93-083-22 Attachment B Rev.: 0 Page Bl  

_ 2 2-/+TT ACH AA ENT I; PA-<iE r;2 MSB Number: 1 Date MSB Loaded: oS"-07-93@003'-f Isl asse"'"f Storage Pad Position:

.1. Placement Date: M0.1 I 2 1 l'1Cf3 Comments:

Date Exam Date 1 G-01 3.00 386,946 33,997.0 08-12-83 09-25-92 2 G-02 3.00 387,078 33,997.0 II 09-25-92 3 G-03 3.00 386,901 33,997.0 n 09-25-92 4 G-04 3.00 387,469 31,413.8 II 09-25-92 5 G-05 3.00 387,077 33,997.0 II 09.:.25-92 6 G-06 3.00 387,248 33,997.0 n 09-25-92 7 G-07 3.00 387,815 33,997.0 II 09-25-92 8 G-08 3.00 387,372 33,997.0 II 10-05-92 9 G-09 3.00 388,101 33,516.6 II 10-05-92 10 G-10 3.00 387,117 33,997.0 II 10-05-92 11 G-11 3.00 388,019 33,516.6 II 10-05-92 12 G-12 3.00 387,677 31,413.8 II 10-05-92 13 G-13 3.00 387,921 30,972.2 II 10-05-92 14 G-14 3.00 387,670 32,722.6 II 10-05-92 .-. 15 G-15 3.00 388,214 32,722.6 II 09-24-92 16 G-16 3.00 387,915 30,972.2 II 10-08-92 17 G-17 3.00 386,138 32,410.2 II 10-08-92 18 G-18 3.00 387,127 34,929.8 II 10-08-92 19 G-20 3.00 387,491 32,410.2 II 10-08-92 20 G-21 3.00 385,931 30,972.2 n 10-09-92 21 G-22 3.00 _-387,641 32,410.2 II 10-09-92 22 G-23 3.00 387,841 32,410.2 II 10-09-92 23 G-24 3. 00. 387,677

* 3 0, 9 72. 2 II 10-09-92 . 24 G-25 3.00 387,993 32,722.6 II 10-09-92 

* C:A,SC-08 -2. 2 A-TTlrCH MEN7 .g VSC-24 STORAGE SHEET PA-G-E MSB Number: Z VCC Number: z.. Date MSB Loaded: 5-JlJ-Cf 3 Storage Pad Position:

2 Placement Date: 5--16-93 Comments:

PUEL ASSEMBLY LISTING Fuel Assembly Parameters ID No Initial U Initial U Burn up Discharge Visual Enr (w/o) Wt (g) (MWD/MTU)

Date Exam Date 1 G-27 3.00 386,612 32, 722. 6 08-12-83 10-09-92 2 G-28 3.00 386,663 31,413.8 n 10-09-92 3 G-29 3.00 386,449 34,929.8 n 09-24-92 4 G-31 3. 00 . 387,923 31,413.8 II 10.-09-92 5 G-32 3.00 387,452 33,516.6 II 10.:.09-92 6 G-33 3.00 388,150 33,516.6 n 10-09-92 7 G-34 3.00 387,834 33,516.6 *n 10-09-92 8 G-37 3.00 387,458 .31,413.8 n 09-25-92 9 G-38 3.00 386,736 34,929.8 II 10-09-92 10 G-39 3.00 387,441 31,413.8 II 09-25-92 11 G-40 3.00 387,700 32,722.6 II 10-09-92 12 G-41 3.00 387,494 32,722.6 II 09-25-92 1.3 G-43 3.00 388,586 32,410.2 II 10-09-92 14 G-44 3.00 386,959 32,410.2 II 10-09-92 15 G.-45 3.00 388,062 30,972.2 II 10-09-92 16 G-46 3.00 387,235 34,929.8 II 10-09-92 17 G-48 3.00 387,739 32,410.2 II 10-14-92 18 G-50 3.00 387,813 32,410.2 II 09-25-92 19 G-53 3.00 386,913 34,929.8 II 10-14-92 20 G-54 3.00 386,371 34,929.8 n 10-14-92 21 G-57 3.00 . 387, 399 30,972.2 II 10-14-92 22 G-59 3.00 387,242 34,929.8 II 10-14-92 23 G-60 3.00 386,196 32,722.6 II 10-14-92 I 24 G-63 3.00 386,985 30,972.2 II 10-14-92

* VCC Number: Date MSB Loaded: Storage Pad Position:

Of?-2.2-A-TT AC..tf A.I E: N 7 PMiE &If 3 3 Placement Date: 6/30/94 FUEL ASSEMBLY LISTING Fuel Assembly Parameters Initial U Initial U Burn up Discharge Visual Enr (w/o) Wt <al lMWD/MTlJ)

Date Exam Date 2.74 415,213 30,260 08/29/81 04/07/94 2.74 415,470 33,027 08/29/81 04/11/94 . 2.74 415,208 33,027 08/29/81 04/11/94 " 3.00 386,826 35,117 08/12/83 01/24/94 . 1.51 400,106 12,990 01/06/78 04/07/94 : 3.05 385,792 35,333 08/29/81 01/19/94 3.05 385,292 35,333 08/29/81 04/06/94 3.00 387,137 31,414 08/12/83 03/18/93 1.5 401,697 13,366 01/06/78 01/19/94 1.5 401,583 13,911 01/06/78.

