* , MOL.19971208.0655
WBS: 1.2.2QA: L
Civilian Radioactive Waste Management SystemManagement & Operating Contractor
Summary Report of Commercial Reactor Criticality Datafor McGuire Unit 1
Revision 00
Document Identifier No.: BOOOOOOOO-01717-5705-00063 REV 00
August 15, 1997
Prepared for.
U.S. Department of EnergyYucca Mountain Site Characterization Project Office
P.O. Box 30307Las Vegas, NV 89036-0307
Prepared by:
Civilian Radioactive Waste Management SystemManagement & Operating Contractor
1180 Town Center DriveLas Vegas, Nevada 89134
Under Contract NumberDE-ACOI-91RWO0134
Oe
Civilian Radioactive Waste Management SystemManagement & Operating Contractor
Summary Report of Commercial Reactor Criticality Datafor McGuire Unit 1
Document Identifier No.: BOOOOOOOO-01717-5705-00063 Revision 00
August 15, 1997
Prepared by:
Checked by:
C. W. Mays, AuthorWaste Package Criticality Analysis Methodology
K D. Wriht, CheckerWaste Package Criticality Analysis Methodology
Date: z/g5
Date: _____/___1__
Checked by:_ 0 3 4-L. B. Wimmer, Checker (Reference 5 Input)Waste Package Criticality Analysis Methodology
Approved b 7 )D. A. Thomas, ManagerWaste Package Criticality Analysis Methodology
Date: a _8/_ 4_/9
Date: e,6W VAT Z.
Approved by: P A, GH.A.B ton, Department Manager
I Waste Package Development
Date: _ _I__ s _/,_
BOOO0OOO-01717-5705-00063 REV 00 If August IS, 1997
w-
IESTORY OF CHANGE PAGE
Initia Issuance, REV 00 .............. August 15,1997
BOOOOOOOO-01717-5705-00063 REV 00 Hi August IS, 1997
Acknowledgments
The author would like to express his thanks to Duke Power Company for their assistance withgathering and verification of the information used to model the critical statepoint conditions forthe McGuire Unit I reactor. The author would also like to thank Duke Power Company forgranting permission to publish this information.
BOOOOOOOO-01717-5705-00063 REV 00 IV August IS, 1997
TABLE OF CONTENTS
Section Page
1.0 INTRODUCTION ........................................................... I1.1 Background . ............................................ 11.2 Objective ....................................................... 11.3 Scope ............................................ 11.4 Quality Assurance ............................................. I
2.0 REACTOR DESIGN INFORMATION ......................................... 3
3.0 FUEL CYCLE DESIGN INFORMATION . ..................................... 93.1 Fuel Batch Data . ............................................ 93.2 Fuel Assembly Data ............................................ 21
4.0 CORE OPERATIONS AND STATEPOINT INFORMATION . . 244.1 Core Follow Data ................................................. 244.2 Statepoint Critical Condition Measurements ............ ................. 24
5.0 REFERENCES ................... .................... 26
BOOOOOOO-01717-S705-00063 REV 00 v Augut S, 1997
LIST OF FIGURES
Page
Figure 2-1.Figure 2-2.Figure 2-3.Figure 2-4.
Figure 2-5.
Figure 2-6.
Figure 2-7.
Figure 2-8.
Figure 2-9.
Figure 2-10.
Figure 3-1.Figure 3-2.
Horizontal View of Vessel Internals Along Core Midplane ..... ............ 4Radial View of Fuel Assembly Layout Along the Core Flat ................. 5Radial View of a Single 17 x 17 Fuel Assembly .......................... 7Axial Dimensions by Region for Westinghouse 17 x 17 Standard Fuel Assembly
................................................................ 8Axial Dimensions for Guide Tubes for Westinghouse 17x17 Standard FuelAssembly ..................................................... 10Axial Dimensions for Instrument Tube for Westinghouse 17x17 Standard FuelAssembly ....................................................... 11Axial Dimensions for Fuel Rod Assembly for Westinghouse 17x17 Standard FuelAssembly ..................................................... 12Axial Dimensions for RCCAs (Rods 0% Withdrawn) for Westinghouse 17x17Standard Fuel Assembly .................. ......................... 14Axial Dimensions for Pyrex BPRAs for Westinghouse 17x17 Standard FuelAssembly ..................................................... 16Axial Dimensions for Thimble Plug for Westinghouse 17x17 Standard FuelAssembly ..................................................... 17Cycle I Core Loading . ............................................ 22Burnable Poison Rod Locations ...................................... 23
B00000000-01717-S705-00063 REV 00 vi August 15, 1997
LIST OF TABLES
Page
Table 2-1. Dimensions from Core Center to Outside Surface of Pressure Vessel ..... ....... 3Table 2-2. McGuire I Cycle I Fuel Assembly/Core Data .............................. 6Table 2-3. Volume Fractions for Non-Fuel Regions for Non-Control Assemblies ..... ...... 9Table 2-4. Fuel Rod Assembly Volume Fractions for Regions 3 and 5 .................... 9Table 2-5. Volume Fractions for Assemblies with RCCAs (0% Withdrawn) - Regions I - 3
..................................................................... . ................................13Table 2-6. Volume Fractions for Assemblies with BPRAs - Regions 2 - 3 ................ 15Table 3-1. Fuel AssemblylPinlCycle Description for Cycle I ........................... 20Table 3-2. Cycle Length and Time During Cycle Statepoint Data Measured for Cycles 1-7 ... 21Table 4-1. Statepoint Data for McGuire Unit I - Measured Critical Conditions ..... ....... 25Table 4-2. Statepoint Data for McGuire Unit 1 - Shutdown and Startup Dates ..... ........ 25
BOODOOOO-01717.5705-00063 REV 00 TH August 15, 1997
1.0 INTRODUCTION
The "Summary Report of Commercial Reactor Criticality Data for McGuire Unit 1 " contains thedetailed information necessary to perform commercial reactor criticality (CRC) analyses for the'McGuire Unit I reactor.
