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{{#Wiki_filter:APPENDIX B
{{#Wiki_filter:____________________________________________________________________________
Certificate of Compliance No. 1015 B-1 Renewed Amendment No. 4 APPENDIX B APPROVED CONTENTS AND DESIGN FEATURES FOR THE NAC-UMS SYSTEM AMENDMENT 4


APPROVED CONTENTS AND DESIGN FEATURES FOR THE NAC-UMS SYSTEM
LIST OF EFFECTIVE PAGES (updated by Revision UMSS-04B)
Appendix B Certificate of Compliance No. 1015 B-2 B-1........................Amendment No. 4 B-2........................Amendment No. 4 B-3........................Amendment No. 4 B1-1.......................Amendment No. 4 B2-1.......................Amendment No. 4 B2-2.......................Amendment No. 4 B2-3.......................Amendment No. 4 B2-4.......................Amendment No. 4 B2-5.......................Amendment No. 4 B2-6.......................Amendment No. 4 B2-7.......................Amendment No. 4 B2-8.......................Amendment No. 4 B2-9.......................Amendment No. 4 B2-10.....................Amendment No. 4 B2-11.....................Amendment No. 4 B2-12.....................Amendment No. 4 B2-13.....................Amendment No. 4 B2-14.....................Amendment No. 4 B2-15.....................Amendment No. 4 B2-16.....................Amendment No. 4 B2-17.....................Amendment No. 4 B2-18.....................Amendment No. 4 B3-1....................... Amendment No. 4 B3-2....................... Amendment No. 4 B3-3....................... Amendment No. 4 B3-4....................... Amendment No. 4 B3-5....................... Amendment No. 4 B3-6....................... Amendment No. 4 B3-7....................... Amendment No. 4 B3-8....................... Amendment No. 4 B3-9....................... Amendment No. 4 B3-10..................... Amendment No. 4 B3-11..................... Amendment No. 4 B3-12..................... Amendment No. 4 B3-13..................... Amendment No. 4 Renewed Amendment No. 4


AMENDMENT 4
Approved Contents B 2.0 Certificate of Compliance No. 1015 B-3 Appendix B Table of Contents B 1.0 [Reserved]................................................................................................................... B1-1 B 2.0 Approved Contents..................................................................................................... B2-1 B 2.1 Fuel Specifications and Loading Conditions................................................... B2-1 Figure B2-1 PWR Basket Fuel Loading Positions............................................................ B2-4 Figure B2-2 BWR Basket Fuel Loading Positions............................................................ B2-4 Table B2-1 Fuel Assembly Limits.................................................................................... B2-5 Table B2-2 PWR Fuel Assembly Characteristics............................................................ B2-8 Table B2-3 BWR Fuel Assembly Characteristics............................................................ B2-9 Table B2-4 Minimum Cooling Time Versus Burnup/Initial Enrichment for PWR Fuel................................................................................................... B2-10 Table B2-5 Minimum Cooling Time Versus Burnup/Initial Enrichment for BWR Fuel................................................................................................... B2-11 Table B2-6 Maine Yankee Site Specific Fuel Canister Loading Position Summary..... B2-12 Table B2-7 Maine Yankee Site Specific Fuel Limits..................................................... B2-13 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material - Required Cool Time in Years Before Assembly is Acceptable.................................................................................................. B2-16 Table B2-9 Loading Table for Maine Yankee CE 14 x 14 Fuel Containing CEA Cooled to Indicated Time................................................................... B2-18 B 3.0 Design Features.......................................................................................................... B3-1 B 3.1 Site.................................................................................................................. B3-1 B 3.2 Design Features Important for Criticality Control............................................. B3-1 B 3.3 Codes and Standards...................................................................................... B3-1 B 3.4 Site Specific Parameters and Analyses........................................................... B3-7 B 3.5 CANISTER HANDLING FACILITY (CHF)..................................................... B3-11 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM....................... B3-3 Table B3-2 Load Combinations and Service Condition Definitions for the CANISTER HANDLING FACILITY (CHF) Structure................................... B3-13 Renewed Amendment No. 4  


Certificate of Compliance No. 1015 B-1 Renewed Amendment No. 4 LIST OF EFFECTIVE PAGES (updated by Revision UMSS-04B)
Approved Contents B 2.0 Certificate of Compliance No. 1015 B1-1 1.0
 
[Reserved]
Appendix B
Renewed Amendment No. 4  
 
B-1........................ Amendment No. 4 B-2........................ Amendment No. 4 B-3........................ Amendment No. 4 B3-1....................... Amendment No. 4 B1-1....................... Amendment No. 4 B3-2....................... Amendment No. 4 B3-3....................... Amendment No. 4 B2-1....................... Amendment No. 4 B3-4....................... Amendment No. 4 B2-2....................... Amendment No. 4 B3-5....................... Amendment No. 4 B2-3....................... Amendment No. 4 B3-6....................... Amendment No. 4 B2-4....................... Amendment No. 4 B3-7....................... Amendment No. 4 B2-5....................... Amendment No. 4 B3-8....................... Amendment No. 4 B2-6....................... Amendment No. 4 B3-9....................... Amendment No. 4 B2-7....................... Amendment No. 4 B3-10..................... Amendment No. 4 B2-8....................... Amendment No. 4 B3-11..................... Amendment No. 4 B2-9....................... Amendment No. 4 B3-12..................... Amendment No. 4 B2-10..................... Amendment No. 4 B3-13..................... Amendment No. 4 B2-11..................... Amendment No. 4 B2-12..................... Amendment No. 4 B2-13..................... Amendment No. 4 B2-14..................... Amendment No. 4 B2-15..................... Amendment No. 4 B2-16..................... Amendment No. 4 B2-17..................... Amendment No. 4 B2-18..................... Amendment No. 4
 
Certificate of Compliance No. 1015 B-2 Renewed Amendment No. 4 Approved Contents B 2.0
 
Appendix B Table of Contents
 
B 1.0 [Reserved]................................................................................................................... B1 -1
 
B 2.0 Approved Contents..................................................................................................... B2-1 B 2.1 Fuel Specifications and Loading Conditions................................................... B2-1
 
Figure B2-1 PWR Basket Fuel Loading Positions............................................................ B2-4 Figure B2-2 BWR Basket Fuel Loading Positions............................................................ B2-4 Table B2-1 Fuel Assembly Limits.................................................................................... B2-5 Table B2-2 PWR Fuel Assembly Characteristics............................................................ B2-8 Table B2-3 BWR Fuel Assembly Characteristics............................................................ B2-9 Table B2-4 Minimum Cooling Time Versus Burnup/Initial Enrichment for PWR Fuel...................................................................................................B2-10 Table B2-5 Minimum Cooling Time Versus Burnup/Initial Enrichment for BWR Fuel...................................................................................................B2-11 Table B2-6 Maine Yankee Site Specific Fuel Canister Loading Position Summary..... B2-12 Table B2-7 Maine Yankee Site Specific Fuel Limits..................................................... B2-13 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material - Required Cool Time in Years Before Assembly is Acceptable.................................................................................................. B2-16 Table B2-9 Loading Table for Maine Yankee CE 14 x 14 Fuel Containing CEA Cooled to Indicated Time................................................................... B2-18
 
B 3.0 Design Features.......................................................................................................... B3-1 B 3.1 Site..................................................................................................................B3 -1 B 3.2 Design Features Important for Criticality Control............................................. B3-1 B 3.3 Codes and Standards...................................................................................... B3-1 B 3.4 Site Specific Parameters and Analyses........................................................... B3-7 B 3.5 CANISTER HANDLING FACILITY (CHF)..................................................... B3-11
 
Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM....................... B3-3 Table B3-2 Load Combinations and Service Condition Definitions for the CANISTER HANDLING FACILITY (CHF) Structure................................... B3-13
 
Certificate of Compliance No. 1015 B-3 Renewed Amendment No. 4 Approved Contents B 2.0
 
1.0 [Reserved]
 
Certificate of Compliance No. 1015 B1-1 Renewed Amendment No. 4 Approved Contents B 2.0
 
B 2.0 APPROVED CONTENTS
 
B 2.1 Fuel Specifications and Loading Conditions The NAC-UMS System is designed to provide passive dry storage of canistered PWR and BWR spent fuel. The system requires few operating controls. The principal controls and limits for the NAC-UMS SYSTEM are satisfied by the selection of fuel for storage that meets the Approved Contents presented in this section and in Tables B2-1 through B2-5 for the standard NAC-UMS SYSTEM design basis spent fuels.


Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-1 B 2.0 APPROVED CONTENTS B 2.1 Fuel Specifications and Loading Conditions The NAC-UMS System is designed to provide passive dry storage of canistered PWR and BWR spent fuel. The system requires few operating controls. The principal controls and limits for the NAC-UMS SYSTEM are satisfied by the selection of fuel for storage that meets the Approved Contents presented in this section and in Tables B2-1 through B2-5 for the standard NAC-UMS SYSTEM design basis spent fuels.
This section also permits the loading of fuel assemblies that are unique to specific reactor sites. SITE SPECIFIC FUEL assembly configurations are either shown to be bounded by the analysis of the standard NAC-UMS System design basis fuel assembly configuration of the same type (PWR or BWR), or are shown to be acceptable contents by specific evaluation of the configuration.
This section also permits the loading of fuel assemblies that are unique to specific reactor sites. SITE SPECIFIC FUEL assembly configurations are either shown to be bounded by the analysis of the standard NAC-UMS System design basis fuel assembly configuration of the same type (PWR or BWR), or are shown to be acceptable contents by specific evaluation of the configuration.
The separate specific evaluation may establish different limits, which are maintained by administrative controls for preferential loading. The preferential loading controls allow the loading of fuel configurations that may have higher burnup, additional hardware material or unique configurations as compared to the standard NAC-UMS System design basis spent fuels.
The separate specific evaluation may establish different limits, which are maintained by administrative controls for preferential loading. The preferential loading controls allow the loading of fuel configurations that may have higher burnup, additional hardware material or unique configurations as compared to the standard NAC-UMS System design basis spent fuels.
Unless specifically excepted, SITE SPECIFIC FUEL must meet all of the controls and limits specified for the NAC-UMS System.
Unless specifically excepted, SITE SPECIFIC FUEL must meet all of the controls and limits specified for the NAC-UMS System.
If any Fuel Specification or Loading Conditions of this section are violated, the following actions shall be completed:
If any Fuel Specification or Loading Conditions of this section are violated, the following actions shall be completed:
* The affected fuel assemblies shall be placed in a safe condition.
The affected fuel assemblies shall be placed in a safe condition.
* Within 24 hours, notify the NRC Operations Center.
Within 24 hours, notify the NRC Operations Center.
* Within 30 days, submit a special report that describes the cause of the violation and actions taken to restore or demonstrate compliance and prevent recurrence.
Within 30 days, submit a special report that describes the cause of the violation and actions taken to restore or demonstrate compliance and prevent recurrence.
 
(continued)
(continued)
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B2-1 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-2 B 2.1.1 Fuel to be Stored in the NAC-UMS SYSTEM INTACT FUEL ASSEMBLIES meeting the limits specified in Tables B2-1 through B2-5 may be stored in the NAC-UMS SYSTEM.
 
B 2.1.2 Maine Yankee SITE SPECIFIC FUEL Preferential Loading The estimated Maine Yankee SITE SPECIFIC FUEL inventory is shown in Table B2-6.
B 2.1.1 Fuel to be Stored in the NAC-UMS SYSTEM
 
INTACT FUEL ASSEMBLIES meeting the limits specified in Tables B2-1 through B2-5 may be stored in the NAC-UMS SYSTEM.
 