04/06/94 1.5 400,690 12,990 01/06/78 04/08/94 2.74 415,913 28,128 08/29/81 03/21/94 2.74 416,121 28,824 08/29/81 03/21/94 3.00 387,028 35, 117 *08/12/83 04/07/94 1.5 401,962 13,626 01/06/78 04/05/94 1.51 401,039 13,626 01/06/78 04/08/94 3.00 386,875 35,117 08/12/83 03/30/94 2.74 415,481 30,260 08/29/81 03/21/94 2.74 415,795 28,128 08/29/81 03/25/94 3.00 386,489 35,173 08/12/83 03/31/94.

3.00 386,901 35,173 08/12/83 04/04/94 2.74 415,751 33,027 08/29/81 01/13/94 2.74 415,660 30,260 08/29/81 04/05/94 2.74 415432 30353 08/29/81 04/11/94

* VCC Number: Date MSB Loaded: -Storage Pad Position:

* 6 EFOOOZ 7 EF001G 8 G062 9 XF22 10 XF30 11 XF46 12 EF001H 13 EF001J 14 G065 15 XF51 16 E065 17 G066 18 EF001K 19 EF001R 20 G067 21 G030 22 EF0006 23 EF0010 24 XF53 * .eA--s c -. q? -0 .v.; -2 z., VSC-24 STORAGE SHEET A.I ENT &5 4 MSB Number: Placement Date: FUEL ASSEMBLY LISTING Fuel Assembly Parameters Initial U Enr (w/o) 2.74 2.74 2.75 3.00 1.50 2.73 2.74 3.00 1.51 1.50 1.50 2.74 2.73 3.00 1.50 3.05 3.00 2.73 2.74 3.00 3.00 2.74 2.74 1.51 Initial U wt (a) 415,192 415,199 415,810 387,249 401,817 415,647 415,453 387,358 401,013 404,306 401,473 415,333 414,477 387,876 401,056 386,524 386,896 415,010 414,830 387,422 386,654 415,135 415,726 400975 EAvg XFAvg . GAvg Burn up (MWD/MTU) 30,343 30,260 30,585 35, 117 13,626 30,585 30,343 35,117 13,626 13,366 13, 110 30,353 33,629 33,517 13,366 35,333 34,930 33,629 31,787 33,517 35,173 30,260 30,260 12 990 29585 17071 34562 Heat Discharge Visual Load Date Exam Date (KW) 08/29/81 03/30/94 0.4152 08/29/81 03/31/94 0.4152 08/29/81 01/10/94 0.4158 08/12/83 04/08/94 0.5034 01/06/78 01/18/94 0.2009 08/29/81 04/04/94 0.4156 08/29/81 04/11/94 0.4155 08/12/83 01/20/94 0.5036 01/06/78 03/31/94 0.2005 01/06/78 04/07/94 0.2022 01/06/78 01/14/94 0.2007 08/29/81 04/11/94 0.4153 08/29/81 04/11/94 0.4559 08/12/83 03/28/94 0.5042 01/06/78 04/06/94 0.2005 08/29/81 04/05/94 0.4638 08/12/83 01/21/94 0.5030 08/29/81 04/11/94 0.4565 08/29/81 04/05/94 0.4563 08/12/83 03/30/94 0.5036 08/12/83 04/08/94 0.5027 08/29/81 04/11/94 0.4151 08/29/81 04/11/94 0.4157 01/06/78 01/18/94 0.2005 Total Ht I 9.381

* *

* EA-SC-93-083-22 Attachment C Rev.: 0 Page Cl Attachment C ) ANSYS INPUT DECK

* * * /PREP7 /TITLE VCC-MSB-3 AMB= 0.0 F 5.97 KW AFTER 20 YEARS IN STORAGE /SHOW,BNCHVCC2,GEO,, /SHRINK, .3 KAN,-1 -GGGG=5.97

* Total Heat Generation of MSB assenilly KW/MSB y AAAA=0.00

* ClElll. friction Loss K For Air Flow TOAS=29.846

* Assuned Value; Must match TOCA; Outlet Air F DRHI=13.69167

* Air at Bott of MSB TAVE=((AAAA+TOAS)/2)