1.1 Background
The United States Department of Energy (DOE) Office of Civilian Radioactive WasteManagement (OCRWM) is developing a methodology for criticality analysis to support disposalof commercial spent nuclear fuel in a geologic repository. A topical report on the disposalcriticality analysis methodology is scheduled to be submitted to the United States NuclearRegulatory Commission (NRC) for formal review in September 1998. This technical reportprovides data that will be used in analyses that will support the development of parts of thedisposal criticality analysis methodology.
1.2 Objective
The objective of this report is to present the data required for performing analytical CRCevaluations for the McGuire Unit 1 reactor. Results from the CRC evaluations will support thedevelopment and validation of the neutronics models used for criticality analyses involvingcommercial spent nuclear fuel. These models and their validation will be discussed in theDisposal Criticality Analysis Methodology Topical Report.
1.3 Scope
The scope of this Summary Report is the data required to perform the first of 6 statepointcalculations from cycles 1, 6 and 7 of McGuire Unit 1 (revision will include the data for theremaining 5 statepoints). The only interface for the development of the information in thisdocument is with Framnatome Cogema Fuels (FCF). FCF is one of the teammates of the CivilianRadioactive Waste Management System Management and Operating Contractor (M&O). FCFindependently requested and received permission from Duke Power Company, theownerloperator of McGuire Unit 1, to publish the information related to statepoint measurementsthat is recorded in this document. All the information contained in this report is documented inan FCF calculational file (Reference 5). The data provided in reference S was obtained fromvarious other reports, calculations, and drawings developed under an NRC accepted qualityassurance program (Reference 1) and the data has supported prior licensing submittals. The datatherefore will be considered acceptable for quality affecting activities and for use in analysesaffecting procurement, construction, or fabrication.
1A Quality Assurance
The Quality Assurance program applies to the development of this report. The data provided inthis report will indirectly be used to develop the methodology for evaluating the Mined GeologicDisposal System (MGDS) waste package and engineered barrier segment; the waste package andengineered barrier segment have been identified as MGDS Q-List items important to safety and
BOO0 O-01717-570500063 REV 00 I August 15, 1997
waste isolation (Reference 2). The waste package is on the Q-List by direct inclusion by theDOE; a QAP-2-3 evaluation has yet to be conducted. There are no determination of importanceevaluations developed in accordance with Nevada Line Procedure, NLP-2-0, since the reportdoes not involve any field activity.
The Waste Package Development Department responsible manager has evaluated the technicaldocument development activity in accordance with QAP-2-0 Conduct of Activities. The"Develop Technical Documents" (Reference 3) evaluation has determined the preparation andreview of this technical document is subject to Quality Assurance Requirements and Description(Reference 4) controls. No scientific and engineering software or computational software wasused in the development of this report.
BCOOGOOOOO-01717-570S-00063 REV 00 2Ags 5192 .August 15, 1997
2.0 REACTOR DESIGN INFORMATION
This section provides general material and geometry data for modeling the McGuire Unit 1reactor. Figures 2-1 through 2-10 provide pictorial representations of various components thatmust be modeled. A horizontal view of the vessel internals is presented in Figure 2-1. Thisincludes the 193 fuel assemblies (FA) in the reactor core region. All dimensions in this figureare measured from the center of the reactor core. A radial view of the fuel assembly layout(along the core flat) and extending through the core liner is provided in Figure 2-2. The coreliner, core barrel, neutron pad, and vessel weld liner are represented as stainless steel (SS304).The pressure vessel is carbon steel (CS508). Table 2-1 provides dimensions from the center ofthe core (along the core flat) to the outside surface of the pressure vessel.