B 2.1.2 Maine Yankee SITE SPECIFIC FUEL Preferential Loading
 
The estimated Maine Yankee SITE SPECIFIC FUEL inventory is shown in Table B2-6.
As shown in this table, certain of the Maine Yankee fuel configurations must be preferentially loaded in specific basket fuel tube positions.
As shown in this table, certain of the Maine Yankee fuel configurations must be preferentially loaded in specific basket fuel tube positions.
Corner positions are used for CONSOLIDATED FUEL, certain HIGH BURNUP FUEL and DAMAGED FUEL or FUEL DEBRIS loaded in a MAINE YANKEE FUEL CAN, for fuel assemblies with missing fuel rods, burnable poison rods or fuel assemblies with fuel rods that have been replaced by hollow zirconium alloy rods. Designation for placement in corner positions results primarily from shielding or criticality evaluations of these fuel configurations. CONSOLIDATED FUEL is conservatively designated for a corner position, even though analysis shows that these lattices could be loaded in any basket position.
Corner positions are used for CONSOLIDATED FUEL, certain HIGH BURNUP FUEL and DAMAGED FUEL or FUEL DEBRIS loaded in a MAINE YANKEE FUEL CAN, for fuel assemblies with missing fuel rods, burnable poison rods or fuel assemblies with fuel rods that have been replaced by hollow zirconium alloy rods. Designation for placement in corner positions results primarily from shielding or criticality evaluations of these fuel configurations. CONSOLIDATED FUEL is conservatively designated for a corner position, even though analysis shows that these lattices could be loaded in any basket position.
Corner positions are positions 3, 6, 19, and 22 in Figure B2-1.
Corner positions are positions 3, 6, 19, and 22 in Figure B2-1.
Preferential loading is also used for HIGH BURNUP fuel not loaded in the MAINE YANKEE FUEL CAN. This fuel is assigned to peripheral locations, positions 1, 2, 3, 6, 7, 12, 13, 18, 19, 22, 23, and 24 in Figure B2-1. The interior locations, positions 4, 5, 8, 9, 10, 11, 14, 15, 16, 17, 20, and 21, must be loaded with fuel that has lower burnup and/or longer cool times to maintain the design basis heat load (23 kW per canister).
Preferential loading is also used for HIGH BURNUP fuel not loaded in the MAINE YANKEE FUEL CAN. This fuel is assigned to peripheral locations, positions 1, 2, 3, 6, 7, 12, 13, 18, 19, 22, 23, and 24 in Figure B2-1. The interior locations, positions 4, 5, 8, 9, 10, 11, 14, 15, 16, 17, 20, and 21, must be loaded with fuel that has lower burnup and/or longer cool times to maintain the design basis heat load (23 kW per canister).
One of the two loading patterns (Standard or Preferential) shown in Table B2-8 must be used to load each canister. For the Standard loading pattern, the heat load of each fuel assembly is limited to 0.958 kW. For the Preferential loading pattern, the heat load of the fuel assemblies at the basket periphery locations is limited to 1.05 kW, and the heat load of the fuel assemblies at the basket interior locations is limited to 0.867 kW. Once selected, all of the spent fuel in that canister must be loaded in accordance with that pattern. Within a pattern, mixing of enrichment and cool time is allowed, but no mixing of loading patterns is permitted. Choosing a Preferential pattern restricts the interior fuel to the cool times shown in the Preferential (I) column, and the peripheral fuel to the cool times shown in the Preferential (P) column.
One of the two loading patterns (Standard or Preferential) shown in Table B2-8 must be used to load each canister. For the Standard loading pattern, the heat load of each fuel assembly is limited to 0.958 kW. For the Preferential loading pattern, the heat load of the fuel assemblies at the basket periphery locations is limited to 1.05 kW, and the heat load of the fuel assemblies at the basket interior locations is limited to 0.867 kW. Once selected, all of the spent fuel in that canister must be loaded in accordance with that pattern. Within a pattern, mixing of enrichment and cool time is allowed, but no mixing of loading patterns is permitted. Choosing a Preferential pattern restricts the interior fuel to the cool times shown in the Preferential (I) column, and the peripheral fuel to the cool times shown in the Preferential (P) column.
(continued)
(continued)
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B2-2 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-3 B 2.1.2 Maine Yankee SITE SPECIFIC FUEL Preferential Loading (continued)
 
B 2.1.2 Maine Yankee SITE SPECIFIC FUEL Preferential Loading (continued)
 
Fuel assemblies with a control element assembly (CEA) inserted will be loaded in a Class 2 canister and basket due to the increased length of the assembly with the CEA installed. However, these assemblies are not restricted as to loading position within the basket. Fuel assemblies with non-fuel items installed in corner guide tubes of the fuel assembly must also have a flow mixer installed and must be loaded in a basket corner fuel position in a Class 2 canister.
Fuel assemblies with a control element assembly (CEA) inserted will be loaded in a Class 2 canister and basket due to the increased length of the assembly with the CEA installed. However, these assemblies are not restricted as to loading position within the basket. Fuel assemblies with non-fuel items installed in corner guide tubes of the fuel assembly must also have a flow mixer installed and must be loaded in a basket corner fuel position in a Class 2 canister.
The Transportable Storage Canister loading procedures indicate that loading of a fuel configuration with removed fuel or poison rods, CONSOLIDATED FUEL, or a MAINE YANKEE FUEL CAN with DAMAGED FUEL, FUEL DEBRIS or HIGH BURNUP FUEL, is administratively controlled in accordance with Section B 2.1.
The Transportable Storage Canister loading procedures indicate that loading of a fuel configuration with removed fuel or poison rods, CONSOLIDATED FUEL, or a MAINE YANKEE FUEL CAN with DAMAGED FUEL, FUEL DEBRIS or HIGH BURNUP FUEL, is administratively controlled in accordance with Section B 2.1.
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B2-3 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-4 Figure B2-1 PWR Basket Fuel Loading Positions Figure B2-2 BWR Basket Fuel Loading Positions Renewed Amendment No. 4  


Figure B2-1 PWR Basket Fuel Loading Positions
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-5 Table B2-1 Fuel Assembly Limits I.
 
NAC-UMS CANISTER: PWR FUEL A. Allowable Contents 1.
Figure B2-2 BWR Basket Fuel Loading Positions
Uranium oxide PWR INTACT FUEL ASSEMBLIES listed in Table B2-2 and meeting the following specifications:
 
a.
Certificate of Compliance No. 1015 B2-4 Renewed Amendment No. 4 Approved Contents B 2.0
Cladding Type:
 
Zirconium alloy with thickness as specified in Table B2-2 for the applicable fuel assembly class.
Table B2-1 Fuel Assembly Limits I. NAC-UMS CANISTER: PWR FUEL A. Allowable Contents
b.
: 1. Uranium oxide PWR INTACT FUEL ASSEMBLIES listed in Table B2-2 and meeting the following specifications:
Enrichment, Post-irradiation Cooling Time and Average Burnup Per Assembly:
: a. Cladding Type: Zirconium alloy with thickness as specified in Table B2-2 for the applicable fuel assembly class.
Maximum enrichment limits are shown in Table B2-2. For variable enrichment fuel assemblies, maximum enrichments represent peak rod enrichments. Combined minimum enrichment, maximum burnup and minimum cool time limits are shown in Table B2-4.
: b. Enrichment, Post-Maximum enrichment limits are shown in Table irradiation Cooling Time B2-2. For variable enrichment fuel assemblies, and Average Burnup maximum enrichments represent peak rod Per Assembly: enrichments. Combined minimum enrichment, maximum burnup and minimum cool time limits are shown in Table B2-4.
c.
: c. Decay Heat Per 958.3 watts Assembly: <
Decay Heat Per Assembly:
: d. Nominal Fresh Fuel < 178.3 Assembly Length (in.):
< 958.3 watts d.
: e. Nominal Fresh Fuel < 8.54 Assembly Width (in.):
Nominal Fresh Fuel Assembly Length (in.):
: f. Fuel Assembly Weight < 1,602 (lbs.):
< 178.3 e.
 
Nominal Fresh Fuel Assembly Width (in.):
Decay heat may be higher for site-specific configurations, which control fuel loading position.
< 8.54 f.
Fuel Assembly Weight (lbs.):
< 1,602 Decay heat may be higher for site-specific configurations, which control fuel loading position.
Includes the weight of nonfuel-bearing components.
Includes the weight of nonfuel-bearing components.
B. Quantity per CANISTER: Up to 24 PWR INTACT FUEL ASSEMBLIES.
B. Quantity per CANISTER: Up to 24 PWR INTACT FUEL ASSEMBLIES.
C. PWR INTACT FUEL ASSEMBLIES may contain a flow mixer (thimble plug), an in-core instrument thimble, a burnable poison rod insert (Class 1 and Class 2 contents) consistent with Table B2-2, or solid stainless steel rods (insert ed in the guide tubes).
C. PWR INTACT FUEL ASSEMBLIES may contain a flow mixer (thimble plug), an in-core instrument thimble, a burnable poison rod insert (Class 1 and Class 2 contents) consistent with Table B2-2, or solid stainless steel rods (inserted in the guide tubes).
D. PWR INTACT FUEL ASSEMBLIES shall not contain a control element assembly, except as permitted for SITE-SPECI FIC FUEL.
D. PWR INTACT FUEL ASSEMBLIES shall not contain a control element assembly, except as permitted for SITE-SPECIFIC FUEL.
E. Stainless steel spacers may be used in CANISTERS to axially position PWR INTACT FUEL ASSEMBLIES that are shorter than the available cavity length to facilitate handling.
E. Stainless steel spacers may be used in CANISTERS to axially position PWR INTACT FUEL ASSEMBLIES that are shorter than the available cavity length to facilitate handling.
F. Unenriched fuel assemblies are not authorized f or loading.
F. Unenriched fuel assemblies are not authorized for loading.
G. The minimum length of the PWR INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure that the minimum distance to the fuel region from the base of the CANISTER is 3.2 inches.
G. The minimum length of the PWR INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure that the minimum distance to the fuel region from the base of the CANISTER is 3.2 inches.
H. PWR INTACT FUEL ASSEMBLIES with one or more grid spacers missing or damaged such that the unsupported length of the fuel rods does not exceed 60 inches. End fitting damage including damag ed or missing hold-down springs is allowed, as long as the assembly can be handled safely by normal means.
H. PWR INTACT FUEL ASSEMBLIES with one or more grid spacers missing or damaged such that the unsupported length of the fuel rods does not exceed 60 inches. End fitting damage including damaged or missing hold-down springs is allowed, as long as the assembly can be handled safely by normal means.
 
Renewed Amendment No. 4  
Certificate of Compliance No. 1015 B2-5 Renewed Amendment No. 4 Approved Contents B 2.0
 
Table B2-1 Fuel Assembly Limits (continued)


II. NAC-UMS CANISTER: BWR FUEL A. Allowable Contents
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-6 Table B2-1 Fuel Assembly Limits (continued)
: 1. Uranium oxide BWR INTACT FUEL ASSEMBLIES listed in Table B2-3 and meeting the following specifications:
II.
: a. Cladding Type: Zirconium alloy with thickness as specified in Table B2-3 for the applicable fuel assembly class.
NAC-UMS CANISTER: BWR FUEL A. Allowable Contents 1.
: b. Enrichment: Maximum INITIAL PEAK PLANAR-AVERAGE ENRICHMENTS are shown in Table B2-3.
Uranium oxide BWR INTACT FUEL ASSEMBLIES listed in Table B2-3 and meeting the following specifications:
: a. Cladding Type:
Zirconium alloy with thickness as specified in Table B2-3 for the applicable fuel assembly class.
: b. Enrichment:
Maximum INITIAL PEAK PLANAR-AVERAGE ENRICHMENTS are shown in Table B2-3.
Combined minimum enrichment, maximum burnup and minimum cool time limits are shown in Table B2-5.
Combined minimum enrichment, maximum burnup and minimum cool time limits are shown in Table B2-5.
: c. Decay Heat per Assembly: < 410.7 watts
: c. Decay Heat per Assembly:
: d. Post-irradiation Cooling TimeAs specified in Table B2-5 and for the and Average Burnup Per applicable fuel assembly class.
< 410.7 watts
Assembly:
: d. Post-irradiation Cooling Time and Average Burnup Per Assembly:
: e. Nominal Fresh Fuel Design < 176.1 Assembly Length (in.):
As specified in Table B2-5 and for the applicable fuel assembly class.
: f. Nominal Fresh Fuel Design < 5.51 Assembly Width (in.):
: e. Nominal Fresh Fuel Design Assembly Length (in.):
: g. Fuel Assembly Weight (lbs): <702, including channels
< 176.1 f.
 