* Total heat generation BTU/Hr v-CPAl=0.2390

C*** Calculated Air outlet TOCA lllJSt be equal to assl.Jlled value TOAS C*** ********************************************************************

* MUST BE EQUAL TO 11 TOAS" Air outlet F Q016=CGGGG*3412.0*0.69*16.0/144.0)

* Heat Gen El. 0 -16 In BTU/hr Q032=CGGGG*3412.0*1.08*16.0/144.0)  

*Heat Gen El. 16 -32 In BTU/Hr Q048=(GGGG*3412.0*1.20*16.0/144.0)

* Heat Gen El. 32 -48 In BTU/Hr Q064=(GGGG*3412.0*1.19*16.0/144.0)  

*Heat Gen El. 48 -64 In B'l'U/Hr Q080=(GGGG*3412.0*1.17*16.0/144.0)  

*Heat Gen El. 64 -80 In BTU/Hr Q096=(GGGG*3412.0*1.12*16.0/144.0)  

*Heat Gen El. 80 -96 In BTU/Hr Q112=CGGGG*3412.0*1.05*16.0/144.0)  

*Heat Gen El. 96 -112 In BTU/Hr Q128=CGGGG*3412.0*0.90*16.0/144.0)

* Heat Gen El. 128 -144 In BTU/Hr T016=CTOOO+Q016/(3600.0*CPAl*MFLO))  

*Air at 16 In. T032=CT016+Q032/(3600.0*CPAl*MFLO))

* Air at 32 In. T048=CT032+Q048/(3600.0*CPAl*MFLO))

* Air at 48 In. T064=CT048+Q064/(3600.0*CPAl*MFL0))

* Air at 64 In. T080=(T064+Q080/(3600.0*CPAl*MFL0))

* Air at 80 In. T096=(T080+Q096/(3600.0*CPAl*MFL0))

* Air at 96 In. T112=CT096+Q112/(3600.0*CPAI*MFL0))  

*Air at 112 In. T128=CT112+Q128/(3600.0*CPAl*MFL0))  

*Air at 128 In. T144=CT128+Q144/(3600.0*CPAl*MFL0))

* Air at 144 In. C*** ELEMENT TYPE MODULE C*** DEFINES THE ELEMENT TYPES ET,1,70

* STIF 31 RADIATION LINK ELEMENTS C*** OPTIONS MODULE C*** DEFINES''ANALYSIS OPTIONS KYPOST,O TOFFST,460  

*Used for Rad. T Abs= T F + 460 F C*** END OF OPTIONS MODULE C*** MATERIAL MODULE C*** DEFINES MATERIAL PROPERTIES BTU/hr-ft-F C*** Conduction Elements Kxx=Kyy MP,KXX,1,26.2

* MPTEMP,1,-50,0,32,100,200,300 MPTEMP,7,500,700 . MPDATA,KXX,3,1,0.0114,0.0130,0.0140,0.0154,0.0174,0.0193 MPDATA,KXX,3,7,0.0231,0.0268 MP,KXX,4,2.38

* EA-SC-93-083-22 ATTACHMENT C Page C2 

* EMIS CARDS MP,EMIS,1,.8 MP,EMIS,2,.9 MP ,EMIS,3, .85 MP,EMIS,6,.85 MP,EMIS,7,.85 MP,EMIS,8,.85 C*** END OF MATERIAL MOOULE C*** REAL CONSTANT MOOULE R,1 *FOR STIF55 Elements C*** Real Const.For Radiation Area,From Geo.Fact.,Emiss, SBC R,97,0.4400,0.140,0.9,0.17140E*08 R,98,0.4800,0.140,0.9,0.17140E*08 R,99,0.0500,0.140,0.9,0.17140E*08 R,100,0.0250,0.140,0.9,0.17140E-08 R,101,0.0950,0.140,0.9,0.17140E-08 R,102,0.7188,0.140,0.9,0.17140E-08 R, 103,0.9600,0.140,0.9,0.17140E*08 R,104,0.9600,0.140,0.9,0.17140E-08 R,105,1.2793,0.140,0.9,0.17140E*08*

* R,129,0.3380,1.0,0.8,0.17140E-08  

R,130,0.4510,1.0,0.8,0.17140E*08 R,131,0.4510,1.0,0.8,0.17140E-08 R,132,0.6000,1.0,0.8,0.17140E*08 R,133,0.6020,1.0,0.8,0.17140E-08 R,134,0.4930,1.0,0.8,0.17140E-08 R, 135,0.4270,1.0,0.8,0.17140E*08 R,145,0.0606,1.0,0.8,0.17140E*08 R, 146,0.2470, 1.0,0.8,0.17140E*08 R,148,0.0606,1.0,0.8,0.17140E-08