Table 2-1. Dimensions from Core Center to Outside Surface of Pressure Vessel
DesrilntinCore CenterYz FA-IWaterFA-2WaterFA-3WaterFA4WaterFA-5WaterFA-6WaterFA-7WaterFA-8WaterCore LinerWaterCore BarrelWaterVessel LinerPressure Vessel
Thickness, cm
10.701020.10160
21.402040.10160
21.402040.10160
21.402040.10160
21.402040.10160
21A02040.10160
21.402040.10160
21A02040.21350'2.85000
23.675.72
25.470.56
21.99
Outer Radius, cm00.00000 -10.7010210.8026232.2046632.3062653.7083053.8099075.2119475.3135496.7155896.81718
118.21922118.32082139.72286139.82446161.22650161.44164.29187.96193.68219.15219.71241.70
For Figure 2-1, the axial dimensions of the four symmetric neutron pads can be represented asthe same as the active height of the fuel in the core.
Table 2-2 summarizes fuel assembly and reactor core data used for modeling the McGuire Unit Ireactor for cycle 1. Additional fuel cycle design, core operations, and reactor criticality statepointinformation will be provided in Sections 3 and 4.
BOOOOGOO-01717-5705-00063 REV 00 3 August 5, 1997
Figure 2O. Horizontal View of Vessel Internals Along Core Midplane
BOOOOOOOO-01717.S705-00063 REV 00 4 August 15, 1997
Figure 2-2. Radial View of Fuel Assembly Layout Along the Core Flat
FA-1 FA-2 FA-3 FA-4 FA-5 FA-6 FA-7 FA-B
Along CorenFlat"
______ '-i-I-,
Core Uner
Outside Dimension of FA = 21.40204 cm(Includes Top & Bottom Grids)
Fuel Assembly Pitch = 21.50364 cm
1 164.29 cm
161.44 cm
B00000000-01717-S70540063 REV 00 5 August IS, 1997
Table 2-2. McGuire 1 Cycle 1 Fuel Assembly/Core Data
Fuel Assembly Array Size and TypeNumber of Fuel Pins (NR) / AssemblyNumber of Guide Tubes (NOT) / AssemblyNumber of Instrument Tubes (NaT) / AssemblyNumber of Assemblies in CoreSystem PressureCore Height (H)Pin PitchFuel Pin Cladding OD (outer diameter - ODC)Fuel Cladding MaterialGuide Tube Upper Region
Length in Active Fuel Region (H.)Guide Tube OD (ODGWu)
Guide Tube Lower RegionLength in Active Fuel Region (H2)Guide Tube OD (ODu)
Guide Tube MaterialInstrument Tube OD (ODyr)Instrument Tube MaterialAssembly Pitch (P)Inconel Spacer Grid Height
17x 17Std26424I193
2280 psia/1.572 x 107 Pa365.76 cm1.25984 cm0.94996 cmZircaloy
308.4703 cm1.22428 cm
57.2897 cm1.08966 cmZircaloy1.22428 cmZircaloy21.50364 cm3.35788 cm
Grid Volume for Active Fuel Region in Single Assembly:
Volume of Inconel Grid = Vn = 666.6352 cm'
V^{.G = Volume of Moderator plus Grid in Fuel Assembly (excluding inside guide tubesand instrument tube)
_P2-H -- H [NROD + NOD] - NGT- -[Hi OD-U + H 2 ODGT]442
= 90,263.3285 cm&
Assembly Volume Fraction of Inconel Grid = VOIVM+a = 0.0073854
Figure 2-3 presents a radial view of a single fuel assembly showing the locations of the guidetubes, instrument tube, and fuel pins. Figure 2-4 provides axial dimensions, by region, for theWestinghouse 17 x 17 standard fuel assembly (17 x 17 Std). This assembly contains 6 inconelintermediate spacer grids and two inconel end spacer grids. The upper end spacer grid is abovethe active fuel region, whereas the lower end spacer grid and the 6 intermediate spacer grids areinside the active fuel region.