Nominal Fresh Fuel Design Assembly Width (in.):
Certificate of Compliance No. 1015 B2-6 Renewed Amendment No. 4 Approved Contents B 2.0
< 5.51
: g. Fuel Assembly Weight (lbs):
< 702, including channels Renewed Amendment No. 4  


Table B2-1 Fuel Assembly Limits (continued)
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-7 Table B2-1 Fuel Assembly Limits (continued)
B.
Quantity per CANISTER: Up to 56 BWR INTACT FUEL ASSEMBLIES C.
BWR INTACT FUEL ASSEMBLIES can be unchanneled or channeled with zirconium alloy channels.
D.
BWR INTACT FUEL ASSEMBLIES with stainless steel channels shall not be loaded.
E.
Stainless steel fuel spacers may be used in CANISTERS to axially position BWR INTACT FUEL ASSEMBLIES that are shorter than the available cavity length to facilitate handling.
F.
Unenriched fuel assemblies are not authorized for loading.
G.
The minimum length of the BWR INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure that the minimum distance to the fuel region from the base of the CANISTER is 6.2 inches.
Renewed Amendment No. 4


B. Quantity per CANISTER: Up to 56 BWR INTACT FUEL ASSEMBLIES C. BWR INTACT FUEL ASSEMBLIES can be unchanneled or channeled with zirconium alloy channels.
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-8 Table B2-2 PWR Fuel Assembly Characteristics Fuel Class Vendor 1 Array Max.
D. BWR INTACT FUEL ASSEMBLIES with stainless steel ch annels shall not be loaded.
MTU W/O Boron Max.
E. Stainless steel fuel spacers may be used in CANISTERS to axially position BWR INTACT FUEL ASSEMBLIES that ar e shorter than the available cavity length to facilitate handling.
wt %
F. Unenriched fuel assemblies are not authorized f or loading.
235U 4 With Boron Max.
G. The minimum length of the BWR INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure that the minimum distance to the fuel region from the base of the CANISTER is 6.2 inches.
wt %
235U 5 No. of Fuel Rods 3 No. of Water Holes Max.
Pitch (in)
Min.
Rod Dia. (in)
Min.
Clad Thick (in)
Max.
Pellet Dia.(in)
Max.
Active Length (in)
Min. Guide Tube Thick (in) 1 CE 14x14 0.404 4.7 5.0 176 5
0.590 0.438 0.024 0.380 137.0 0.034 1
Ex/ANF 14x14 0.369 5.0 5.0 179 17 0.556 0.424 0.030 0.351 142.0 0.034 1
WE 14x14 0.362 5.0 5.0 179 17 0.556 0.400 0.024 0.345 144.0 0.034 1
WE 14x14 0.415 5.0 5.0 179 17 0.556 0.422 0.022 0.368 145.2 0.034 1
WE, Ex/ANF 15x15 0.465 4.4 5.0 204 21 0.563 0.422 0.024 0.366 144.0 0.015 1
Ex/ANF 17x17 0.413 4.4 5.0 264 25 0.496 0.360 0.025 0.303 144.0 0.016 1
WE 17x17 0.468 4.5 5.0 264 25 0.496 0.374 0.022 0.323 144.0 0.015 1
WE 17x17 0.429 4.3 5.0 264 25 0.496 0.360 0.022 0.309 144.0 0.015 2
B&W 15x15 0.481 4.4 5.0 208 17 0.568 0.430 0.026 0.369 144.0 0.016 2
B&W 17x17 0.466 4.4 5.0 264 25 0.502 0.379 0.024 0.324 143.0 0.017 3
CE 16x16 0.442 4.8 5.0 236 5
0.506 0.382 0.023 0.3255 150.0 0.035 1
Ex/ANF2 14x14 0.375 5.0 179 17 0.556 0.417 0.030 0.351 144.0 0.036 1
CE2 15x15 0.432 4.2 216 9 6 0.550 0.418 0.026 0.358 132.0 1
Ex/ANF2 15x15 0.431 4.2 216 9 6 0.550 0.417 0.030 0.358 131.8 1
CE2 16x16 0.403 4.8 236 5
0.506 0.382 0.023 0.3255 136.7 0.035 Note: Parameters shown are nominal pre-irradiation values.
1.
Vendor ID indicates the source of assembly base parameters, which are nominal, pre-irradiation values. Loading of assemblies meeting above limits is not restricted to the vendor(s) listed.
2.
14x14, 15x15 and 16x16 fuel manufactured for Prairie Island, Palisades and St. Lucie 2 cores, respectively. These are not generic fuel assemblies provided to multiple reactors.
3.
Fuel rod positions may be occupied by burnable poison rods or solid filler rods.
4.
Maximum initial enrichment without boron credit. Assemblies meeting this limit may contain a flow mixer (thimble plug), an ICI thimble, a burnable poison rod insert, or solid stainless steel rods (inserted in guide tubes).
5.
Maximum initial enrichment with credit for a minimum soluble boron concentration of 1000 ppm in the spent fuel pool water. Assemblies meeting this limit may contain a flow mixer (thimble plug).
6.
Nine non-fuel locations, which may be filled by solid non-fuel rods.
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B2-7 Renewed Amendment No. 4
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-9 Amendment No. 4 Table B2-3 BWR Fuel Assembly Characteristics Fuel Class1 Vendor4 Array Max.
MTU Max.
wt % 235U No. of Fuel Rods Max.
Pitch (in)
Min. Rod Dia. (in)
Min. Clad Thick (in)
Max.
Pellet Dia.(in)
Max. Active Length (in)2 4
Ex/ANF 7 x 7 0.196 4.5 48 0.738 0.570 0.036 0.490 144.0 4
Ex/ANF 8 x 8 0.177 4.7 63 0.641 0.484 0.036 0.405 145.2 4
Ex/ANF 9 x 9 0.173 4.4 79 0.572 0.424 0.030 0.357 145.2 4
GE 7 x 7 0.199 4.5 49 0.738 0.570 0.036 0.488 144.0 4
GE 7 x 7 0.198 4.5 49 0.738 0.563 0.032 0.487 144.0 4
GE 8 x 8 0.173 4.5 60 0.640 0.484 0.032 0.410 145.2 4
GE 8 x 8 0.179 4.5 62 0.640 0.483 0.032 0.410 145.2 4
GE 8 x 8 0.186 4.7 63 0.640 0.493 0.034 0.416 144.0 5
Ex/ANF 8 x 8 0.180 4.6 62 0.641 0.484 0.036 0.405 150.0 5
Ex/ANF 9 x 9 0.167 4.4 743 0.572 0.424 0.030 0.357 150.0 5
Ex/ANF 9 x 9 0.178 4.5 793 0.572 0.424 0.030 0.357 150.0 5
GE 7 x 7 0.193 4.7 49 0.738 0.563 0.037 0.477 146.0 5
GE 7 x 7 0.198 4.5 49 0.738 0.563 0.032 0.487 144.0 5
GE 8 x 8 0.179 4.5 60 0.640 0.484 0.032 0.410 150.0 5
GE 8 x 8 0.185 4.5 62 0.640 0.483 0.032 0.410 150.0 5
GE 8 x 8 0.188 4.7 63 0.640 0.493 0.034 0.416 146.0 5
GE 9 x 9 0.186 4.5 743 0.566 0.441 0.028 0.376 150.0 5
GE 9 x 9 0.198 4.6 793 0.566 0.441 0.028 0.376 150.0 Note: Parameters shown are nominal pre-irradiation values.
: 1. All fuel rods are zirconium alloy clad.
: 2. 150-inch active fuel length assemblies contain 6 natural uranium blankets on top and bottom.
: 3. Shortened active fuel length in some rods.
: 4. Vendor ID indicates the source of assembly base parameters, which are nominal, pre-irradiation values. Loading of assemblies meeting above limits is not restricted to the vendor(s) listed.
Renewed


Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance B2-10 Table B2-4 Minimum Cooling Time Versus Burnup/Initial Enrichment for PWR Fuel Minimum Initial Enrichment Burnup 30 GWD/MTU Minimum Cooling Time [years]
30< Burnup 35 GWD/MTU Minimum Cooling Time [years]
wt % 235U (E) 14x14 15x15 16x16 17x17 14x14 15x15 16x16 17x17 1.9 E < 2.1 5
5 5
5 7
7 5
7 2.1 E < 2.3 5
5 5
5 7
6 5
6 2.3 E < 2.5 5
5 5
5 6
6 5
6 2.5 E < 2.7 5
5 5
5 6
6 5
6 2.7 E < 2.9 5
5 5
5 6
5 5
5 2.9 E < 3.1 5
5 5
5 5
5 5
5 3.1 E < 3.3 5
5 5
5 5
5 5
5 3.3 E < 3.5 5
5 5
5 5
5 5
5 3.5 E < 3.7 5
5 5
5 5
5 5
5 3.7 E < 3.9 5
5 5
5 5
5 5
5 3.9 E < 4.1 5
5 5
5 5
5 5
5 4.1 E < 4.3 5
5 5
5 5
5 5
5 4.3 E < 4.5 5
5 5
5 5
5 5
5 4.5 E < 4.7 5
5 5
5 5
5 5
5 4.7 E < 4.9 5
5 5
5 5
5 5
5 E 4.9 5
5 5
5 5
5 5
5 Minimum Initial Enrichment 35< Burnup 40 GWD/MTU Minimum Cooling Time [years]
40< Burnup 45 GWD/MTU Minimum Cooling Time [years]
wt % 235U (E) 14x14 15x15 16x16 17x17 14x14 15x15 16x16 17x17 1.9 E < 2.1 10 10 7
10 15 15 11 15 2.1 E < 2.3 9
9 6
9 14 13 9
13 2.3 E < 2.5 8
8 6
8 12 12 8
12 2.5 E < 2.7 8
7 6
7 11 11 7
11 2.7 E < 2.9 7
7 6
7 10 10 7
10 2.9 E < 3.1 7
6 6
7 9
9 7
9 3.1 E < 3.3 6
6 6
6 9
8 7
8 3.3 E < 3.5 6
6 6
6 8
8 7
8 3.5 E < 3.7 6
6 6
6 7
8 7
7 3.7 E < 3.9 6
6 6
6 7
8 7
7 3.9 E < 4.1 6
6 6
6 7
7 7
7 4.1 E < 4.3 5
6 6
6 6
7 7
7 4.3 E < 4.5 5
6 6
6 6
7 7
7 4.5 E < 4.7 5
6 5
6 6
7 6
7 4.7 E < 4.9 5
6 5
6 6
7 6
7 E 4.9 5
6 5
6 6
7 6
7 Renewed Amendment No. 4