R,149,0.1740,1.0,0.8,0.17140E-08

R,151,0.6650,1.0,0.9,0.17140E*08 R,166,0.1620,1.0,0.8,0.17140E*08 R,168,0.2400,1.0,0.9,0.17140E*08 C*** END OF REAL CONSTANT MOOULE C*** NOOE MOOULE C*** DEFINES NOOES BY DIRECT INPUT N,1,0.0000,0.00000,0.0000 N,2,1.2500,0.00000,0.0000 N,3,2.5208,0.00000,0.0000 N,4,2.5830,0.00000,0.0000 N,5,2.9170,0.00000,0.0000 N,6,3.0833,0.00000,0.0000 N,7,4.2708,0.00000,0.0000 EA-SC-93-083-22 ATTACHMENT C Page C3 

* N,8,5.5000,0.00000,0.0000 N,9,1.2310,0.21706,0.0000 N,10,2.4825,0.43773,0.0000 N,11,2.5438,0.44853,0.0000 N,12,2.8727,0.50653,0.0000 N,13,3.0365,0.53541,0.0000 N,14,4.2059,0.74162,0.0000 N,15,5.4164,0.95S06,0.0000 N,17,0.0000,0.00000,1.8333 N,18,1.2500,0.00000,1.8333 N,19,2.5208,0.00000,1.8333 N,20,2.5830,0.00000,1.8333 N,21,2.9170,0.00000,1.8333 N,22,3.0833,0.00000,1.8333 N,23,4.2708,0.00000,1.8333 N,24,5.5000,0.00000,1.8333 N,25, 1.2310,0.21706, 1.8333 N,26,2.4825,0.43773,1.8333 N,27,2.5438,0.44853,1.8333 N,28,2.8727,0.50653,1.8333 N,29,3.0365,0.53541,1.8333 N,30,4.2059,0.74162,1.8333 N,31,5.4164,0.95506,1.8333 N,33,0.0000,0.00000,2.0000 N,34,1.2500,0.00000,2.0000 N,35,2.5208,0.00000,2.0000 N,36,2.5830,0.00000,2.0000 N,37,2.9170,0.00000,2.0000 N,38,3.0833,0.00000,2.0000 N,39,4.2708,0.00000,2.0000 N,40,5.5000,0.00000,2.0000 N,41,1.2310,0.21706,2.0000 N,42,2.4825,0.43773,2.0000 N,43,2.5438,0.44853,2.0000 N,44,2.8727,0.50653,2.0000 N,45,3.0365,0.53541,2.0000 N,46,4.2059,0.74162,2.0000 N,47,5.4164,0.95506,2.0000 N,49,0.0000,0.00000,2.0417 N,50,1.2500,0.00000,2.0417 N,51,2.5208,0.00000,2.0417 N,52,2.5830,0.00000,2.0417 N,53,2.9170,0.00000,2.0417 N,54,3.0833,0.00000,2.0417 N,55,4.2708,0.00000,2.0417 N,56,5.5000,0.00000,2.0417 N,57,1.2310,0.21706,2.0417 . N,58, 2 .4825 ,0.43773,2.0417 N,59,2.5438,0.44853,2.0417 N,60,2.8727,0.50653,2.0417 N,61,3.0365,0.53541,2.0417 N,62,4.2059,0.74162,2.0417 N,63,5.4164,0.95506,2.0417 N,65,0.0000,0.00000,2.1040 N,66,1.2500,0.00000,2.1040 N,68,2.5830;0.00000,2.1040 N,69,2.9170,0.00000,2.1040 N,70,3.0833,0.00000,2.1040 N,71,4.2708,0.00000,2.1040 N,72,5.5000,0.00000,2.1040 N,73,1.2310,0.21706,2.1040 N,74,2.4825,0.43773,2.1040 N,75,2.5438,0.44853,2.1040 N,76,2.8727,0.50653,2.1040 N,77,3.0365,0.53541,2.1040 N,78,4.2059,0.74162,2.1040 N,79,5.4164,0.95506,2.1040 N,81,0.0000,0.00000,2.4375 N,83,2.5208,0.00000,2.4375 N,84,2.5830,0.00000,2.4375 EA-SC-93-083-22 ATTACHMENT C Page C4 

* I.

* N,85,2.9170,0.00000,2.4375 N,86,3.0833,0.00000,2.4375 N,87,4.2708,0.00000,2.4375 N,88,5.S000,0.00000,2.4375 N,90,2.4825,0.43773,2.4375 N,91,2.5438,0.44853,2.4375 N,92,2.8727,0.50653,2.4375

N,93,3.0365,0.53541,2.4375 N,94,4.2059,0.74162,2.4375 N,95,5.4164,0.95506,2.4375 N,97,0.0000,0.00000,5:1042 N,99,2.5208,0.00000,5.1042 N,100,2.5830,0.00000,5.1042 N,101;2.9170,0.00000,5.1042 N,102,3.0833,0.00000,5.1042

