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| issue date = 02/28/1986 | | issue date = 02/28/1986 | ||
| title = Rev 1 to St Lucie Unit 1:New & Spent Fuel Storage Criticality Safety Evaluation for Natural U Axial Blanket Fuel. | | title = Rev 1 to St Lucie Unit 1:New & Spent Fuel Storage Criticality Safety Evaluation for Natural U Axial Blanket Fuel. | ||
| author name = | | author name = Brown O, Malody C, Patten T | ||
| author affiliation = SIEMENS POWER CORP. (FORMERLY SIEMENS NUCLEAR POWER | | author affiliation = SIEMENS POWER CORP. (FORMERLY SIEMENS NUCLEAR POWER | ||
| addressee name = | | addressee name = | ||
Revision as of 09:00, 19 June 2019
| ML17216A616 | |
| Person / Time | |
|---|---|
| Site: | Saint Lucie  |
| Issue date: | 02/28/1986 |
| From: | Brown O, Malody C, Patten T SIEMENS POWER CORP. (FORMERLY SIEMENS NUCLEAR POWER |
| To: | |
| Shared Package | |
| ML17216A614 | List: |
| References | |
| XN-NF-83-36, XN-NF-83-36-R01, XN-NF-83-36-R1, NUDOCS 8607150141 | |
| Download: ML17216A616 (29) | |
Text
XN-NF-83-36, Rev.1 Issue Date: 2/28/86 ST.LUCIE UNIT 1 NEW AND SPENT FUEL STORAGE CRITICALITY SAFETY EVALUATION FOR NATURAL URANIIN AXIAL BLANKET FUEL Prepared by 0.C.Brown February l986 E ON NUCLEAR COMPANY, INC.8b07150141 8b0708 PDR ADOCK 05000355'" PDR XN-NF-83-36, Rev.1 ST.LUCIE UNIT 1 NEW AND SPENT FUEL STORAGE CRITICALITY SAFETY EVALUATION FOR NATURAL URANIUM AXIAL BLANKET FUEL Prepared by: rown, ngsneer BWR Neutronics ae Approved by: 'oy, a r Corporate Licensing zan f a en, anager Neutronics and Fuel Management jrs 0 I XN-NF-83-36, Rev.1 ST.LUCIE UNIT 1 NEW AND SPENT FUEL STORAGE CRITICALITY SAFETY EVALUATION FOR NATURAL URANIUM AXIAL BLANKET FUEL TABLE OF CONTENTS Section Page 1.0 2.0 3.0 3.1 3.2 3.3 3.4 4.0 4.1 4.2 4.3 4.4 5.0 6.0 7.0
8.0 INTRODUCTION
..............................................
SUMMARY
OF RESULTS........................................
SPENT FUEL STORAGE POOL ANALYSIS..........................
Design-Base Fuel Assembly Description
......................Storage Array Description
.................................
Storage Array Reactivity
..................................
C oncluslons
~~~~~~~~~~~~~~e~~~~~si~o~oo~~~~~~~o~~~~~~~~~~~~NEW FUEL STORAGE ROOM ANALYSIS............................
Design Base Fuel Assembly Description
.....................
Storage Array Description
.................................
Storage Array Reactivity
..................................
C OnC 1 us 1 OllS~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~o~FUEL INSPECTION ELEVATOR, UPENDER, AND TRANSFER TUBE......CALCULATIONAL METHODS.....................................
COMPUTER MODEL REVIEW AND VALIDATION
..............;.......
R EFERENCES.................................................
APPENDIX 1-SECOND-PARTY REVIEW DOCUMENTATION 1 2 3 3 3 3 5 6 6 6 6 7 8 9 10 11 XN-NF-83-36, Rev.1 ST.LUCIE UNIT 1 NEW AND SPENT FUEL STORAGE CRITICALITY SAFETY EVALUATION FOR NATURAL URANIUM AXIAL BLANKET FUEL LIST OF TABLES Table Page St.Lucie Unit 1 Nominal Fuel Assembly Parameters
.........12 Spent Fuel Storage Pool Reactivity Sensitivity Calculation R esults...........'........................;...............