BOCOOOOOO-01717-5705-00063 REV 00 6 August S, 1997
Figure 2-3. Radial View of a Single 17 x 17 Fuel Assembly
-OK - Assembly Pitch * 21t026408 -
: .-W IN..:IAssembly Outer DImensions a 21A0204 cm
_ _ _ _ CJ _CT CT _ _ -
CT CT
ECTI CT STI CT C
T_ CT CT CT CT)
CT _CT _ _ CT _ _IT _ C _ _
CT CT CT CT C
-- H 1..C-
LI Fuel Pin CallPhi Pitch * 1.2594 cm
Culde Tube
Instrument Tube Note: Assembly outer dimension Is less then 17 timesthe pin pilch. The outermst ens (except earners) arrectangular and nft square like the other cells
BOO800000901717-S705-00063 REV 00 7 August 15, 1997
Figure 24. Axdal Dimensions by Region for Westinghouse 17 x 17 StandardFuel Assembly
- y = 437.B73 cm
RegIon 1: 30.0 cm Upper Reactor Internals
Region 2: 16.606 cffRegio - -4 -
Region 3: 14.656 cff
--- ---
Upper End Fitting
Upper Fuel Plenum andUpper End Spacer Grid
- - y c407.873 cm
--y =392.367 cm
- . y =377.711lcm
y =338.760 cm
y = 286.563 cm
Intermediate Spacer Grid-
Intermediate Spacer Grid
Region 4:Active Fuel365.76 cm
Intermediate Spacer Grid- y = 234.366 cm
- y = 182.169 cmIntermediate Spacer Grid
Intermediate Spacer Grid
Intermediate Spacer Grid
- y=129.972 cm
- - y = 77.776 cm
--. y=15.723 cm
- y * 11.951 cm
-- y=O.Ocm
Lower End Spacer Grid
Region : 11.951 errLower Fuel Plenum
and End Fitting
Region 6: 30.0 cm Lower Reactor Internals
* - y = -30.0 cm
BOOOOOOOO-01717-S705-00063 REV 00 8 August IS, 1997
Figures 2-5 through 2-7 provide axial dimensions for the guide tubes, instrument tube, and fuelpins shown in Figure 2-3. Figures 2-8 through 2-10 provide axial dimensions for rod clustercontrol assemblies (RCCAs) with rods at 0% withdrawn, pyrex burnable poison rod assemblies(BPRAs), and thimble plugs that are attached to BPRAs at empty locations.
Regions 1 and 6, in Figures 2-4 through 2-10, are represented as homogenized regions ofstainless steel and water. Regions 2, 3, and 5 contain various combinations of guide tubes,instrument tube, and fuel rod assemblies (no fuel pellets), as well as other materials (stainlesssteel, inconel, and water). The fraction of guide tubes, instrument tube, and fuel rod assemblieswill be represented explicitly in these regions. (Note: the fuel rod assemblies do not extend toregion 2.) The other materials will be homogenized within the remaining portions of the regions.The water inside the guide tubes and instrument tube will be represented explicitly within therespective tubes. The volume fractions of other materials, by region, for the Westinghouse 17 x17 standard fuel assembly are presented in Table 2-3.
Table 2-3. Volume Fractions for Non-Fuel Regions for Non-Control Assemblies
Voalume Fractions*Region Ss Inc. ater
1 0.1770 0.0 0.82302 0.1243 0.0168 0.85893 0.0031 0.0264 0.97055 0.1625 0.0 0.83756 0.1720 0.0 0.8280
* The volume fractions presented exclude the guide tubes, instrument tube, and fuel rodassembly portions of these regions.Note: Inc = Inconel
SS = Stainless Steel
The fuel rods are contained in regions 3, 4, and 5. Region 4 is modeled explicitly. Regions 3and 5 contain various amounts of stainless steel and zircaloy in the fuel rod assembly whichrepresent plenum springs and end caps. In addition, these regions also contain helium and fissiongases, as well as the zircaloy cladding. The fuel rod assembly volume fractions for materials inthese regions for the Westinghouse 17 x 17 standard fuel assembly are as follows:
Table 2-4. Fuel Rod Assembly Volume Fractions for Regions 3 and S
Fuel Rod Assembly Volume FractionsRgion Zr Cladding Gas
3 0.0764 0.0513 0.2173 0.65505 0.1241 0.1685 0.1898 0.5176
e The zircaloy (Zr) cladding extends from Y = 8.278 cm to Y = 391.615 cm. For all 264 rods,13.904 cm length of fuel cladding is included in region 3 and 3.673 cm length of fuelcladding is included in region 5.