N,103,4.2708,0.00000,5.1042 N,104,5.50Q0,0.00000,5.1042 N,106,2.4825,0.43773,5.1042

N,107,2.5438,0.44853,5.1042 N,108,2.8727,0.50653,5.1042 N,109,3.0365,0.53541,5.1042 N,110,4.2059,0.74162,5.1042 N,111,5.4164,0.95506,5.1042 N,113,0.0000,0.00000,6.4376 N,115,2.5208,0.00000,6.4376 N,116,2.5830,0.00000,6.4376 N,117,2.9170,0.00000,6.4376 N,118,3.0833,0.00000,6.4376 N,119,4.2708,0.00000,6.4376 N,120,5.5000,0.00000,6.4376 N,122,2.4825,0.43773,6.4376 N,123,2.5438,0.44853,6.4376 N,124,2.8727,0.50653,6.4376 N,125,3.0365,0.53541,6.4376

N,126,4.2059,0.74162,6.4376 N,127,5.4164,0.95506,6.4376 N,129,0.0000,0.00000,9.1043 N,131,2.5208,0.00000,9.1043 N,132,2.5830,0.00000,9.1043

N,133,2.9170,0.00000,9.1043 N,134,3.0833,0.00000,9.1043 N,135,4.2708,0.00000,9.1043 N,136,5.5000,0.00000,9.1043 N,138,2.4825,0.43773,9.1043 N,139,2.5438,0.44853,9.1043 N,140,2.8727,0.50653,9.1043 N,141,3.0365,0.53541,9.1043

* N, 142,4.2059,0.

74162,9.1043 N,143,5.4164,0.95506,9.1043 N,144,7.9696,0.69725,9.1043 N,145,0.0000,0.00000,11.771 N,147,2.5208,0.00000,11.771 N,148,2.5830,0.00000,11.771 N,149,2.9170,0.00000,11.771 N,150,3.083310.00000,11.771 N,151,4.2708,0.00000,11.771 N,152,5.5000,0.00000,11.771 N,154,2.4825,0.43773,11.771 N,155,2.5438,0.44853,11.771 N,156,2.8727,0.50653,11.771 N,157,3.0365,0.53541,11.771 N,158,4.2059,0.74162,11.771 N,159,5.4164,0.95506,11.771 N,161,0.0000,0.00000,14.438 N,163,2.5208,0.00000,14.438 N,164,2.5830,0.00000,14.438 N,'165,2.9170,0.00000, 14.438 N,166,3.0833,0.00000,14.438 N,167,4.2708,0.00000,14.438 N,168,5.5000,0.00000,14.438 N,170,2.4825,0.43773,14.438 EA-SC-93-083-22 ATTACHMENT C Page cs 

* N,171,2.5438,0.44853,14.438 N,172,2.8727,0.50653,14.438 N,173,3.0365,0.53541,14.438 N,174,4.2059,0.74162,14.438 N,175,5.4164,0.95506,14.438 N,177,0.0000,0.00000,16.143 N,178,1.2500,0.00000,16.143 N,179,2.5208,0.00000,16.143 N,180,2.5830,0.00000,16.143 N,181,2.9170,0.00000,16.143 N,182,3.0833,0.00000,16.143 N,183,4.2708,0.00000,16.143 N,184,5.5000,0.00000,16.143 N,185,1.2310,0.21706,16.143

 

N,186,2.4825,0.43773,16.143 N,187,2.5438,0.44853,16.143

 

N,188,2.8727,0.50653,16.143 N,189,3.0365,0.53541,16.143 N,190,4.2059,0.74162,16.143 N,

16.143 N,193,0.0000,0.00000,17.186 N,194,1.2500,0.00000,17.186 N,195,2.5208,0.00000,17.186 N,196,2.5830,0.00000,17.186 N,197,2.9170,0.00000,17.186 N,198,3.0833,0.00000,17.186 N,199,4.2708,0.00000,17.186 N,200,5.5000,0.00000,17.186 N,201,1.2310,0.21706,17.186

 

N,202,2.4825,0.43773,17.186

 

N,203,2.5438,0.44853,17.186 N,204,2.8727,0.50653,17.186 N,205,3.0365,0.53541,17.186 N,206,4.2059,0.74162,17.186 N,207,5.4164,0.95506,17.186 N,209,0.0000;0.00000,17.724 N,210,1.2500,0.00000,17.724 N,211,2.5208,0.00000,17.724 N,212,2.5830,0.00000,17.724 N,214,3.0833,0.00000,17.724 N,215,4.2708,0.00000,17.724 N,216,5.5000,0.00000,17.724 N,217,1.2310,0.21706,17.724 N,218,2.4825,0.43773,17.724 N,219,2.5438,0.44853,17.724.

 

 

 

 

 

EC,45,3,2.000,T048 EC' 52 ,3 I 2.000*, (0.5*T064+0.