13 New Fuel Storage Room Reactivity Calculation Results......14
)~l XN-NF-83-36, Rev.1 ST.LUCIE UNIT 1 NEW AND SPENT FUEL STORAGE CRITICALITY SAFETY EVALUATION FOR NATURAL URANIUM AXIAL BLANKET FUEL
1.0 INTRODUCTION
This report summarizes the results of three criticality safety analyses performed for the handling and storage of new and spent fuel at the St.Lucie Unit 1 Nuclear Generating Station.Specifically, the analyses addressed the following areas: 1)Spent Fuel Pool (Section 3.0)2)New Fuel Storage Racks (Section 4.0)3)Fuel Inspection Elevation, Upender, and Fuel Transfer Tube (Section 5.0)An Exxon Nuclear Company (ENC)fuel assembly design which includes natural uranium axial blankets on the assembly ends and a central fuel region enriched to a maximum of 4.0 wtX U-235 was assumed for the analyses.Detailed descriptions of the handling and storage areas is provided in the criticality safety evaluation report sumnarized in Reference 1.\
XN-NF-83-36, Rev.1 2.0
SUMMARY
OF RESULTS Calculations performed for the handling and storage of 4.0 wtX U-235 enriched fuel assemblies external to the St.Lucie Unit 1 reactor core indicate that the applicable criticality safety criteria are met.Worst case reactivities calculated for each area are as follows: Area Calculated keff (95K CL)Limiting keff (9N CL)Criteria Reference Spent Fuel Pool New Fuel Storage Room Fuel Elevator, Upender, Transfer Tube 0.918 0.925 0.924 0.95 0.98 0.95 3t XN-NF-83-36, Rev.I 3.0 SPENT FUEL STORAGE POOL ANALYSIS The high capacity (HI-CAPŽ)spent fuel storage racks were designed to accomnodate 728 fuel assemblies and are generally defined in Attachment A of Reference I.3.1 Desi n Base Fuel Assembly Descri tion The St.Lucie Unit 1 spent fuel storage racks are currently designed and licensed to accept fuel assemblies enriched to 3.7 wtX U-235.Table I summarizes fuel assembly parameters for this fuel design, as well as parame-ters for the Exxon Nuclear fuel design.Also listed in Table I are fuel assembly k calculation results obtained using the CCELL(4)computer code.(CCELL is a pin cell calculation code used to cell-average resonance corrected cross section data for input into other codes, i.e., KENO, etc.)These results indicate a+0.015 bk change in fuel assembly reactivity between the two fuel types.3.2 Stora e Array Descri tion (S ent Fuel Pool Analysis)The spent fuel storage array design and dimensions are described in detail in Reference 1.The array consists of square stainless steel cans having an inside dimension of 8.4835 inches.The cans have a nominal wall thickness of 0.25 inches and-are fixed in a square-pitched array on nominal 12.53-inch centers.3.3 Storage Array Reactivity (k)(Spent Fuel Pool Analysis)For the nominal storage array geometry defined in Section 3.2, keff was calculated for the Exxon Nuclear fuel enriched to 4.0 wtX, U-235 using the KENO IV(5)Monte Carlo computer code.(Cross section data from the XSDRN 123-energy group library were prepared for input into KENO IV using the l l XN-NF-83-36, Rev.I, NITAWL(6)and XSDRNPM(6) codes.A detailed description of the calculation method is given in Section 6.0.)For a pool water temperature of 68oF, a keff of 0.874+0.005 was calculated assuming an effectively infinite array.From results summarized in Reference I, a 8<of+0.034 has been established between the nominal and worst case (minimum offset)storage array conditions.
Applying this hk to the KENO-calculated nominal keff value results in a worst case k ff of 0.918(*)at the 955 confidence level.For postulated accidents such as the dropping of a fuel assembly on top of the racks or having an assembly by accident achieve any other abnormal location in the pool, credit may be taken for realistic initial pool condi-tions(2).These conditions include taking credit for soluble boron (>1720 ppm)present in the pool water.At about 1700 ppm, boron storage array reactivity (keff)is reduced aPProximately 20%hk.Hence, Postulated accidents defined above are of little concern from a criticality safety standpoint.
To better understand the reactivity sensitivity of the storage arrangement to stainless steel can wall thickness and fuel cell center-to-center spacing, several calculations were performed using the one-dimensional transport code XSDRNPM.A cyl indricized-equivalent nominal storage cell was modeled with a reflective cell boundary to appr oximate an infinite array.Results of these calculations are summarized in Table II.For a stainless steel can wal 1 thickness decrease of 0.05 inches, storage array reactivity increases about+0.005 hk.For a storage cell center-to-center spacing decrease from 12.4375 inches to 12.0000 inches, results indicate a reactivity increase of about+0.020&.*kef f(MC)=0.874+(2)(0.005)
+0.034=0.918 (95K confidence level).