B00000000-01717-5705-00063 REV 00 9 August 15, I59
Figure 2-5. Axial Dimensions for Guide Tubes for Westinghouse 17x17Standard Fuel Assembly
Y - 437.873 cm-
Y 407.873 cm-
Y = 392.367 cm-
Y =.377.711 cm
Y = 11.951 cm-
Y = 0.0 cm -
Y - -30.0 cm -
-I Guide Tube24 per Fuel AssemblyReg 1: Upper Reactor
Internals-I
Reg 2: Upper EndFitting
-4
Reg 3: Upper FuelPlenum & EndSpacer Grid
It
9-Y c 3.381 cm
- Y c 69.241 cm
Reg 4: Active Fuel
-4._
Reg 6: Lower FuelPlenum andEnd Fitting U .. Y 6.O5E cm
Reg 6: Lower ReactorI Internals
BOOOOOD -01717-5705-00063 REV 00 10 August 15, 1997
Figure 2-6. Axial Dimensions for Instrument Tube for Westinghouse 17x17Standard Fuel Assembly
Y = 437.873 cm
Y = 407.873 cm
Y = 392.367 cm'
Y = 377.711 cm-
Instrument TubeI per Fuel AssemblyReg 1: Uppei Reactor
Internals-m
Ad -Y r 397.497 cmReg 2: Upper EndFitting
Reg 3: Upper FuelPlenum & EndSpacer Grid
,_ _
Reg 4: Active Fuel
I
Y = 11.951 cl
Y = 0.0 cm
Y=-30.Ocm
- I'II
IReg 6: Lower Fuel
Plenum andEnd Fitting
-' - Y a5.664 cm
Reg 6: Lower ReactorInternals
BOOOOOOOO-01717-5705-00063 REV 00 or' August 15, 1997
Figure 2-7. Axial Dimensions for Fuel Rod Assembly for Westinghouse 17x17Standard Fuel Assembly
Y = 437.873 cm
Y = 407.873 cm-
Y - 392.367 cm'
Y = 377.711 cm-
Y= 1.951 cm-
Y = 0.0 cm -
Yu= 30.0 cm -
-I. Fuel Rod Assembly- 264 per Fuel AssemblyReg 1: Upper Reactor
Internals-I-
Reg 2: Upper EndFitting
_ -Y = 392.367 cmReg 3: Upper Fuel
Plenum & EndSpacer Grid
_I.
Reg 4: Active Fuel
-4
Reg 6: Lower FuelPlenum andEnd Fitting
- Y7.2136cm
-4Reg 6: Lower Reactor
Internals
BOOOOOOO-01717-570S-00063 REV 002 12 August 15, 1997
Figure 2-8 provides axial dimensions for a fully inserted (0% withdrawn) control rod for aWestinghouse 17x17 standard fuel assembly.
RCCA Materials/Dimensions:
Lower cap - stainless steel (diameter = 0.96774 cm)
Cladding - stainless steel (Clad OD = 0.96774 cm, Clad ID (inner diameter) = 0.87376 cm)
Absorber - Ag-In-Cd (diameter = 0.86614 cm)
Spacer - stainless steel (diameter = 0.8585 cm)
Upper plenum/spring area - Volume Fractions: Clad - Stainless SteelSpring - InconelGas
=0.1848= 0.2784= 0.5368
Upper cap - stainless steel (diameter = 0.96774 cm)
Upper stem - stainless steel (diameter = 0.5563 cm)
RCCA Volume Fractions:
The control rods are represented explicitly in regions 2, 3, and 4. The remainder of materials(excluding fuel rods, instrument tube, and guide tubes) are homogenized in regions 1, 2, and 3.The volume fractions of these materials (including non-RCCA materials) for RCCAs with rods at0 % withdrawn are given in Table 2-5.
Table 2-5. Volume Fractions for Assemblies with RCCAs (0% Wlthdrawn) - Regions 1 - 3
Volume Fractions (Rods 0% WD)Ss Inc WaterRegton
123*
0.19070.14440.0031
0.00350.02180.0264
0.80580.83380.9705
* Region 3 volume fractions are the same as for non-control assemblies.
For fully withdrawn control rods (100% withdrawn) the volume fractions presented in Table 2-3(for non-control assemblies) should be used.
BOOOOOOOO-01717-S705-00063 REV 00 13 August 15, 1997
Figure 2M8. Axial Dimensions for RCCAs (Rods 0%o Withdrawn) forWestinghouse 17x17 Standard Fuel Assembly
Y = 437.873 cm
Y = 407.873 cm
Reg 1: Upper ReactorInternals
1- 1.
Reg 2: Upper EndFitting
Y = 392.36'
Y = 377.71
-
[7 cm~ Reg 3: Upper Fuel
Plenum & EndSpacer Grid
1 cm-
Reg 4: Active Fuel
Fully InsertedControl Rod
24 per Fuel Assembly
-pp tmY = 404.96 cm
UpperCap - Y = 400.662 cm
UpperPlenam .Y a 389.712 cmand sprdng
_ _ a 378.981 cm. 13\- ~-Y = 37J.711 cm
Spacer Region
Absorber Region
Lower Cup Region
-Y. _Y = 17.031 cm
-Y = 16.161 cmv_- AA ONT - aI 1.wgI wi -
Y=0.Ocm -
Y = -30.0 cm -
Reg 6: Lower FuelPlenum andEnd Fitting
_I
Reg 6: Lower ReactorInternals
BOOOOOOOO-01717-570500063 REV 00 14 Augost 15, 1997
Figure 2-9 provides axial dimensions for the pyrex burnable absorber rod assembly for aWestinghouse 17x17 standard fuel assembly.