5*T080) EC,59,3,2.000,(0.5*T096+0.5*T112)

EC,73,3,2.000,T144 EC,80,3,2.000,T144 EC,19,5,2.000,AAAA EC,26,5,2.000,AAAA EC,33,5,2.000,AAAA EC,40,5,2.000,(0.S*T016+0.S*T032)  

 

EC,47,5,2.000,T048 EC,54,S,2.000,(0.5*T064+0.S*T080)

EC,75,5,2.000,T144 EC,82,5,2.000,T144 EA-SC-93-083-22 ATTACHMENT C Page C11 

 

 

NT,241,TEMP,AAAA C*** ELEMENT TEMPERATURE MODULE C*** INPUT HEAT GENERATION LOADS BTU/hr*ft*ft*ft QE,37,C336.2*0.97*GGGG/24.00)

QE,92,SOCO QE,93,SOCO QE,94,SOCO QE,95,SOCO QE,96,SOCO QE, 153,SOSI QE,154,SOSI QE,155,SOSI QE,156,SOSl QE, 157,SOSI QE,158,SOSI QE,159,SOSl QE,160,SOSI QE,161,SOSI . QE, 162,SOSI QE, 163,SOSI QE, 164,SOSI QE,165,SOSI QE, 171,SOTO QE, 172,SOTO QE,173,SOTO ETLIST,ALL MPLIST ,ALL RLIST,ALL NLIST,ALL ELIST,ALL ECLIST ,ALL NTLIST ,ALL QELIST,ALL LWRITE TIME,0.0 ITER,-20,20,20 LWRITE TIME,0.0 ITER,-40,20,20 LWRITE AFWRITE FINISH EA-SC-93-083-22 ATTACHMENT C Page C12 

* * * /INPUT ,27 FINISH EA-SC-93-083-22 ATTACHMENT C Page C13 

* * * /PREP7 /TITLE VCC-MSB-3 AMB= a.a F 3.885 KW AFTER so YEARS IN STORAGE /SHOW,BNCHVCC2,GEO,, /SHRINK,.3 KAN,-1 1 GGGG=3.885

* Total Heat Generation of MSB assembly K'J/MSB AAAA=0.00

* Ant>ient Air Tell1)erature F SOTO=O.O

* Solar Load on Top BTU/hr/ft**2 , SOSI=O.O

* Assuned Value: Must match TOCA: Outlet Air F DRHl=13.69167

* Air at Bott of MSB TAVE=( CAAAA+TOAS)/2) . C*** ******************************************************

* Total heat generation BTU/Hr ..-CPAl=0.239

C*** Calculated Air outlet TOCA 111Jst be equal to assl.Jlled value TOAS C*** ********************************************************************

* MUST BE EQUAL TO 11 TOAS 11 Air outlet F QQ16=CGGGG*3412.0*0.69*16.0/144.0)

* Heat Gen El. 0 -16 In BTU/hr Q032=CGGGG*3412.0*1.08*16.0/144.0)  

*Heat Gen El. 16 -32 In BTU/Hr Q048=CGGGG*3412.0*1.20*16.0/144.0)  

*Heat Gen El. 32 -48 In BTU/Hr QQ64=CGGGG*3412.0*1.19*16.0/144.0)

* Heat Gen El. 48 -64 In BTU/Hr QQ80=CGGGG*3412.0*1.17*16.0/144.0)  

*Heat Gen El. 64 -80 In BTU/Hr QQ96=CGGGG*3412.0*1.12*16.0/144.0)  

*Heat Gen El. 80 -96 In BTU/Hr Q112=CGGGG*3412.0*1.05*16.0/144.0)

* Heat Gen El. 112 -128 In BTU/Hr Q144=CGGGG*3412.0*0.60*16.0/144.0)  

*Heat Gen El. 128 -144 In BTU/Hr T016=CTOOO+Q016/C3600.0*CPAI*MFLO))

* Air at 16 In. T032=CT016+Q032/C3600.0*CPAl*MFLO))  

*Air at 32 In. T048=CT032+Q048/(3600.0*CPAI*MFLO))

* Air at 48 In. T064=CT048+QQ64/C3600.0*CPAl*MFLO))

* Air at 64 In. T080=(T064+Q080/(3600.0*CPAl*MFLO))

* Air at 80 In. T096=CT080+Q096/(3600.0*CPAI*MFLO))

* Air at 96 In.