Table B2-4 Minimum Cooling Time Versus Burnup/Initial Enrichment for PWR Fuel Minimum Burnup 30 GWD/MTU 30< Burnup 35 GWD/MTU Initial Minimum Cooling Time [years] Minimum Cooling Time [years]
Approved Contents B 2.0 Certificate of Compliance B2-11 Table B2-5 Minimum Cooling Time Versus Burnup/Initial Enrichment for BWR Fuel Minimum Initial Enrichment Burnup 30 GWD/MTU Minimum Cooling Time [years]
Enrichment wt % 235U (E) 14x14 15x15 16x16 17x17 14x14 15x15 16x16 17x17 1.9 E < 2.1 5 5 5 5 7 7 5 7 2.1 E < 2.3 5 5 5 5 7 6 5 6 2.3 E < 2.5 5 5 5 5 6 6 5 6 2.5 E < 2.7 5 5 5 5 6 6 5 6 2.7 E < 2.9 5 5 5 5 6 5 5 5 2.9 E < 3.1 5 5 5 5 5 5 5 5 3.1 E < 3.3 5 5 5 5 5 5 5 5 3.3 E < 3.5 5 5 5 5 5 5 5 5 3.5 E < 3.7 5 5 5 5 5 5 5 5 3.7 E < 3.9 5 5 5 5 5 5 5 5 3.9 E < 4.1 5 5 5 5 5 5 5 5 4.1 E < 4.3 5 5 5 5 5 5 5 5 4.3 E < 4.5 5 5 5 5 5 5 5 5 4.5 E < 4.7 5 5 5 5 5 5 5 5 4.7 E < 4.9 5 5 5 5 5 5 5 5 E 4.9 5 5 5 5 5 5 5 5 Minimum 35< Burnup 40 GWD/MTU 40< Burnup 45 GWD/MTU Initial Minimum Cooling Time [years] Minimum Cooling Time [years]
30< Burnup 35 GWD/MTU Minimum Cooling Time [years]
Enrichment wt % 235U (E) 14x14 15x15 16x16 17x17 14x14 15x15 16x16 17x17 1.9 E < 2.1 10 10 7 10 15 15 11 15 2.1 E < 2.3 9 9 6 9 14 13 9 13 2.3 E < 2.5 8 8 6 8 12 12 8 12 2.5 E < 2.7 8 7 6 7 11 11 7 11 2.7 E < 2.9 7 7 6 7 10 10 7 10 2.9 E < 3.1 7 6 6 7 9 9 7 9 3.1 E < 3.3 6 6 6 6 9 8 7 8 3.3 E < 3.5 6 6 6 6 8 8 7 8 3.5 E < 3.7 6 6 6 6 7 8 7 7 3.7 E < 3.9 6 6 6 6 7 8 7 7 3.9 E < 4.1 6 6 6 6 7 7 7 7 4.1 E < 4.3 5 6 6 6 6 7 7 7 4.3 E < 4.5 5 6 6 6 6 7 7 7 4.5 E < 4.7 5 6 5 6 6 7 6 7 4.7 E < 4.9 5 6 5 6 6 7 6 7 E 4.9 5 6 5 6 6 7 6 7
wt % 235U (E) 7x7 8x8 9x9 7x7 8x8 9x9 1.9 E < 2.1 5
5 5
8 7
7 2.1 E < 2.3 5
5 5
6 6
6 2.3 E < 2.5 5
5 5
6 5
6 2.5 E < 2.7 5
5 5
5 5
5 2.7 E < 2.9 5
5 5
5 5
5 2.9 E < 3.1 5
5 5
5 5
5 3.1 E < 3.3 5
5 5
5 5
5 3.3 E < 3.5 5
5 5
5 5
5 3.5 E < 3.7 5
5 5
5 5
5 3.7 E < 3.9 5
5 5
5 5
5 3.9 E < 4.1 5
5 5
5 5
5 4.1 E < 4.3 5
5 5
5 5
5 4.3 E < 4.5 5
5 5
5 5
5 4.5 E 4.7 5
5 5
5 5
5 Minimum Initial Enrichment 35< Burnup 40 GWD/MTU Minimum Cooling Time [years]
40< Burnup 45 GWD/MTU Minimum Cooling Time [years]
wt % 235U (E) 7x7 8x8 9x9 7x7 8x8 9x9 1.9 E < 2.1 16 14 15 26 24 25 2.1 E < 2.3 13 12 12 23 21 22 2.3 E < 2.5 11 9
10 20 18 19 2.5 E < 2.7 9
8 8
18 16 17 2.7 E < 2.9 8
7 7
15 13 14 2.9 E < 3.1 7
6 6
13 11 12 3.1 E < 3.3 6
6 6
11 10 10 3.3 E < 3.5 6
5 6
9 8
9 3.5 E < 3.7 6
5 6
8 7
7 3.7 E < 3.9 6
5 5
7 6
7 3.9 E < 4.1 5
5 5
7 6
7 4.1 E < 4.3 5
5 5
7 6
6 4.3 E < 4.5 5
5 5
6 6
6 4.5 E 4.7 5
5 5
6 6
6 Renewed Amendment No. 4  


Certificate of Compliance B2-10 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance B2-12 Table B2-6 Maine Yankee Site Specific Fuel Canister Loading Position Summary Site Specific Spent Fuel Configurations1 Est. Number of Assemblies2 Canister Loading Position Total Number of Fuel Assemblies3 1,434 Any Inserted Control Element Assembly (CEA) 168 Any Inserted In-Core Instrument (ICI) Thimble 138 Any Consolidated Fuel 2
 
Corner4 Fuel Rod Replaced by Rod Enriched to 1.95 wt %
Table B2-5 Minimum Cooling Time Versus Burnup/Initial Enrichment for BWR Fuel
3 Any Fuel Rod Replaced by Stainless Steel Rod or Zirconium Alloy Rod 18 Any Fuel Rods Removed 10 Corner4 Variable Enrichment6 72 Any Variable Enrichment and Axial Blanket6 68 Any Burnable Poison Rod Replaced by Hollow Zirconium Alloy Rod 80 Corner4 Damaged Fuel in MAINE YANKEE FUEL CAN 12 Corner4 Burnup between 45,000 and 50,000 MWD/MTU 90 Periphery5 MAINE YANKEE FUEL CAN As Required Corner4 Inserted Start-up Source 4
 
Corner4 Inserted CEA Finger Tip or ICI String Segment 1
Minimum Burnup 30 GWD/MTU 30< Burnup 35 GWD/MTU Initial Minimum Cooling Time [years] Minimum Cooling Time [years]
Corner4 1.
Enrichment wt % 235U (E) 7x7 8x8 9x9 7x7 8x8 9x9 1.9 E < 2.1 5 5 5 8 7 7 2.1 E < 2.3 5 5 5 6 6 6 2.3 E < 2.5 5 5 5 6 5 6 2.5 E < 2.7 5 5 5 5 5 5 2.7 E < 2.9 5 5 5 5 5 5 2.9 E < 3.1 5 5 5 5 5 5 3.1 E < 3.3 5 5 5 5 5 5 3.3 E < 3.5 5 5 5 5 5 5 3.5 E < 3.7 5 5 5 5 5 5 3.7 E < 3.9 5 5 5 5 5 5 3.9 E < 4.1 5 5 5 5 5 5 4.1 E < 4.3 5 5 5 5 5 5 4.3 E < 4.5 5 5 5 5 5 5 4.5 E 4.7 5 5 5 5 5 5
All spent fuel, including that held in a Maine Yankee fuel can, must conform to the loading limits presented in Tables B2-8 and B2-9 for cool time.
 
2.
Minimum 35< Burnup 40 GWD/MTU 40< Burnup 45 GWD/MTU Initial Minimum Cooling Time [years] Minimum Cooling Time [years]
The number of fuel assemblies in some categories may vary depending on future fuel inspections.
Enrichment wt % 235U (E) 7x7 8x8 9x9 7x7 8x8 9x9 1.9 E < 2.1 16 14 15 26 24 25 2.1 E < 2.3 13 12 12 23 21 22 2.3 E < 2.5 11 9 10 20 18 19 2.5 E < 2.7 9 8 8 18 16 17 2.7 E < 2.9 8 7 7 15 13 14 2.9 E < 3.1 7 6 6 13 11 12 3.1 E < 3.3 6 6 6 11 10 10 3.3 E < 3.5 6 5 6 9 8 9 3.5 E < 3.7 6 5 6 8 7 7 3.7 E < 3.9 6 5 5 7 6 7 3.9 E < 4.1 5 5 5 7 6 7 4.1 E < 4.3 5 5 5 7 6 6 4.3 E < 4.5 5 5 5 6 6 6 4.5 E 4.7 5 5 5 6 6 6
3.
 
Includes these site specific spent fuel configurations and standard fuel assemblies. Standard fuel assemblies may be loaded in any canister position.
Certificate of Compliance B2-11 Renewed Amendment No. 4 Approved Contents B 2.0
4.
 
Basket corner positions are positions 3, 6, 19, and 22 in Figure B2-1. Corner positions are also periphery positions.
Table B2-6 Maine Yankee Site Specific Fuel Canister Loading Position Summary
5.
 
Basket periphery positions are positions 1, 2, 3, 6, 7, 12, 13, 18, 19, 22, 23, and 24 in Figure B2-1. Periphery positions include the corner positions.
Est. Number of Site Specific Spent Fuel Configurations 1 Assemblies2 Canister Loading Position Total Number of Fuel Assemblies 3 1,434 Any Inserted Control Element Assembly (CEA) 168 Any Inserted In-Core Instrument (ICI) Thimble 138 Any Consolidated Fuel 2 Corner4 Fuel Rod Replaced by Rod Enriched to 1.95 wt % 3 Any Fuel Rod Replaced by Stainless Steel Rod or Zirconium 18 Any Alloy Rod Fuel Rods Removed 10 Corner4 Variable Enrichment6 72 Any Variable Enrichment and Axial Blanket 6 68 Any Burnable Poison Rod Replaced by Hollow Zirconium Alloy 80 Corner4 Rod Damaged Fuel in MAINE YANKEE FUEL CAN 12 Corner4 Burnup between 45,000 and 50,000 MWD/MTU 90 Periphery5 MAINE YANKEE FUEL CAN As Required Corner4 Inserted Start-up Source 4 Corner4 Inserted CEA Finger Tip or ICI String Segment 1 Corner4
6.
: 1. All spent fuel, including that held in a Maine Yankee fuel can, must conform to the loading limits presented in Tables B2-8 and B2-9 for cool time.
Variably enriched fuel assemblies have a maximum burnup of less than 30,000 MWD/MTU and enrichments greater than 1.9 wt %. The minimum required cool time for these assemblies is 5 years.
: 2. The number of fuel assemblies in some categories may vary dep ending on future fuel inspections.
Renewed Amendment No. 4  
: 3. Includes these site specific spent fuel configurations and standard fuel assemblies. Standard fuel assemblies may be loaded in any canister p osition.
: 4. Basket corner positions are positions 3, 6, 19, and 22 in Figure B2-1. Corner positions are also periphery positions.
: 5. Basket periphery positions are positions 1, 2, 3, 6, 7, 12, 13, 18, 19, 22, 23, and 24 in Figure B2-1. Periphery positions include the corner p ositions.
: 6. Variably enriched fuel assemblies have a maximum burnup of less than 30,000 MWD/ MTU and enrichments greater than 1.9 wt %. The minimum required cool time for these assemblies is 5 years.
 
Certificate of Compliance B2-12 Renewed Amendment No. 4 Approved Contents B 2.0
 
Table B2-7 Maine Yankee Site Specific Fuel Limits
 
A. Allowable Contents
: 1. Combustion Engineering 14 x 14 PWR INTACT FUEL ASSEMBLIES meeting the specifications presented in Tables B2-1, B2-2 and B2-4.
: 2. PWR INTACT FUEL ASSEMBLIES may contain inserted Control Element Assemblies (CEA), In-Core Instrument (ICI) Thimbles or Flow Mixers. CEAs or Flow Mixers may not be inserted in damaged fuel assemblies, consolidated fuel assemblies or assemblies with irradiated stainless steel replacement rods. Fuel assemblies with a CEA or Flow Mixe r inserted must be loaded in a Clas s 2 CANISTER and cannot be loaded in a Class 1 CANISTER. Fuel assemblies without an inserted CEA or CEA Plug, including those with inserted ICI Thimbles, must be loaded in a Class 1 CANISTER.
: 3. PWR INTACT FUEL ASSEMBLIES with fuel rods replaced with stainless steel or zirconium alloy rods or with uranium oxide rods nominally enriched up to 1.95 wt %.
: 4. PWR INTACT FUEL ASSEMBLIES with fuel rods having variable enrichments with a maximum fuel rod enrichment up to 4.21 wt % 235U and that also have a maximum pl anar average enrichment up to 3.99 wt % 235U.
: 5. PWR INTACT FUEL ASSEMBLIES with annular axial end blankets. The axial end blanket enrichment may be up to 2.6 wt % 235U.
: 6. PWR INTACT FUEL ASSEMBLIES with solid filler rods or burnable poison rods occupying up to 16 of 176 fuel rod positions.
: 7. PWR INTACT FUEL ASSEMBLIES with one or more grid spacers missing or damaged such that the unsupported length of the fuel rods does not exceed 60 inches or with end fitting damage, including damaged or missing hold-down springs, as long as the assembly can be handled safely by normal means.