XN-NF-83-36, Rev.1 3.4 Conclusions (S ent Fuel Pool Anal sis)The results of this analysis demonstrate that Exxon Nuclear design fuel defined in Table I and enriched to 4.0 wtX U-235 can be stored in the St.Lucie Vnit 1 storage pool and continue to meet NRC criticality safety criteria, i.e., the neutron multiplication factor in the pool shall be (0.95 under worst credible conditions.
The adequacy of the calculational methods used in this analysis is discussed in Section 7.0.
XN-NF-83-36, Rev.1 4.0 NEW FUEL STORAGE ROOM ANALYSIS The new fuel storage array was analyzed in 1979(1)for CE fuel assemblies enriched to 3.70 wtX U-235.Results of this analysis indicated the maximum storage array reactivity (keff)to be about G.92 for all degrees of uniformly interspersed moderation.
4.1 Desi n Base Fuel Assembly Description The Exxon Nuclear fuel assembly defined in Section 3.1 and Table I was used in reactivity calculations for the new fuel storage array.4.2 Stora e Array Descri tion (New Fuel Stora e Room)The St.Lucie Unit 1 new fuel storage room consists of a 10x10 fuel assembly array arrangement with the two middle rows{running north and south)removed.The room has concrete walls around the entire array and cells are spaced on 21-inch centers.The fuel is normally stored in the dry condition.
Additional details concerning the arrangement can be found in Attachment B of Reference 1.4.3 Storage Array Reactivity (k)(New Fuel Stora e)Since the new fuel is stored dry, reactivity calculations were performed for varying degrees of moderation in the event the array became moderated.
For the case of full flooding, the array would remain subcritical due to neutron isolation between fuel assemblies.
For the case of uniform moderation interspersed within and between fuel assemblies in the storage array, i.e., aqueous foam, etc., 123 energy group KENO-IV calculations were performed for water densities in the array ranging from 15%water (by volume)to 2.5X.Results of these calculations are summarized in Table III and indicate the maximum keff of the array to be 0.925 at the 95K confidence level.
7 XN-NF-83-36, Rev.1 4.4 Conclusions (New Fuel Stora e)The results summarized in Section 4.3 and Table III'emonstrate that the maximum keff or the St.Lucie Unit 1 new fuel storage room will not exceed the limiting criterion of 0.98 for all degrees of uniform moderation in the array.Specifically, the maximum reactivity occurs for a moderator void fraction between 0.90 and 0.95 and is estimated to be about 0.925 at the 95K confidence level.
XN-NF-83-36, Rev.1 5.0 FUEL INSPECTION ELEVATOR, UPENDER AND TRANSFER TUBE For the fuel inspection elevator, upender and transfer tube, keff calcula-tions were performed for three worst case situations in the previous evalua-tion, see Attachment C of Reference 1.The case which produced the highest reactivity involved the fuel inspection elevator.For this case, it was assumed that one fuel assembly was in the elevator and one additional assembly was located four (4)inches edge-to-edge from the elevator assembly.Assuming this condition, a KENO calculation was performed for the Exxon Nuclear fuel assembly defined in Table I.This case was run with 18 energy group cross section data prepared using CCELL and gave a resulting keff of 0.914+0.005 or 0.924 at the 95K, confidence level.Hence, it is concluded that'the fuel inspection elevator, upender and transfer tube will all meet the keff<0 g5 criterion for the 4.0 wtX U-235 enriched fue'l.
0 I I' e 9 XN-NF-83-36, Rev.I 6.0 CALCULATIONAL METHODS The KENO-IV Monte Carlo code(5)was used to calculate the reactivities of the storage arrays and fuel elevator.Multigroup cross section data from the XSDRN 123 group library were generated for input into KENO-IV using the NITAWL(6)and XSDRNPM(6) codes.Specifically, the NITAWL code was utilized to obtain cross section data adjusted to account for resonance self-shielding by the Nordheim Integral Method.The XSDRNPM code, a discrete ordinates one-dimensional transport theory code, was then used to prepare spatially cell-weighted cross section data representative of the fuel assembly for input into KENO-IV.Cross section data for the fuel elevator keff calcula-tion were prepared using the CCELL code.CCELL is a combination of the HRG(8)and THERMOS(9) codes, and produces multigroup cross section data treated in a similar fashion to the NITAWL/XSDRNPM methodology.