* T112=CT096+Q112/C3600.0*CPAl*MFLO))  

*Air at 112 In. T128=CT112+Q128/(3600.0*CPAI*MFLO))  

*Air at 128 In. T144=CT128+Q144/(3600.0*CPAI*MFL0))

* Air at 144 In. C*** ELEMENT TYPE MODULE . C*** DEFINES THE ELEMENT TYPES ET,1,70

* STIF 31 RADIATION LINK ELEMENTS C*** OPTIONS.MODULE C*** DEFINES.ANALYSIS OPTIONS KYPOST,0 TOFFST,460  

*Used for Rad. T Abs= T F + 460 F C*** END OF OPTIONS MODULE C*** MATERIAL MODULE C*** DEFINES MATERIAL PROPERTIES BTU/hr-ft-F C*** Conduction Elements Kxx=Kyy MP,ICXX, 1,26.2 ** MP,ICXX,2,0.719

* MPTEMP,1,-50,0,32,100,200,300 MPTEMP,7,500,700 MPDATA,ICXX,3,1,0.0114,0.0130,0.0140,0.0154,0.0174,0.0193 MPDATA,ICXX,3,7,0.0231,0.0268 MP,ICXX,4,2.38

* MP,KXX,9,10.0  

* . 1 EA-SC-93-083-22 ATTACHMENT C Page C14 

* MP,DENS,5,0.0065  

*

* C*** Conduction Elements Spec. Heat BTU/Lb-F MP,C,1,0.11

* EMIS CARDS MP ,EMIS, 1, .8 MP,EMIS,2,.9 MP,EMIS,3,.85 MP,EMIS,6,.85 MP,EMIS,7,.85 MP,EMIS,8,.85 C*** END OF MATERIAL MODULE C*** REAL CONSTANT MODULE R,1 *FOR STIF55 Elements C*** Real Const.For Radiation Area,From Geo.Fact.,Emiss, SBC R,97,0.4400,0.140,0.9,0.17140E-08  

 

R,98,0.4800,0.140,0.9,0.17140E-08 R,99,0.0500,0.140,0.9,0.17140E*08 R,100,0.0250,0.140,0.9,0.17140E-08 R, 101,0.0950,0.140,0.9,0.17140E-08 R,102,0.7188,0.140,0.9,0.17140E-08 R,103,0.9600,0.140,0.9,0.17140E-08 R,104,0.9600,0.140,0.9,0.17140E*08 R,105,1.2793,0.140,0.9,0.17140E-08 R,106,1.2810,0.140,0.9,0.17140E*08 R,107,1.0500,0.140,0.9,0.17140E-08 R,108,0.6590,0.140,0.9,0.17140E*08 R,109,0.3794,0.140,0.9,0.17140E-08 R, 110,0.1290,0.140,0.9,0.17140E-08 R, 111,0.04895,1.0,0.8,0.17140E-08 R,127,0.0165,1.0,0.8,0.17140E-08 R, 128,0.0446,1.0,0.8,0.17140E-08

* R,129,0.3380,1.0,0.8,0.17140E-08 R,130,0.4510,1.0,0.8,0.17140E-08 R,131,0.4510,1.0,0.8,0.17140E-08 R,132,0.6000,1.0,0.8,0.17140E-08 R, 133,0.6020,1.0,0.8,0.17140E-08 R,134,0.4930,1.0,0.8,0.17140E*08 R,135,0.4270,1.0,0.8,0.17140E*08 R,145,0.0606,1.0,0.8,0.17140E-08 R,146,0.2470,1.0,0.8,0.17140E*08 R,149,0.1740,1.0,0.8,0.17140E-08 R,151,0.6650,1.0,0.9,0.17140E-08 R,166,0.1620,1.0,0.8,0.17140E*08 R, 168,0.2400, 1.0,0.9,0.17140E-08 C*** ENO OF REAL CONSTANT MODULE C*** NOOE MODULE C*** DEFINES NODES BY DIRECT INPUT N,1,0.0000,0.00000,0.0000 N,2,1.2500,0.00000,0.0000 N,3,2.5208,0.00000,0.0000 N,4,2.5830,0.00000,0.0000 N,5,2.9170,0.00000,0.0000 N,6,3.0833,0.00000,0.0000 N,7,4.2708,0.00000,0.0000 EA-SC-93-083-22 ATTACHMENT C Page C15 

N,69,2.9170,0.00000,2.1040 N,70,3.0833,0.00000,2.1040 N,71,4.2708,0.00000,2.1040 N,72,5.5000,0.00000,2.1040 N,73,1.2310,0.21706,2.1040 N,74,2.4825,0.43773,2.1040 . N, 75,2.5438,0.44853,2.1040 N,76,2.8727,0.50653,2.1040 N,77,3.0365,0.53541,2.1040 N,78,4.2059,0.74162,2.1040 N,81,0.0000,0.00000,2.4375 N,83,2.5208,0.00000,2.4375 N,84,2.5830,0.00000,2.4375 EA*SC*93*083*22 ATTACHMENT C Page C16 