Approved Contents B 2.0 Certificate of Compliance B2-13 Table B2-7 Maine Yankee Site Specific Fuel Limits A. Allowable Contents 1.
Combustion Engineering 14 x 14 PWR INTACT FUEL ASSEMBLIES meeting the specifications presented in Tables B2-1, B2-2 and B2-4.
2.
PWR INTACT FUEL ASSEMBLIES may contain inserted Control Element Assemblies (CEA), In-Core Instrument (ICI) Thimbles or Flow Mixers. CEAs or Flow Mixers may not be inserted in damaged fuel assemblies, consolidated fuel assemblies or assemblies with irradiated stainless steel replacement rods. Fuel assemblies with a CEA or Flow Mixer inserted must be loaded in a Class 2 CANISTER and cannot be loaded in a Class 1 CANISTER. Fuel assemblies without an inserted CEA or CEA Plug, including those with inserted ICI Thimbles, must be loaded in a Class 1 CANISTER.
3.
PWR INTACT FUEL ASSEMBLIES with fuel rods replaced with stainless steel or zirconium alloy rods or with uranium oxide rods nominally enriched up to 1.95 wt %.
4.
PWR INTACT FUEL ASSEMBLIES with fuel rods having variable enrichments with a maximum fuel rod enrichment up to 4.21 wt % 235U and that also have a maximum planar average enrichment up to 3.99 wt % 235U.
5.
PWR INTACT FUEL ASSEMBLIES with annular axial end blankets. The axial end blanket enrichment may be up to 2.6 wt % 235U.
6.
PWR INTACT FUEL ASSEMBLIES with solid filler rods or burnable poison rods occupying up to 16 of 176 fuel rod positions.
7.
PWR INTACT FUEL ASSEMBLIES with one or more grid spacers missing or damaged such that the unsupported length of the fuel rods does not exceed 60 inches or with end fitting damage, including damaged or missing hold-down springs, as long as the assembly can be handled safely by normal means.
B. Allowable Contents requiring preferential loading based on shielding, criticality or thermal constraints. The preferential loading requirement for these fuel configurations is as described in Table B2-6.
B. Allowable Contents requiring preferential loading based on shielding, criticality or thermal constraints. The preferential loading requirement for these fuel configurations is as described in Table B2-6.
: 1. PWR INTACT FUEL ASSEMBLIES with up to 176 fuel rods missing from the fuel assembly lattice.
1.
: 2. PWR INTACT FUEL ASSEMBLIES with a burnup between 45,000 and 50,000 MWD/MTU that must be loaded in accordance with Tables B 2-6 and B2-8.
PWR INTACT FUEL ASSEMBLIES with up to 176 fuel rods missing from the fuel assembly lattice.
: 3. PWR INTACT FUEL ASSEMBLIES with a burnable poison rod replaced by a hollow zirconium alloy rod.
2.
PWR INTACT FUEL ASSEMBLIES with a burnup between 45,000 and 50,000 MWD/MTU that must be loaded in accordance with Tables B2-6 and B2-8.
3.
PWR INTACT FUEL ASSEMBLIES with a burnable poison rod replaced by a hollow zirconium alloy rod.
Renewed Amendment No. 4


Certificate of Compliance B2-13 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance B2-14 Table B2-7 Maine Yankee Site Specific Fuel Limits (continued) 4.
 
INTACT FUEL ASSEMBLIES with a start-up source in a center guide tube. The assembly must be loaded in a basket corner position and must be loaded in a Class 1 CANISTER. Only one (1) start-up source may be loaded in any fuel assembly or any CANISTER.
Table B2-7 Maine Yankee Site Specific Fuel Limits (continued)
5.
: 4. INTACT FUEL ASSEMBLIES with a start-up source in a center guide tube. The assembly must be loaded in a basket corner position and must be loaded in a Class 1 CANISTER. Only one (1) start-up source may be loaded in any fuel assembly or any CANISTER.
PWR INTACT FUEL ASSEMBLIES with CEA ends (finger tips) and/or ICI segment inserted in corner guide tube positions. The assembly must also have a CEA plug installed. The assembly must be loaded in a basket corner position and must be loaded in a Class 2 CANISTER.
: 5. PWR INTACT FUEL ASSEMBLIES with CEA ends (finger tips) and/or ICI segment inserted in corner guide tube positions. The assembly must also have a CEA plug installed. The assembly must be loaded in a basket corner position and must be loaded in a Class 2 CANISTER.
6.
: 6. INTACT FUEL ASSEMBLIES may be loaded in a MAINE YANKEE FUEL CAN.
INTACT FUEL ASSEMBLIES may be loaded in a MAINE YANKEE FUEL CAN.
: 7. FUEL enclosed in a MAINE YANKEE FUEL CAN. The MAINE YANKEE FUEL CAN can only be loaded in a Class 1 CANISTER. The contents that must be loaded in the MAIN E YANKEE FUEL CAN are:
7.
FUEL enclosed in a MAINE YANKEE FUEL CAN. The MAINE YANKEE FUEL CAN can only be loaded in a Class 1 CANISTER. The contents that must be loaded in the MAINE YANKEE FUEL CAN are:
a) PWR fuel assemblies with up to two INTACT or DAMAGED FUEL rods inserted in each fuel assembly guide tube or with up to two burnable poison rods inserted in each guide tube. The rods inserted in the guide tubes cannot be from a different fuel assembly. The maximum number of rods in the fuel assembly (fuel rods plus inserted rods, including burnable poison rods) is 176.
a) PWR fuel assemblies with up to two INTACT or DAMAGED FUEL rods inserted in each fuel assembly guide tube or with up to two burnable poison rods inserted in each guide tube. The rods inserted in the guide tubes cannot be from a different fuel assembly. The maximum number of rods in the fuel assembly (fuel rods plus inserted rods, including burnable poison rods) is 176.
b) A DAMAGED FUEL ASSEMBLY with up to 100% of the fuel rods classified as damaged and/or damaged or missing assembly hardware components. A DAMAGED FUEL ASSEMBLY cannot have an inserted CEA or other non-fuel component.
b) A DAMAGED FUEL ASSEMBLY with up to 100% of the fuel rods classified as damaged and/or damaged or missing assembly hardware components. A DAMAGED FUEL ASSEMBLY cannot have an inserted CEA or other non-fuel component.
c) Individual INTACT or DAMAGED FUEL rods in a rod type structure, which may be a guide tube, to maintain configuration control.
c)
Individual INTACT or DAMAGED FUEL rods in a rod type structure, which may be a guide tube, to maintain configuration control.
d) FUEL DEBRIS consisting of fuel rods with exposed fuel pellets or individual intact or partial fuel pellets not contained in fuel rods.
d) FUEL DEBRIS consisting of fuel rods with exposed fuel pellets or individual intact or partial fuel pellets not contained in fuel rods.
Renewed Amendment No. 4


Certificate of Compliance B2-14 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-15 Table B2-7 Maine Yankee Site Specific Fuel Limits (continued) e) CONSOLIDATED FUEL lattice structure with a 17 x 17 array formed by grids and top and bottom end fittings connected by four solid stainless steel rods. Maximum contents are 289 fuel rods having a total lattice weight 2,100 pounds. A CONSOLIDATED FUEL lattice cannot have an inserted CEA or other non-fuel component. Only one CONSOLIDATED FUEL lattice may be stored in any CANISTER.
 
C. Unenriched fuel assemblies are not authorized for loading.
Table B2-7 Maine Yankee Site Specific Fuel Limits (continued)
D. A canister preferentially loaded in accordance with Table B2-8 may only contain fuel assemblies selected from the same loading pattern.
 
Renewed Amendment No. 4
e) CONSOLIDATED FUEL lattice structure with a 17 x 17 array formed by grids and to p and bottom end fittings connected by four solid stainless steel rods. Maximum contents are 289 fuel rods having a total lattice weight 2,100 pounds. A CONSOLIDATED FUEL lattice cannot have an inserted CEA or other non-fuel component. Only one CONSOLIDATED FUEL lattice may be stored in any CANISTER.


C. Unenriched fuel assemblies are not authorized f or loading.
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-16 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material -
Required Cool Time in Years Before Assembly is Acceptable Burnup 30 GWD/MTU - Minimum Cool Time [years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 5
5 5
2.1 E < 2.3 5
5 5
2.3 E < 2.5 5
5 5
2.5 E < 2.7 5
5 5
2.7 E < 2.9 5
5 5
2.9 E < 3.1 5
5 5
3.1 E < 3.3 5
5 5
3.3 E < 3.5 5
5 5
3.5 E < 3.7 5
5 5
3.7 E 4.2 5
5 5
30 < Burnup 35 GWD/MTU - Minimum Cool Time
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 5
5 5
2.1 E < 2.3 5
5 5
2.3 E < 2.5 5
5 5
2.5 E < 2.7 5
5 5
2.7 E < 2.9 5
5 5
2.9 E < 3.1 5
5 5
3.1 E < 3.3 5
5 5
3.3 E < 3.5 5
5 5
3.5 E < 3.7 5
5 5
3.7 E 4.2 5
5 5
35 < Burnup 40 GWD/MTU - Minimum Cool Time
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 7
7 5
2.1 E < 2.3 6
6 5
2.3 E < 2.5 6
6 5
2.5 E < 2.7 5
6 5
2.7 E < 2.9 5
6 5
2.9 E < 3.1 5
6 5
3.1 E < 3.3 5
6 5
3.3 E < 3.5 5
6 5
3.5 E < 3.7 5
6 5
3.7 E 4.2 5
6 5
1.
Standard loading pattern: allowable decay heat = 0.958 kW per assembly 2.
Preferential loading pattern, interior basket locations: allowable heat decay
.867 kW per assembly 3.
Preferential loading pattern, periphery basket locations: allowable heat decay = 1.05 kW per assembly Renewed Amendment No. 4


D. A canister preferentially loaded in accordance with Table B2-8 may only contain fuel assemblies selected from the same loading patt ern.
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-17 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material -
Required Cool Time in Years Before Assembly is Acceptable (Continued) 40 < Burnup 45 GWD/MTU - Minimum Cool Time
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 11 11 6
2.1 E < 2.3 9
9 6
2.3 E < 2.5 8
8 6
2.5 E < 2.7 7
7 6
2.7 E < 2.9 7
7 6
2.9 E < 3.1 6
7 6
3.1 E < 3.3 6
7 5
3.3 E < 3.5 6
7 5
3.5 E < 3.7 6
7 5
3.7 E 4.2 6
7 5
45 < Burnup 50 GWD/MTU - Minimum Cool Time
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 Not allowed Not allowed 7
2.1 E < 2.3 Not allowed Not allowed 7
2.3 E < 2.5 Not allowed Not allowed 7
2.5 E < 2.7 Not allowed Not allowed 7
2.7 E < 2.9 Not allowed Not allowed 7
2.9 E < 3.1 Not allowed Not allowed 7
3.1 E < 3.3 Not allowed Not allowed 7
3.3 E < 3.5 Not allowed Not allowed 6
3.5 E < 3.7 Not allowed Not allowed 6
3.7 E 4.2 Not allowed Not allowed 6
1.
Standard loading pattern: allowable decay heat = 0.958 kW per assembly 2.
Preferential loading pattern, interior basket locations: allowable heat decay = 0.867 kW per assembly 3.
Preferential loading pattern, periphery basket locations: allowable heat decay = 1.05 kW per assembly Renewed Amendment No. 4


Certificate of Compliance No. 1015 B2-15 Renewed Amendment No. 4 Approved Contents B 2.0
Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-18 Table B2-9 Loading Table for Maine Yankee CE 14 x 14 Fuel Containing CEA Cooled to Indicated Time 30 GWD/MTU Burnup - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 5
5 5
5 5
2.1 E < 2.3 5
5 5
5 5
2.3 E < 2.5 5
5 5
5 5
2.5 E < 2.7 5
5 5
5 5
2.7 E < 2.9 5
5 5
5 5
2.9 E < 3.1 5
5 5
5 5
3.1 E < 3.3 5
5 5
5 5
3.3 E < 3.5 5
5 5
5 5
3.5 E < 3.7 5
5 5
5 5
3.7 E 4.2 5
5 5
5 5
30 < Burnup 35 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 5
5 5
5 5
2.1 E < 2.3 5
5 5
5 5
2.3 E < 2.5 5
5 5
5 5
2.5 E < 2.7 5
5 5
5 5
2.7 E < 2.9 5
5 5
5 5
2.9 E < 3.1 5
5 5
5 5
3.1 E < 3.3 5
5 5
5 5
3.3 E < 3.5 5
5 5
5 5
3.5 E < 3.7 5
5 5
5 5
3.7 E 4.2 5
5 5
5 5
35 < Burnup 40 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 7
7 7
7 7
2.1 E < 2.3 6
6 6
6 6
2.3 E < 2.5 6
6 6
6 6
2.5 E < 2.7 5
6 5
5 5
2.7 E < 2.9 5
6 5
5 5
2.9 E < 3.1 5
6 5
5 5
3.1 E < 3.3 5
5 5
5 5
3.3 E < 3.5 5
5 5
5 5
3.5 E < 3.7 5
5 5
5 5
3.7 E 4.2 5
5 5
5 5
40 < Burnup 45 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 11 11 11 11 11 2.1 E < 2.3 9
9 9
9 9
2.3 E < 2.5 8
8 8
8 8
2.5 E < 2.7 7
7 7
7 7
2.7 E < 2.9 7
7 7
7 7
2.9 E < 3.1 6
6 6
6 6
3.1 E < 3.3 6
6 6
6 6
3.3 E < 3.5 6
6 6
6 6
3.5 E < 3.7 6
6 6
6 6
3.7 E 4.2 6
6 6
6 6
Renewed Amendment No. 4  


Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material -
Design Features B 3.0 Certificate of Compliance No. 1015 B3-1 B 3.0 DESIGN FEATURES B 3.1 Site B 3.1.1 Site Location The NAC-UMS SYSTEM is authorized for general use by 10 CFR 50 license holders at various site locations under the provisions of 10 CFR 72, Subpart K.
Required Cool Time in Years Before Assembly is Acceptable Burnup 30 GWD/MTU - Minimum Cool Time [years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 5 5 5 2.1 E < 2.3 5 5 5 2.3 E < 2.5 5 5 5 2.5 E < 2.7 5 5 5 2.7 E < 2.9 5 5 5 2.9 E < 3.1 5 5 5 3.1 E < 3.3 5 5 5 3.3 E < 3.5 5 5 5 3.5 E < 3.7 5 5 5 3.7 E 4.2 5 5 5 30 < Burnup 35 GWD/MTU - Minimum Cool Time
B 3.2 Design Features Important for Criticality Control B 3.2.1 CANISTER-INTACT FUEL ASSEMBLIES a)
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 5 5 5 2.1 E < 2.3 5 5 5 2.3 E < 2.5 5 5 5 2.5 E < 2.7 5 5 5 2.7 E < 2.9 5 5 5 2.9 E < 3.1 5 5 5 3.1 E < 3.3 5 5 5 3.3 E < 3.5 5 5 5 3.5 E < 3.7 5 5 5 3.7 E 4.2 5 5 5 35 < Burnup 40 GWD/MTU - Minimum Cool Time
Minimum 10B loading in the neutron absorbers:
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 7 7 5 2.1 E < 2.3 6 6 5 2.3 E < 2.5 6 6 5 2.5 E < 2.7 5 6 5 2.7 E < 2.9 5 6 5 2.9 E < 3.1 5 6 5 3.1 E < 3.3 5 6 5 3.3 E < 3.5 5 6 5 3.5 E < 3.7 5 6 5 3.7 E 4.2 5 6 5
1.
: 1. Standard loading pattern: allowable decay heat = 0.958 kW per assembly
PWR - 0.025g/cm2 2.
: 2. Preferential loading pattern, interior basket locations: allowable heat decay
BWR - 0.011g/cm2 b)
.867 kW per assembly
Minimum length of INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure the minimum distance to the fuel region from the base of the CANISTER is:
: 3. Preferential loading pattern, periphery basket locations: allowable heat decay = 1.05 kW per assembly
1.
 
PWR - 3.2 inches 2.
Certificate of Compliance No. 1015 B2-16 Renewed Amendment No. 4 Approved Contents B 2.0
BWR - 6.2 inches c)
 
Soluble boron concentration in the PWR fuel pool and CANISTER water:
Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material -
Required Cool Time in Years Before Assembly is Acceptable (Continued)
 
40 < Burnup 45 GWD/MTU - Minimum Cool Time
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 11 11 6 2.1 E < 2.3 9 9 6 2.3 E < 2.5 8 8 6 2.5 E < 2.7 7 7 6 2.7 E < 2.9 7 7 6 2.9 E < 3.1 6 7 6 3.1 E < 3.3 6 7 5 3.3 E < 3.5 6 7 5 3.5 E < 3.7 6 7 5 3.7 E 4.2 6 7 5 45 < Burnup 50 GWD/MTU - Minimum Cool Time
[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 Not allowed Not allowed 7 2.1 E < 2.3 Not allowed Not allowed 7 2.3 E < 2.5 Not allowed Not allowed 7 2.5 E < 2.7 Not allowed Not allowed 7 2.7 E < 2.9 Not allowed Not allowed 7 2.9 E < 3.1 Not allowed Not allowed 7 3.1 E < 3.3 Not allowed Not allowed 7 3.3 E < 3.5 Not allowed Not allowed 6 3.5 E < 3.7 Not allowed Not allowed 6 3.7 E 4.2 Not allowed Not allowed 6
: 1. Standard loading pattern: allowable decay heat = 0.958 kW per assembly
: 2. Preferential loading pattern, interior basket loca tions: allowable heat decay = 0.867 kW per assembly
: 3. Preferential loading pattern, periphery basket locations: al lowable heat decay = 1.05 kW per assembly
 
Certificate of Compliance No. 1015 B2-17 Renewed Amendment No. 4 Approved Contents B 2.0
 
Table B2-9 Loading Table for Maine Yankee CE 14 x 14 Fuel Containing CEA Cooled to Indicated Time 30 GWD/MTU Burnup - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 5 5 5 5 5 2.1 E < 2.3 5 5 5 5 5 2.3 E < 2.5 5 5 5 5 5 2.5 E < 2.7 5 5 5 5 5 2.7 E < 2.9 5 5 5 5 5 2.9 E < 3.1 5 5 5 5 5 3.1 E < 3.3 5 5 5 5 5 3.3 E < 3.5 5 5 5 5 5 3.5 E < 3.7 5 5 5 5 5 3.7 E 4.2 5 5 5 5 5 30 < Burnup 35 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 5 5 5 5 5 2.1 E < 2.3 5 5 5 5 5 2.3 E < 2.5 5 5 5 5 5 2.5 E < 2.7 5 5 5 5 5 2.7 E < 2.9 5 5 5 5 5 2.9 E < 3.1 5 5 5 5 5 3.1 E < 3.3 5 5 5 5 5 3.3 E < 3.5 5 5 5 5 5 3.5 E < 3.7 5 5 5 5 5 3.7 E 4.2 5 5 5 5 5 35 < Burnup 40 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 7 7 7 7 7 2.1 E < 2.3 6 6 6 6 6 2.3 E < 2.5 6 6 6 6 6 2.5 E < 2.7 5 6 5 5 5 2.7 E < 2.9 5 6 5 5 5 2.9 E < 3.1 5 6 5 5 5 3.1 E < 3.3 5 5 5 5 5 3.3 E < 3.5 5 5 5 5 5 3.5 E < 3.7 5 5 5 5 5 3.7 E 4.2 5 5 5 5 5 40 < Burnup 45 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 11 11 11 11 11 2.1 E < 2.3 9 9 9 9 9 2.3 E < 2.5 8 8 8 8 8 2.5 E < 2.7 7 7 7 7 7 2.7 E < 2.9 7 7 7 7 7 2.9 E < 3.1 6 6 6 6 6 3.1 E < 3.3 6 6 6 6 6 3.3 E < 3.5 6 6 6 6 6 3.5 E < 3.7 6 6 6 6 6 3.7 E 4.2 6 6 6 6 6
 
Certificate of Compliance No. 1015 B2-18 Renewed Amendment No. 4 Design Features B 3.0
 
B 3.0 DESIGN FEATURES
 
B 3.1 Site B 3.1.1 Site Location The NAC-UMS SYSTEM is authorized for general use by 10 CFR 50 license holders at various site locations under the provisions of 10 CFR 72, Subpart K.
 
B 3.2 Design Features Important for Criticality Control B 3.2.1 CANISTER-INTACT FUEL ASSEMBLIES a) Minimum 10B loading in the neutron absorbers:
: 1. PWR - 0.025g/cm2
: 2. BWR - 0.011g/cm2 b) Minimum length of INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure the minimu m distance to the fuel region from the base of the CANISTER is:
: 1. PWR - 3.2 inches
: 2. BWR - 6.2 inches c) Soluble boron concentration in the PWR fuel pool and CANISTER water:
: 1. Fuel meeting the enrichment limits in Table B2-2 without boron - 0 ppm.
: 1. Fuel meeting the enrichment limits in Table B2-2 without boron - 0 ppm.
: 2. Fuel meeting the enrichment limits in Table B 2-2 with boron 1000 ppm.
: 2. Fuel meeting the enrichment limits in Table B2-2 with boron 1000 ppm.
d) Minimum water temperature for PWR fuel to ensure boron is solubl e:
d) Minimum water temperature for PWR fuel to ensure boron is soluble:
: 1. Temperature should be 5 - 10 oF higher than the minimum needed to ensure solubility.
1.
 
Temperature should be 5 - 10oF higher than the minimum needed to ensure solubility.
B 3.3 Codes and Standards The American Society of Mechanical Engineers Boiler and Pressure Vessel Code (ASME Code), 1995 Edition with Addenda through 1995, is the governing Code for the NAC-UMS CANISTER.
B 3.3 Codes and Standards The American Society of Mechanical Engineers Boiler and Pressure Vessel Code (ASME Code), 1995 Edition with Addenda through 1995, is the governing Code for the NAC-UMS CANISTER.
The American Concrete Institute Specifications ACI-349 (1985) and ACI-318 (1995) govern the NAC-UMS CONCRETE CASK design and construction, respectively.
The American Concrete Institute Specifications ACI-349 (1985) and ACI-318 (1995) govern the NAC-UMS CONCRETE CASK design and construction, respectively.
 
The American National Standards Institute ANSI N14.6 (1993) and NUREG-0612 govern the NAC-UMS TRANSFER CASK design, operation, fabrication, testing, inspection and maintenance.
The American National Stand ards Institute ANSI N14. 6 (1993) and NUREG-0612 govern the NAC-UMS TRANSFER CASK design, operation, fabrication, testing, inspection and maintenance.
 
(continued)
(continued)
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-1 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-2 B 3.3.1 Exceptions to Codes, Standards, and Criteria Table B3-1 lists exceptions to the ASME Code for the design of the NAC-UMS SYSTEM.
 
B 3.3.2 Construction/Fabrication Exceptions to Codes, Standards, and Criteria Proposed alternatives to ASME Code, Section III, 1995 Edition with Addenda, through 1995, including exceptions listed in Specification B3.3.1, may be used when authorized by the Director of the Office of Nuclear Material Safety and Safeguards or designee. The request for such alternatives should demonstrate that:
B 3.3.1 Exceptions to Codes, Standards, and Criteria Table B3-1 lists exceptions to the ASME Code for the design of the NAC-UMS SYSTEM.
: 1. The proposed alternatives would provide an acceptable level of quality and safety, or 2.
 
Compliance with the specified requirements of ASME Code, Section III, 1995 Edition with Addenda through 1995, would result in hardship or unusual difficulty without a compensating increase in the level of quality and safety.
B 3.3.2 Construction/Fabrication Exceptions to Codes, Standards, and Criteria
 
Proposed alternatives to ASME Code, Section III, 1995 Edition with Addenda, through 1995, including exceptions listed in Specification B3.3.1, may be used when authorized by the Director of the Office of Nuclear Material Safety and Safeguards or designee. The request for such alternatives should demonstrate that:
: 1. The proposed alternatives would provide an acceptable level of quality and safety, or
: 2. Compliance with the specified requirements of ASME Cod e, Section III, 1995 Edition with Addenda through 1995, would result in hardship or unusual difficulty without a compensating increase in the level of quality and safety.
 
Requests for exceptions shall be submitted in accordance with 10 CFR 72.4.
Requests for exceptions shall be submitted in accordance with 10 CFR 72.4.
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-2 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-3 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER NB-1100 Statement of requirements for Code stamping of components.
 
CANISTER is designed and will be fabricated in accordance with ASME Code, Section III, Subsection NB to the maximum practical extent, but Code stamping is not required. The completion of an ASME Design Specification, Design Report and Overpressure Protection Report is not required.
Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM
CANISTER NB-2000 Requirements to be supplied by ASME-approved material supplier.
 