BPRA Materials/Dimensions:
Lower cap - stainless steel (diameter = 0.96774 cm)
Cladding - stainless steel Outer tube - OD = 0.96774 cm, ID = 0.87376 cmInner tube - OD = 0.46101 cm, ID) = 0.42799 cm
Absorber - B203 -SiO2 Pyrex tube - OD = 0.85344 cm, ED = 0.48260 cm
Upper plenum region - stainless steel clad (outer tube), helium gas in annulus
Upper cap - stainless steel (diameter = 0.96774 cm)
Upper stem - stainless steel (diameter = 0.54356 cm)
BPRA Volume Fractions:
The burnable poison and other materials inside the guide tubes are represented explicitly throughregion 3 and into region 2. This includes most of the upper end cap. The BPRA upper structure(beyond the end cap) is homogenized with the other assembly components within region 2. Thevolume fractions of these materials (including non-BPRA materials) are given in Table 2-6.There are 24 locations (guide tubes) for rod insertion in the fuel assembly. The number ofburnable poison rods varies from 9 to 20 among the BPRAs for cycle I of McGuire 1. A thimbleplug (Figure 2-10) is used for any empty location where a burnable poison rod is not installed.
Table 2.-. Volume Fractions for Assemblies with BPRAs - Regions 2 .3
Volume Fractions BPRAsRegion SS Inc Water
2 0.1649 0.0228 0.81233* 0.0031 0.0264 0.9705
* Region 3 volume fractions are the same as for non-control assemblies.
B00000000-01717.S705-00063 REV 00 is August IS, 1997
Figure 2-9. Axial Dimensions for Pyrex BPRAs for Westinghouse 17x17Standard Fuel Assembly
Y = 437.873 cm- .U
PyrexBurnable Poison Rod
up to 24 per Fuel AssemblyReg 1: Upper Reactor
InternalsY = 407.B7
Y = 392.3E
y 377.71
Y M 11.951
Y = 0.0 cm
Y - -30.0 cn
I- -r* cm-
Reg 2: Upper EndFitting
S7 cm- Reg 3: Upper Fuel
Plenum & EndI cm- Spacer Grid
Reg 4: Active Fuel
cm -
UpperStem
Uppe c-ap
Y = 401.688 cm
A - Y - 398.708 c mI I- V Ub.13b cm
UpperPlenum
- Y e 376.441 cm
Burnable PohsonRegion
Lower Cap Region
- ______ =16.761 cm- ~ Y = 13.863 cm
n ,
Reg 6: Lower FuelPlenum andEnd Fitting
_4
Reg 6: Lower ReactorInternals I
BOOOdOOOO-01717-5705-00063 REV 00 16 August 15, 1997
Figure 2-10. Axial Dimensions for Thimble Plug for Westinghouse 17x17Standard Fuel Assembly
Y = 437.873 cm,
Y = 407.873 cm-
Y = 392.367 cm
Y=377.711 cm -
Y = 11.951 cm-
Y = 0.0 cm -
Y=-30.0cm -
.
Reg 1: Upper ReactorInternals
I_
Reg 2: Upper EndFitting
Thimble Plugfor Empty BP Locations
Upper StemUpper Head f
-. .Y = 400.369 cm= MY = 398.708 cm
Thimbi Neck Y - 397.996 cm
Thimble Plug Y194.288 cm
... ._ Y - 383.315 cm
Rep 3: Upper FuelPlenum & EndSpacer Grid
-4
Reg 4: Active Fuel
-4
Reg 6: Lower FuelPlenum andEnd Fitting
-tRep 6: Lower Reactor
Internals
BOOOOOOO-01717-S705-00063 REV 00 17 August 15, 1997
--
Thimble Plug Materlals/Dimenslons:
Thimble plug - stainless steel (diameter = 1.08204 cm)
Thimble neck - stainless steel (diameter = 0.4826 cm)
Upper head - stainless steel (diameter = 0.96774 cm)
Upper stem - stainless steel (diameter = 0.54356 cm)
BOOOOOO-01717.5705-00063 REV 00 is August 15, 1997
3.0 FUEL CYCLE DESIGN INFORMATION
This section provides fuel assembly design data for cycle 1 of the McGuire Unit I reactor. Fuelassembly design data for later cycles will be provided in a revision to this report Material andgeometry data for the fuel assembly components are presented in Section 3.1. The fuel assemblylocations for cycle 1, fuel enrichments and number of burnable absorber rods for each assembly,and control rod bank locations are presented in Section 3.2.
3.1 Fuel Batch Data
Material and geometry data for each fresh fuel batch present in cycle 1 are given in Table 3-1.This includes the fuel assembly type, the enrichment and kilograms of uranium in each fuelassembly (by batch), the diameter of the fuel pellets, and the type of fuel assembly grid material.The radial dimensions of the fuel clad, instrument tube, and guide tube are also presented. Inaddition, material and radial dimensions for RCCAs and BPRAs are provided. This data shouldbe used in modeling each fuel assembly type for bumup calculations and the reactor criticalitycalculations for the statepoints defined in Table 3-2.