10 XN-NF-83-36, Rev.1 7.0 COMPUTER MODEL REVIEW AND VALIDATION The calculated worst case keff (0.918)for the spent fuel storage array is about A less than the comparable value for 3.7 wtX fuel (0.947)reported in Reference 1.This is apparently due to a high degree of conservatism in the Reference 1 calculational model.The computer code models used for the calculations in this report have been benchmarked against experimental data and adequately reproduce the critical values.(On the average, the critical value is reproduced to within one standard deviation.)
Detailed results of these benchmark calculations are given in Reference 7.In addition, the results and conclusions of this criticality safety evaluation have been second-party reviewed by an individual knowledgeable in the area of critical-ity safety.The findings of this review are given in Appendix I.
g'I XN-NF-83-36, Rev.1
8.0 REFERENCES
2.Letter (with attachments) from R.E.Uhrig (FPL)to V;Stello (USNRC),"St.Lucie Unit 1 Docket No.50-335 Proposed Amendment to Facilities Operating License DPR-67," dated October 4, 1979.Letter to all Power Reactor Operators from B.K.Grimes (NRC),"OT Position for Review and Acceptance of Spent Fuel Storage and Handling Applications," dated April 14, 1978.3.American Nuclear Society Standard, ANS-N18.2.
4.W.W.Porath,"CCELL Users Guide," BNW/JN-86, Pacific Northwest Labora-tories, February 1972.5.L.M.Petrie and N.F.Cross,"KENO IV: An Improved Monte Carlo Criticality Program," ORNL-4938, Oak Ridge National Laboratory, November 1975.6.N.M.Green, et.al.,"AMPX-A Modular Code System for Generating Coupled Multigr'oup Neutron-Ganma Libraries from ENDF/B," ORNL-TM-3706, Oak Ridge National Laboratory, March 1976.7.C.0.Brown,"Criticality Safety Benchmark Calculations for Low-Enriched Uranium Metal and Uranium Oxide Rod-Water Lattices," XN-NF-499, Exxon Nuclear Company, Inc., April 1979.8.J.L.Carter, Jr.,"HRG-3: A Code-for-Calculating the Slowing-Down Spectrum in the P1 or B1 Approximation," BNWL-1432, Battelle-Pacific Northwest Laboratories, June 1970.9.D.R.Skeen and L.J.Page,"THERMOS/BATTELLE:
The Battelle Version of the THERMOS Code," BNWL-516, Battelle-Pacific Northwest Laboratories, September 1967.
12 XN-NF-83-36, Rev.1.Table I St.Lucie Unit 1 Nominal Fuel Assembly Parameters Type: Lattice Pitch: Clad O.D.: Clad Material: Active Fuel Rods: No.of Control Rod Guide Tubes: Guide Tube Material: Guide Tube O.D.: Guide Tube Tk: Eff.Array Dimension:
Active Fuel Length: CE 14xl4 0.580 inch 0.440 inch Zr-4 176 5 Zr-4 1.115 inch 0.040 inch 8.12 inch x 8.12 inch 136.7 inch CE 14x14'\WWWWWW ENC 14xl4 Enrichment, wtX Pel]et OD, inch Stacked Fuel Density, g/cc Clad Tk, inch Moderator-to-Fuel Volume Ratio(>)Axial U-235 Loading, g/cm k (CCELL)3.7 0.3765 10.054 0.028 1.934'41.45 1.447 4.0 (assumed)0.3700 10.199 0.031 2.034 43.91(2)1.462 This ratio takes into account the zirconium tubing and water associated with the instrument and control rod locations within the fuel assembly.This value corresponds to an axial U-235 loading at 4.0 wtX and does not include the axial blankets of natural uranium.
13 XN-NF-83-36, Rev.1 Table II St.Lucie Unit 1 Spent Fuel Storage Pool Reactivity Sensitivity Calculation Results (NITAML/XSDRNPH)
Case Oescription Nominal Storage Array 6k~Comments 1 (base)Enrichment
-4.0 wtX Temperature
-6BoF Mall Thickness-0.25" C-C Spacing-12.4375" Nominal Arrangement 2a 2b Mall Thickness-0.20" Mall Thickness-0.10"+0.0052+0.0249 3a 3b C-C Spacing-12.0000" C-C Spacing-11.5625"+0.0199+0.0462 Min.Offset Condition
~*s 1 r I s e~14 XN-NF-83-36, Rev.1/Table III St.Lucie Unit 1 New Fuel Storage Room Reactivity Calculation Results Fuel Assembly: Number of Assemblies in Room: Array Geometry: Calculation Model: ENC 14x14 (4.0 wtX U-235)80 Per Ebasco Services Dwg No.8770-6-832, Rev.3 KENO IV with 123 group cross sections prepared using NITAWL/XSDRNPH Case Vol%Hater in Array keff+~Comnents 2.5 5.0 10.0 15.0 0.825+0.006 0.905+0.005(1)0.898+0.006 0.811+0.006 Max.Calculated keff Peak keff estimated to be about 0.925 (at the 95K confidence level)and to occur between 2.5 and 5.0 vol%water in the storage array.