Materials will be supplied by NAC-approved suppliers with Certified Material Test Reports (CMTRs) in accordance to NB-2000 requirements.
Component Reference ASME Code Requirement Exception, Justification and Code Compensatory Measures Section/Article CANISTER NB-1100 Statement of CANISTER is designed and will be requirements for Code fabricated in accordance with ASME stamping of Code, Section III, Subsection NB to the components. maximum practical extent, but Code stamping is not required. The completion of an ASME Design Specification, Design Report and Overpressure Protection Report is not required.
CANISTER NB-2500 Repairs to pressure-retaining material from which a defect(s) has been removed are to be examined by magnetic particle or dye penetrant methods. If the depth of the repair exceeds the lesser of 3/8-inch or 10% of the section thickness, examination is to be by radiography.
CANISTER NB-2000 Requirements to be Materials will be supplied by NAC-supplied by ASME-approved suppliers with Certified approved material Material Test Reports (CMTRs) in supplier. accordance to NB-2000 requirements.
In accordance with ASME Code Case N-595-4, a loaded CANISTER shell examination of a weld repair of material within 1/2-inch of a closure weld may be done by progressive magnetic particle or dye penetrant examination methods for each weld layer 1/4-inch and final surface.
CANISTER NB-2500 Repairs to pressure-In accordance with ASME Code Case retaining material from N-595-4, a loaded CANISTER shell which a defect(s) has examination of a weld repair of been removed are to be material within 1/2-inch of a closure examined by magnetic weld may be done by progressive particle or dye penetrant magnetic particle or dye penetrant methods. If the depth of examination methods for each weld the repair exceeds the layer 1/4-inch and fina l surface.
CANISTER Shield Lid and Structural Lid Welds NB-4243 Full penetration welds required for Category C joints (flat head to main shell per NB-3352.3).
lesser of 3/8-inch or 10% of the section thickness, examination is to be by radiography.
Shield lid and structural lid to CANISTER shell welds are not full penetration welds. These field welds are performed independently to provide a redundant closure.
CANISTER NB-4243 Full penetration welds Shield lid and structural lid to Shield Lid required for Category C CANISTER shell welds are not full and joints (flat head to main penetration welds. These field welds Structural Lid shell per NB-3352.3). are performed independently to Welds provide a redundant closure.
Leaktightness of the CANISTER is verified by testing.
Leaktightness of the CANISTER is verified by testing.
CANISTER NB-4421 Requires removal of Structural lid to CANISTER shell weld Structural Lid backing ring. uses a backing ring that is not Weld removed. The backing ring permits completion of the groove weld; it is not considered in any analyses; and it has no detrimental effect on the CANISTERs function.
CANISTER Structural Lid Weld NB-4421 Requires removal of backing ring.
 
Structural lid to CANISTER shell weld uses a backing ring that is not removed. The backing ring permits completion of the groove weld; it is not considered in any analyses; and it has no detrimental effect on the CANISTERs function.
Certificate of Compliance No. 1015 B3-3 Renewed Amendment No. 4 Design Features B 3.0
Renewed Amendment No. 4  
 
Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)


Component Reference ASME Code Requirement Exception, Justification and Code Compensatory Measures Section/Article CANISTER NB-5230 Radiographic (RT) or Root and final surface liquid penetrant Vent Port ultrasonic (UT) examination to be performed per Cover and examination required. ASME Code Section V, Article 6, with Drain Port acceptance in accordance with ASME Cover to Code, Section III, NB-5350.
Design Features B 3.0 Certificate of Compliance No. 1015 B3-4 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)
Shield Lid Welds; Shield Lid to Canister Shell Weld CANISTER NB-5230 Radiographic (RT) or The CANISTER structural lid to Structural Lid ultrasonic (UT) CANISTER shell closure weld is to Shell Weld examination required. performed in the field following fuel assembly loading. The structural lid-to-shell weld will be verified by either ultrasonic (UT) or progressive liquid penetrant (PT) examination. If progressive PT examination is used, at a minimum, it must include the root and final layers and each approximately 3/8 inch of weld depth.
Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER Vent Port Cover and Drain Port Cover to Shield Lid Welds; Shield Lid to Canister Shell Weld NB-5230 Radiographic (RT) or ultrasonic (UT) examination required.
Root and final surface liquid penetrant examination to be performed per ASME Code Section V, Article 6, with acceptance in accordance with ASME Code, Section III, NB-5350.
CANISTER Structural Lid to Shell Weld NB-5230 Radiographic (RT) or ultrasonic (UT) examination required.
The CANISTER structural lid to CANISTER shell closure weld is performed in the field following fuel assembly loading. The structural lid-to-shell weld will be verified by either ultrasonic (UT) or progressive liquid penetrant (PT) examination. If progressive PT examination is used, at a minimum, it must include the root and final layers and each approximately 3/8 inch of weld depth.
If UT examination is used, it will be followed by a final surface PT examination. For either UT or PT examination, the maximum, undetectable flaw size is demonstrated to be smaller than the critical flaw size.
If UT examination is used, it will be followed by a final surface PT examination. For either UT or PT examination, the maximum, undetectable flaw size is demonstrated to be smaller than the critical flaw size.
The critical flaw size is determined in accordance with ASME Code, Section XI methods. The examination of the weld will be performed by qualified personnel per ASME Code Section V, Articles 5 (UT) and 6 (PT) with acceptance per ASME Code Section III, NB-5332 (UT) per 1995 Addenda, and NB-5350 for (PT).
The critical flaw size is determined in accordance with ASME Code, Section XI methods. The examination of the weld will be performed by qualified personnel per ASME Code Section V, Articles 5 (UT) and 6 (PT) with acceptance per ASME Code Section III, NB-5332 (UT) per 1995 Addenda, and NB-5350 for (PT).
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-4 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-5 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)
 
Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER Vessel and Shield Lid NB-6111 All completed pressure retaining systems shall be pressure tested.
Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)
The CANISTER shield lid to shell weld is performed in the field following fuel assembly loading. The CANISTER is then pneumatically (air/nitrogen/
 
Component Reference ASME Code Requirement Exception, Justification and Code Compensatory Measures Section/Article CANISTER NB-6111 All completed pressure The CANISTER shield lid to shell weld Vessel and retaining systems shall is performed in the field following fuel Shield Lid be pressure tested. assembly loading. The CANISTER is then pneumatically (air/nitrogen/
helium-over-water) pressure tested as defined in Chapter 9 and described in Chapter 8. Accessibility for leakage inspections precludes a Code compliant hydrostatic test. The shield lid-to-shell weld is also leak tested to the leak-tight criteria of ANSI N14.5.
helium-over-water) pressure tested as defined in Chapter 9 and described in Chapter 8. Accessibility for leakage inspections precludes a Code compliant hydrostatic test. The shield lid-to-shell weld is also leak tested to the leak-tight criteria of ANSI N14.5.
The vent port and drain port cover welds are examined by root and final PT examination. The structural lid enclosure weld is examined by progressive PT or UT and final surface PT.
The vent port and drain port cover welds are examined by root and final PT examination. The structural lid enclosure weld is examined by progressive PT or UT and final surface PT.
CANISTER NB-7000 Vessels are required to No overpressure protection is Vessel have overpressure provided. The function of the protection. CANISTER is to confine radioactive contents under normal, off-normal, and accident conditions of storage. The CANISTER vessel is designed to withstand a maximum internal pressure considering 100% fuel rod failure and maximum accident temperatures.
CANISTER Vessel NB-7000 Vessels are required to have overpressure protection.
CANISTER NB-8000 States requirements for The NAC-UMS SYSTEM is marked Vessel nameplates, stamping and identified in accordance with 10 and reports per NCA-CFR 72 requirements. Code stamping 8000. is not required. The QA data package will be in accordance with NACs approved QA program. The completion of an ASME Design Specification, Design Report and Overpressure Protection Report is not required.
No overpressure protection is provided. The function of the CANISTER is to confine radioactive contents under normal, off-normal, and accident conditions of storage. The CANISTER vessel is designed to withstand a maximum internal pressure considering 100% fuel rod failure and maximum accident temperatures.
 
CANISTER Vessel NB-8000 States requirements for nameplates, stamping and reports per NCA-8000.
Certificate of Compliance No. 1015 B3-5 Renewed Amendment No. 4 Design Features B 3.0
The NAC-UMS SYSTEM is marked and identified in accordance with 10 CFR 72 requirements. Code stamping is not required. The QA data package will be in accordance with NACs approved QA program. The completion of an ASME Design Specification, Design Report and Overpressure Protection Report is not required.
 
Renewed Amendment No. 4  
Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)


Component Reference ASME Code Requirement Exception, Justification and Code Compensatory Measures Section/Article CANISTER NG-2000 Requires materials to Materials to be supplied by NAC-Basket be supplied by ASME approved suppliers with CMTRs in Assembly approved material accordance with NG-2000 supplier. requirements.
Design Features B 3.0 Certificate of Compliance No. 1015 B3-6 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)
CANISTER NG-8000 States requirements for The NAC-UMS SYSTEM will be Basket nameplates, stamping marked and identified in accordance Assembly and reports per NCA-with 10 CFR 72 requirements. No 8000. Code stamping is required. The CANISTER basket data package will be in accordance with NACs approved QA program.
Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER Basket Assembly NG-2000 Requires materials to be supplied by ASME approved material supplier.
CANISTER NB-2130/ NG-2130 States requirements for The NAC-UMS CANISTER and Vessel and certification of material Basket Assembly component materials Basket organizations and are procured in accordance with the Assembly materials to NCA-3861 specifications for materials in ASME Material and NCA-3862, Code Section II with Certified Material respectively. Test Reports. The component materials will be obtained from NAC approved Suppliers in accordance with NACs approved QA program.
Materials to be supplied by NAC-approved suppliers with CMTRs in accordance with NG-2000 requirements.
 
CANISTER Basket Assembly NG-8000 States requirements for nameplates, stamping and reports per NCA-8000.
Certificate of Compliance No. 1015 B3-6 Renewed Amendment No. 4 Design Features B 3.0
The NAC-UMS SYSTEM will be marked and identified in accordance with 10 CFR 72 requirements. No Code stamping is required. The CANISTER basket data package will be in accordance with NACs approved QA program.
 
CANISTER Vessel and Basket Assembly Material NB-2130/ NG-2130 States requirements for certification of material organizations and materials to NCA-3861 and NCA-3862, respectively.
B 3.4 Site Specific Parameters and Analyses This section presents site-specific parameters and analytical bases that must be verified by the NAC-UMS SYSTEM user. The parameters and bases presented in Section B.3.4.1 are those applied in the design basis analysis. The parameters and bases us ed in the evaluation of SITE SPECIFIC FUEL are presented in the appropriate sections below.
The NAC-UMS CANISTER and Basket Assembly component materials are procured in accordance with the specifications for materials in ASME Code Section II with Certified Material Test Reports. The component materials will be obtained from NAC approved Suppliers in accordance with NACs approved QA program.
 
Renewed Amendment No. 4  
B 3.4.1 Design Basis Site Specific Parameters and Analyses
 
The design basis site-specific parameters and analyses that require verification by the NAC-UMS SYSTEM user are:
: 1. The temperature of 76&deg; F is the maximum average yearly temperature. The 3-day average ambient temperature shall be 106 &deg;F or less.
: 2. The allowed temperature extremes, averaged over a 3-day period, shall be greater than -40&deg;F and less than 13 3&deg; F.
: 3. a) The design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad or at the center of gravity of the loaded concrete cask on the ISFSI pad are bounded by the values shown:
 
Horizontal g-level in each of Two Coefficient Orthogonal Corresponding Configuration of Friction Directions Vertical g-level Standard 0.35 0.26g 0.26g Standard 0.40 0.29g 0.29g Note: For site conditions that are not bounded by the above values, site-specific analysis may be performed in accordance with B 3.4.1(3)(b).
 
b) Alternatively, the design basis earthquake motion of the ISFSI pad may be limited so that the acceleration g-load resulting from the collision of two sliding casks remains bounded by the accident condition analyses present ed in Chapter 11 of the FSAR.


Design Features B 3.0 Certificate of Compliance No. 1015 B3-7 B 3.4 Site Specific Parameters and Analyses This section presents site-specific parameters and analytical bases that must be verified by the NAC-UMS SYSTEM user. The parameters and bases presented in Section B.3.4.1 are those applied in the design basis analysis. The parameters and bases used in the evaluation of SITE SPECIFIC FUEL are presented in the appropriate sections below.
B 3.4.1 Design Basis Site Specific Parameters and Analyses The design basis site-specific parameters and analyses that require verification by the NAC-UMS SYSTEM user are:
1.
The temperature of 76&deg;F is the maximum average yearly temperature. The 3-day average ambient temperature shall be 106&deg;F or less.
2.
The allowed temperature extremes, averaged over a 3-day period, shall be greater than -40&deg;F and less than 133&deg;F.
3.
a)
The design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad or at the center of gravity of the loaded concrete cask on the ISFSI pad are bounded by the values shown:
Configuration Coefficient of Friction Horizontal g-level in each of Two Orthogonal Directions Corresponding Vertical g-level Standard 0.35 0.26g 0.26g Standard 0.40 0.29g 0.29g Note: For site conditions that are not bounded by the above values, site-specific analysis may be performed in accordance with B 3.4.1(3)(b).
b)
Alternatively, the design basis earthquake motion of the ISFSI pad may be limited so that the acceleration g-load resulting from the collision of two sliding casks remains bounded by the accident condition analyses presented in Chapter 11 of the FSAR.
Site-specific analysis by the cask user shall demonstrate that a cask does not slide off the ISFSI pad.
Site-specific analysis by the cask user shall demonstrate that a cask does not slide off the ISFSI pad.
(continued)
(continued)
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-7 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-8 B 3.4.1 Design Basis Site Specific Parameters and Analyses (continued) 4.
 