The length of each fuel cycle, expressed as effective-full-power-days (EFPD), is provided inTable 3-2. The time during each cycle where statepoint criticality data was measured is alsopresented.
BOOOOOOOO-01717-5705-00063 REV 00 19 August 15, 1997
Table 3-1. Fuel AssemblylPin/Cycle Description for Cycle 1
FreshFuel Assembly wt % kgUl FP Pellet
eLey. Bath LIie L= AsseMblv OD (cm)I I Std 2.108 458.93 0.81915
2 Std 2.601 458.97 0.819153 Std 3.106 460.39 0.81915
FP - Fuel Pin; PA - Fuel Assembly; BP - Burnable Poison
FP CladQO fern0.949960.949960.94996
FP aad11? (cmn)0.835660.835660.83566
FA GridMaterilInconelInconelInconel
BPRA20LPyrexPyrexPyrex
DesclDtlonInstrument TubeGuide Tube (Upper Region)
(Lower Region)
ECCASPellet MaterialFraction of Pellet MaterialsPellet DensityPellet ODClad MaterialClad ODClad ID
Material OD (cm)Zircaloy 1.22428Zircaloy 1.22428Zircaloy 1.08966
1P 431.1431.1431.00838
Ag-in-CdAg(80%), In(15.0%), Cd(5.0%)10.16 Slcc0.86614 cmSS3040.96774 cm0.87376 cm
BPRAS (Annular - Pyrex tubes)MaterialDensityPyrex ODPyrex IDClad MaterialOuter Clad ODOuter Clad IDInner Clad ODInner Clad ID
B203-SiO22.25 glcc0.85344 cm0.4826 cmSS3040.96774 cm0.87376 cm0.46101 cm0.42799 cm
BDOOOOOOQ001717-S705-00063 REV 00 20 August 15, 1997
Table 3.2. Cycle Length and Time During Cycle Statepoint Data Measured for Cycles 1-7
End-of-CycleEFP
401.4
StatepointNiuber*
SP46
Time of MeasurementEEDP
0.0l
2
3
268.0
288.5
300.0
316.3
4
5
6 298.0
408.0
SP47SP48
SP49SP50SP51
0.062.4
0.0129.0282.3
7
e The unique statepoint numbers SP46, SP47, SP48, SP49, SP50, and SPSI are assigned toMcGuire Unit I data.
3.2 Fuel Assembly Data
The fuel assembly loadings for cycle I are presented in Figure 3-1. (Fuel assembly loadings forlater cycles will be presented in the next revision to this report) A one-eighth corerepresentation is used, where the fuel assembly at the center of the core is in location H8. Theenrichment of U-235 (by batch), the locations of BPRAs, and number of burnable poison (BP)rods in each, and the location of the various control rod banks are also presented. The fuelassemblies with BPRAs may contain different number of BP rods (i.e., 9, 10, 12, 16, or 20 BProds). The location of these BP rods in a fuel assembly along with the orientation of theassembly in the reactor core is presented in Figure 3-2.
BOOOOOOOO.01717-5705.00063 REV 00 21 August IS, 1997
Figure 3-1. Cycle 1 Core Loading
1/ CORE LOADNG FMR MCJRE UINT 1, YCLE1Westinhouse 193FA Core (17 x 17 Arry)
B. AG F E D C
82 1 2 112 1 3
i) F(1) RI) RI) I R) 1(1) (I)Ift 2 1 t 21 1 3 1 3
10FRt)F1) F(1)
2F(t) RI)
2F(1) ~~F(1) I I)
_ _4. -
11 fRI)I
FRI)2
tI)I
F(I) .Ia-4~-I--I - .4 -
12 2I)2
RI)2
RI)3Batch-es; 1 & 3 are SMassy
- I. - I -
13 R1)3
R1)3
.r evlous FAposition ColumrwmR:w (C/) - 139 CornF I C~ycIe FAwas Fresh (F)
= Fuel Batch (B)
Cclde -ac / KgA1 1 ZIOAS 458M
2 2.6 4W.J
BPRALocatons(XW = BP Rods at X nuter of locations
Sep B1310PE; AS, AlO12BP; B1116 E, CO. D9, E10, CtO20EP; Q3, lK B9, DlI, C12
Al BP Rods have Boron badngof 12 wl %2M In glass rodWeISt of Boron Is O0L00419 b/ft
(0.006236 Vc)
EA =Shutdoven Bank A; 612SB = iuftdoiv Bank B; C09
SC1 aShutdown Bard( D,-C11SE =ShutdOM1Bank ED00CA =ConroBankcARBCB ControlBank B, 10CC = ContolBakcBOS, FlCD = ContolBak D; HOD12
Not: An burnae poison rod assenbties (BPRA asseniles were moved duringsteam gertorrepairoutage(some BPholdown springs broken) at l91A EFPD.