}~~XN-NF-83-36, Rev.I APPENDIX I SECOND-PARTY REVIEM DOCUMENTATION
'i~~~HJ$84 UGLEULR coMPANY,Oc.
internal Correspondence XN-NF-83-36 Rev.1 Distribution Date: To: From:
Subject:
May 3, 1983 C.O.Brown J.E.Pieper CRITICALITY SAFETY ANALYSIS POR ST.LUCIE UNIT 1 NEW AND SPENT FUEL STORAGE, XN>>NF-83-36 Ref: A.S.Jameson (Canbustion Engineering) to R.W.Winnard (Florida Power t Light), September 18, 1979,"Bases for Updating the St.Lucie-1 Technical Specification 5.3.1".I have completed a reviev of the calculations and the analysis approach used in the study of the St.Lucie Unit 1 new, spent fuel storage and fuel inspection elevator, upender and transfer tube.I believe that in conjunction vith the referenced letter, your analysis adequately deaan-strates the criticality safety of Exxon Nuclear 4.0 vt.%U fuel design when used in this equipment.
The cross-section library used for the analyses vere traced through the HITAWL, XSDRNPM, NITAWL code stream.The KENO and CCELL runs vere also revieved.The folloving s~cific runs vere revieved: CCELL NITAWL XSDRNPM NZTAWL ZEND ZV XSDRNPM XSDRNPM XSDRNPM'SDRNPM XSDRNPM XSDRNPM NZTAWL CCELL XENO-2 CCELL CCELL CCELL CCELL NZTAWL NITAWL Job Name XCEL 940 NZTAWGE XSDRNMP NZT?lW81, KSTLUGQ XSDRNRU XSDRHRX XSDRNRO XSDRNRZ XSDRN7U XSDRNDR NIT?LNH3 XCE19LG KEN?2OZ XCEL9LF XCEL9FU XCEL9LC XCE19LD NZTAWST NZTAWSV Date of Run 25/03/83 28/03/83 28/03/83 28/03/83 28/03/83 05/04/83 05/04/83 05/04/83 05/04/83 04/04/83 31/03/83 31/03/83 14/04/83 19/04/83 08/21/83 05/04/83 05/04/83 05/04/83 08/04/83 07/04/83 Time of Run 12 55.19 13 34 40 13.57.27 15.26.40 19.20.06 20.42.17 20 24.10 20.46.15 20.46.27 19 29.26 13.20.36 12.57.20 16.04.53 19.54.07 12.58.58 11.56.45 12 26.17 12.26.18 13.24.21 17.25.33
~tg I c~C.O.arche XN-NF-83-36 Rev.1 May 3, 1983 NIThWL NITAHL XSDRNPM XSDRNPM XSDRNPM XSDRNPM KENO-IV KENO-IV XENO-IV KENO-IV Job Name NIThWUO NITKWSU XSDRNV1 XSDRN9R XSDRNXB XSDRN95 XSTLU2D XSTLUG3 XSTLUSP KSTLUHL Date of Run 06/04/83.07/04/83 08/04/83 07/04/83 06/04/83 07/04/83 08/04/83 07/04/83 07/04/83 07/04/83 Time of Run 15.46.14 17.25.32 15.46.14 17.44.21 15.58.31 17.44-35 17.59.02 22.15.34 20.11.34 22.15.36 The following items~e included in the review of the codes: XENO: CCELL Options Corz'ect Mixtures Geometry Adequate Histories Cross Sections (Data or Lihrary tape).eff Geometry Atom Densities Verif ied Resonance Treatment Options X NITASL: Input Tape Output Tape ZD Runners Resonance Parameters A>here used)XSDRNPM: Input Tape Output Tape Gecxnetzy Options KQctures Convergence clc XN-NF-83-36, Rev.1 Issue Date: 2/28/86 ST.LUCIE UNIT 1 NEM AND SPENT FUEL STORAGE CRITICALITY SAFETY EVALUATION FOR NATURAL URANIIN AXIAL BLANKET FUEL 1.DISTRIBUTION 0.C.Brown'L.D.Gerrald T.J.Helbling (5)J.S.Holm T.M.Patten G.N.Mard Document Control (2)
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