* L N,85,2.9170,0.00000,2.4375 N,86,3.0833,0.00000,2.4375 N,87,4.2708,0.00000,2.4375 N,88,5.5000,0.00000,2.4375 N,90,2.4825,0.43773,2.4375 N,91,2.5438,0.44853,2.4375 N,92,2.8727,0.50653,2.4375 N,93,3.0365,0.53541,2.4375 N,94,4.2059,0.74162,2.4375 N,95,5.4164,0;95506,2.4375  

N,97,0.0000,0.00000,5.1042 N,99,2.5208,0.00000,5.1042 N,100,2.5830,0.00000,5.1042 N,101,2.9170,0.00000,5.1042 N,102,3.0833,0.00000,5.1042 N,103,4.2708,0.00000,5.1042 N,104,5.5000,0.00000,5.1042 N,106,2.4825,0.43773,5.1042 N,107,2.5438,0.44853,5.1042 N,108,2.8727,0.50653,5.1042 N,109,3.0365,0.53541,5.1042 N,110,4.2059,0.74162,5.1042 N,111,5.4164,0.95506,5.1042 N,113,0.0000,0.00000,6.4376 N,115,2.5208,0.00000,6.4376 N,116,2.5830,0.00000,6.4376 N,117,2.9170,0.00000,6.4376 N,118,3.0833,0.00000,6.4376 N,119,4.2708,0.00000,6.4376 N,120,5.5000,0.00000,6.4376 N,122,2.4825,0.43773,6.4376 N,123,2.5438,0.44853,6.4376 N,124,2.8727,0.50653,6.4376 N,125,3.0365,0.53541,6.4376 N,126,4.2059,0.74162,6.4376 N,127,5.4164,0.95506,6.4376 N,129,0.0000,0.00000,9.1043 N,131,2.5208,0.00000,9.1043 N,132,2.5830,0.00000,9.1043 N,133,2.9170,0.00000,9.1043 N,134,3.0833,0.00000,9.1043 N,135,4.2708,0.00000,9.1043

_N, 136,5.5000,0.00000,9.1043 N,138,2.4825,0.43773,9.1043 N,139,2.5438,0.44853,9.1043 N,140,2.8727,0.50653,9.1043 N,141,3.0365,0.53541,9.1043  

-N, 142,4.2059,0.74162,9.1043 N,143,5.4164,0.95506,9.1043 N,144,7.9696,0.69725,9.1043 N,145,0.0000,0.00000,11.771 N,147,2.5208,0.00000,11.771 N,148,2.5830,0.00000,11.771 N,149,2.9170,0.00000,11.771 N,150,3.0833,0.00000,11.771 N,152,5.5000,0.00000,11.771 N,154,2.4825,0.43773,11.771 N,155,2:5438,0.44853,11.771 N,156,2.8727,0.50653,11.771 N,157,3.0365,0.53541,11.771 N,158,4.2059,0.74162,11.771 N,159,5.4164,0.95506,11.771  

-N, 161,0.0000,0.00000, 14.438 N,163,2.5208,0.00000,14.438 N,164,2.5830,0.00000,14.438 N,165,2.9170,0.00000,14.438 N,166,3.0833,0.00000,14.438 N,167,4.2708,0.00000,14.438 N,168,5.5000,0.00000,14.438 N,170,2.4825,0.43773,14.438 EA-SC-93-083-22

N,183,4.2708,0.00000,16.143 N,184,5.5000,0.00000,16.143 N,185,1.2310,0.21706,16.143 N,186,2.4825,0.43773,16.143 N,187,2.5438,0.44853,16.143 N,188,2.8727,0.50653,16.143 N,189,3.0365,0.53541,16.143  

N,190,4.2059,0.74162,16.143 N,191,5.4164,0.95506,16.143 N,193,0.0000,0.00000,17.186 N,194,1.2500,0.00000,17.186 N,195,2.5208,0.00000,17.186 N,196,2.5830,0.00000,17.186 N,197,2.9170,0.00000,17.186 N,198,3.0833,0.00000,17.186 N,199,4.2708,0.00000,17.186 N,200,5.5000,0.00000,17.186 N,201,1.2310,0.21706,17.186 N,202,2.4825,0.43773,17.186 N,203,2.5438,0.44853,17.186 N,204,2.8727,0.50653,17.186

N,205,3.0365,0.53541,17.186 N,206,4.2059,0.74162,17.186 N,207,5.4164,0.95506,17.186 N,209,0.0000,0.00000,17.724 N,210,1.2500,0.00000,17.724 N,211,2.5208,0.00000,17.724 N,212,2.5830,0.00000,17.724 N,213,2.9170,0.00000,17.724 N,214,3.0833,0.00000,17.724 N,215,4.2708,0.00000,17.724 N,216,5.5000,0.00000,17.724 N,217,1.2310,0.21706,17.724 N,218,2.4825,0.43773,17.724 N,219,2.5438,0.44853,17.724 N,220,2.8727,0.50653,17.724