BOOOGOOOO.01717-5705-00063 REV 00 22 August 15, 1997
Figure 3-2. Burnable Poison Rod Locations
I I
I
I I I I I I
I
-
I
I I
BOOOOOOO-01717-570540063 REV 00 23 August 15, 197
4.0 CORE OPERATIONS AND STATEPOINT INFORMATION
This section provides core operations data for the burnup calculations required to generateisotopic concentrations for the statepoint evaluations. The measured critical conditions for thestatepoints evaluated are also contained in this section.
4.1 Core Follow Data
The use of commercial reactor criticality data for model validation requires detailed knowledgeof how the reactor was operated for the lifetime of every fuel assembly contributing to thecriticality database. This is necessary in order to adequately model the conditions for bumupcalculations at each axial location of each fuel assembly represented in the reactor core for eachstatepoint evaluation. Thus, core follow calculations based on core operation data are used toprovide local conditions as a function of time to be used for all burnup calculations performed insupport of the statepoint evaluations. In addition, measured global data such as rod insertionsand boron letdown data are also provided.
The core follow calculations provide three-dimensional thermal-hydraulic (CM feedback andbumup data. (his data will be provided in the next revision to this report.)
4.2 Statepolnt Critical Condition Measurements
Measured critical conditions for 6 reactor startups (or statepoints) are provided in Table 4-1. Thedata includes the initial startup of the reactor or beginning-of-life (BOL), the beginning-of-cycle(BOC) of reload cycles 6 and 7, and three reactor restarts during cycles 6 and 7 of McGuire Unit1. The cycle and statepoint number, along with the EFPDs during the cycle for which the startupoccurred, is provided. The elapsed time (in hours) since the reactor was shutdown (downtime)prior to the startup is also given for each statepoint. In addition, Table 4-1 provides the measuredsoluble boron concentration (ppmB), rod bank positions, and temperature of the moderator orcoolant in the reactor (for each statepoint) when criticality was achieved.
Table 4-2 provides shutdown and startup dates for each cycle and statepoint. The cycleshutdown and startup dates can be used in determining the downtime for fuel assemblies that areout of the reactor for one or more cycles and are then reinserted in a later cycle.
BOOOOOOOO-01717-5705-00063 REV 00 24 August 15, 1997
Table 4-1. Statepoint Data for McGuire Unit 1 - Measured Critical Conditions
c£edefSD EM~
1 (SP46) 0.0
6(SP47)
6(SP48)
7(SP49)
7(SP50)
7(SP51)
0.0
62.4
0.0
129.0
2823
Dowrntime(hours)
0
1872
1505
3120
711
451
VZmR
1279
1538
1320
1689
1335
931
WD WD 313 129
Rod Positions, cm above bottom of fuel* T(coolant)Bk CAflk C Dk Bk CD in
558.9
558.1
557.9
WD WD 358 174
WD WD 315 131
WID VD 313
) WD 279
) WD WD :
WD = Rod Withdrawn
129
94
283
558.8
558.2
557
* Measured from the bottom of active fuel region to bottom of control rod absorber region (See Figure 24).
Table 4.2. Statepoint Data for McGufre Unit I - Shutdown and Startup Dates
ce(SP EFPD Shutdown Date
I(SP46) 0.0
2(-)* 0.0 24 Feb 19843(-)* 0.0 19 Apr 1985
4(-)* 0.0 16 May 1986
S(-)* 0.0 04 Sep 1987
6(SP47)* 0.0 12 Oct 1988
6(SP48) 62A 07 Mar 1989
7(SP49)* 0.0 08 Jan 1990
7(SP5O) 129.0 15 Oct 1990
7(SP51) 282.3 25Apr 1991
408.0 (EOC) 20 Sep 1991
EOC = end-of-cycle
Shutdown date is for previous cycle.
Startup Date
08 Aug 1981
28 Apr 1984
24 Jun 1985
07 Sep 1986
12 Nov 1987
29 Dec 1988
09 May 1989
18 May 1990
14 Nov 1990
14 May 1991
BOOOOOOOO-01717-S70500063 REV ao 25 August. 15, 1997
5.0 REFERENCES
1. Quality Assurance Programfor Framatome Cogema Fuels, Document Number. 56-1177617-04, FCF, August 5, 1996.
2. Q-Ust, YMPI90-55Q, REV 04, Yucca Mountain Site Characterization Project.
3. QAP-2-0 Activity Evaluations, ID No. WP-06, Develop Technical Documents, CivilianRadioactive Waste Management System M&O, August 3, 1997.
4. Quality Assurance Requirements and Description, DOE/RW-0333P, REV 7, DOE OCRWM.
5. McGuire I NEMO Depletion and Statepoints (HLW), Document Number: 32-1267111 -00,FCF.
BOOOOOOOO.01717-5705-00063 REV 00 26 August 15, 1997
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