The analyzed flood condition of 15 fps water velocity and a height of 50 feet of water (full submergence of the loaded cask) are not exceeded.
B 3.4.1 Design Basis Site Specific Parameters and Analyses (continued)
5.
: 4. The analyzed flood condition of 15 fps water velocity and a height of 50 feet of water (full submergence of the loade d cask) are not exceeded.
The potential for fire and explosion shall be addressed, based on site-specific considerations. This includes the condition that the fuel tank of the cask handling equipment used to move the loaded CONCRETE CASK onto or from the ISFSI site contains no more than 50 gallons of fuel.
: 5. The potential for fire and explosion shall be add ressed, based on site-specific considerations. This includes the condition that the fuel tank of the cask handling equipment used to mo ve the loaded CONCRETE CASK onto or from the ISFSI site contains no more than 50 gallons of fuel.
 
6 In cases where engineered features (i.e., berms, shield walls) are used to ensure that requirements of 10 CFR 72.104(a) are met, such features are to be considered important to safety and must be evaluated to determine the applicable Quality Assurance Category on a site specific basis.
6 In cases where engineered features (i.e., berms, shield walls) are used to ensure that requirements of 10 CFR 72.104(a) are met, such features are to be considered important to safety and must be evaluated to determine the applicable Quality Assurance Category on a site specific basis.
: 7. TRANSFER CASK OPERATIONS shall only be conducted with surrounding air temperatures 0&deg;F.
7.
: 8. The VERTICAL CONCRETE CASK shall only be lifted by the lifting lugs with surrounding air temperatures 0&deg;F.
TRANSFER CASK OPERATIONS shall only be conducted with surrounding air temperatures 0&deg;F.
 
8.
Certificate of Compliance No. 1015 B3-8 Renewed Amendment No. 4 Design Features B 3.0
The VERTICAL CONCRETE CASK shall only be lifted by the lifting lugs with surrounding air temperatures 0&deg;F.
 
Renewed Amendment No. 4  
B 3.4.2 Maine Yankee Site Specific Parameters and Analyses
 
The design basis site-specific parameters and analyses that require verification by Maine Yankee are:
: 1. The temperature of 76 &deg;F is the maximum average yearly temperature. The 3-day average ambient temperature shall be 106 &deg;F or less.
: 2. The allowed temperature extremes, averaged over a 3-day period, shall be greater than -40&deg;F and less than 133&deg; F.
: 3. The design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad are bounded by the values shown:


Horizontal g-level Corresponding Coefficient in each of Two Vertical Configuration of Friction Orthogonal Directions1 g-level (upward)
Design Features B 3.0 Certificate of Compliance No. 1015 B3-9 B 3.4.2 Maine Yankee Site Specific Parameters and Analyses The design basis site-specific parameters and analyses that require verification by Maine Yankee are:
1.
The temperature of 76&deg;F is the maximum average yearly temperature. The 3-day average ambient temperature shall be 106&deg;F or less.
2.
The allowed temperature extremes, averaged over a 3-day period, shall be greater than -40&deg;F and less than 133&deg;F.
3.
The design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad are bounded by the values shown:
Configuration Coefficient of Friction Horizontal g-level in each of Two Orthogonal Directions1 Corresponding Vertical g-level (upward)
Maine Yankee 0.50 0.38 0.38 x 0.667 =
Maine Yankee 0.50 0.38 0.38 x 0.667 =
0.253g 1 Earthquake loads are applied to the center of gravity of the concrete cask on the ISFSI pad.
0.253g 1 Earthquake loads are applied to the center of gravity of the concrete cask on the ISFSI pad.
: 4. The analyzed flood condition of 15 fps water velocity and a height of 50 f eet of water (full submergence of the loade d cask) are not exceeded.
4.
: 5. The potential for fire and explosion shall be addressed, ba sed on site-specific considerations. This includes the condition that the fuel tank of the cask handling equipment used to move the loaded CONCRETE CASK onto or from the ISFSI site contains no more than 50 gallons of fuel.
The analyzed flood condition of 15 fps water velocity and a height of 50 feet of water (full submergence of the loaded cask) are not exceeded.
: 6. Physical testing shall be conducted to demonstrate that the coeffi cient of friction between the concrete cask and ISFSI pad surface is at least 0.5.
5.
 
The potential for fire and explosion shall be addressed, based on site-specific considerations. This includes the condition that the fuel tank of the cask handling equipment used to move the loaded CONCRETE CASK onto or from the ISFSI site contains no more than 50 gallons of fuel.
6.
Physical testing shall be conducted to demonstrate that the coefficient of friction between the concrete cask and ISFSI pad surface is at least 0.5.
(continued)
(continued)
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-9 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-10 B 3.4.2 Maine Yankee Site Specific Parameters and Analyses (continued) 7.
 
In addition to the requirements of 10 CFR 72.212(b)(2)(ii), the ISFSI pad(s) and foundation shall meet the design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad as specified in B 3.4.2 (3).
B 3.4.2 Maine Yankee Site Specific Parameters and Analyses (continued)
The surface of the ISFSI pad shall have a broom finish or brushed surface as defined in ACI 116R-90 and described in Sections 7.12 and 7.13.4 of ACI 302.1R.
: 7. In addition to the requirements of 10 CFR 72.212(b)(2)(ii), the ISFSI pad(s) and foundation shall meet th e design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad as specified in B 3.4.2 (3).
8.
 
In cases where engineered features (i.e., berms, shield walls) are used to ensure that requirements of 10 CFR 72.104(a) are met, such features are to be considered important to safety and must be evaluated to determine the applicable Quality Assurance Category on a site specific basis.
The surface of the ISFSI pad shall have a broom finish or brushed surface as defined in ACI 116R-90 and described in Sections 7.12 an d 7.13.4 of ACI 302.1R.
9.
: 8. In cases where engineered features (i.e., berms, shield walls) are used to ensure that requirements of 10 CFR 72.104(a) are met, such features are to be considered important to safety and must be evaluated to determine the applicable Quality Assurance Category on a site spec ific basis.
TRANSFER CASK OPERATIONS shall only be conducted with surrounding air temperatures 0&deg;F.
: 9. TRANSFER CASK OPERATIONS shall only be conducted with surrounding air temperatures 0&deg;F.
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-10 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-11 B 3.5 CANISTER HANDLING FACILITY (CHF)
 
B 3.5 CANISTER HANDLING FACILITY (CHF)
B 3.5.1 TRANSFER CASK and CANISTER Lifting Devices Movements of the TRANSFER CASK and CANISTER outside of the 10 CFR 50 licensed facilities, when loaded with spent fuel are not permitted unless the movements are made with a CANISTER HANDLING FACILITY designed, operated, fabricated, tested, inspected and maintained in accordance with the guidelines of NUREG-0612, Control of Heavy Loads at Nuclear Power Plants and the below clarifications. This Technical Specification does not apply to handling heavy loads under a 10 CFR 50 license.
B 3.5.1 TRANSFER CASK and CANISTER Lifting Devices Movements of the TRANSFER CASK and CANISTER outside of the 10 CFR 50 licensed facilities, when loaded with spent fuel are not permitted unless the movements are made with a CANISTER HANDLING FACILITY designed, operated, fabricated, tested, inspected and maintained in accordance with the guidelines of NUREG-0612, Control of Heavy Loads at Nuclear Power Plants and the below clarifications. This Technical Specification does not apply to handling heavy loads under a 10 CFR 50 license.
 
B 3.5.2 CANISTER HANDLING FACILITY Structure Requirements B 3.5.2.1 CANISTER Station and Stationary Lifting Devices 1.
B 3.5.2 CANISTER HANDLING FACILITY Structure Requirements B 3.5.2.1 CANISTER Station and Stationary Lifting Devices
The weldment structure of the CANISTER HANDLING FACILITY shall be designed to comply with the stress limits of ASME Code, Section III, Subsection NF, Class 3 for linear structures. The applicable loads, load combinations, and associated service condition definitions are provided in Table B3-2. All compression loaded members shall satisfy the buckling criteria of ASME Code, Section III, Subsection NF.
: 1. The weldment structure of the CANISTER HANDLING FACILITY shall be designed to comply with the stress limits of ASME Code, Section III, Subsection NF, Class 3 for linear structures. The applicable loads, load combinations, and associated service condition definitions are provided in Table B3-2. All compression loaded members shall satisfy the buckling criteria of ASME Code, Section III, Subsection NF.
2.
: 2. If a portion of the CANISTER HANDLING FACILITY struct ure is constructed of reinforced concrete, then the factored load combinations set forth in ACI-318 (1995) for the loads defined in Table B3-2 shall apply.
If a portion of the CANISTER HANDLING FACILITY structure is constructed of reinforced concrete, then the factored load combinations set forth in ACI-318 (1995) for the loads defined in Table B3-2 shall apply.
: 3. The TRANSFER CASK and CANISTER lifting device used with the CANISTER HANDLING FACILITY shall be designed, fabricated, operated, tested, inspected and maintained in accordance with NUREG-0612, Section 5.1.
3.
 
The TRANSFER CASK and CANISTER lifting device used with the CANISTER HANDLING FACILITY shall be designed, fabricated, operated, tested, inspected and maintained in accordance with NUREG-0612, Section 5.1.
(continued)
(continued)
Renewed Amendment No. 4


Certificate of Compliance No. 1015 B3-11 Renewed Amendment No. 4 Design Features B 3.0
Design Features B 3.0 Certificate of Compliance No. 1015 B3-12 B 3.5.2.1 CANISTER HANDLING Station and Stationary Lifting Devices (continued) 4.
 
The CHF design shall incorporate an impact limiter for CANISTER lifting and movement if a qualified single failure proof crane is not used. The impact limiter must be designed and fabricated to ensure that, if a CANISTER is dropped, the confinement boundary of the CANISTER would not be breached.
B 3.5.2.1 CANISTER HANDLING Station and Stationary Lifting Devices (continued)
: 4. The CHF design shall incorporate an impact limiter for CANI STER lifting and movement if a qualified single failure proof crane is not used. The impact limiter must be designed and fabricated to ensure that, if a CANI STER is dropped, the confinement boundary of the CANISTER would not be breached.
 
B 3.5.2.2 Mobile Lifting Devices If a mobile lifting device is used as the lifting device, in lieu of a stationary lifting device, it shall meet the guidelines of NUREG-0612, Section 5.1, with the following clarifications:
B 3.5.2.2 Mobile Lifting Devices If a mobile lifting device is used as the lifting device, in lieu of a stationary lifting device, it shall meet the guidelines of NUREG-0612, Section 5.1, with the following clarifications:
: 1. Mobile lifting devices shall have a minimum safety factor of two over the allowable load table for the lifting device in accor dance with the guidance of NUREG-0612, Section 5.1.6(1)(a) and shall be capable of stopping and holding the load during a Design Basis Earthquake (DBE) event.
1.
: 2. Mobile lifting devices shall conform to the requirements of ANSI B30.5, Mobile and Locomotive Cranes, in lieu of the requirements of ANSI B30.2, Overh ead and Gantry Cranes.
Mobile lifting devices shall have a minimum safety factor of two over the allowable load table for the lifting device in accordance with the guidance of NUREG-0612, Section 5.1.6(1)(a) and shall be capable of stopping and holding the load during a Design Basis Earthquake (DBE) event.
: 3. Mobile cranes are not required to meet the requirements of NUREG-0612, Section 5.1.6(2) for new cranes.
2.
 
Mobile lifting devices shall conform to the requirements of ANSI B30.5, Mobile and Locomotive Cranes, in lieu of the requirements of ANSI B30.2, Overhead and Gantry Cranes.
Certificate of Compliance No. 1015 B3-12 Renewed Amendment No. 4 Design Features B 3.0
3.
 
Mobile cranes are not required to meet the requirements of NUREG-0612, Section 5.1.6(2) for new cranes.
Table B3-2 Load Combinations and Service Condition Definitions for the CANISTER HANDLING FACILITY (CHF) Structure
Renewed Amendment No. 4  
 
Load Combination ASME Section III Service Comment Condition for Definition of Allowable Stress D* All primary load bearing Level A members must satisfy Level A D + S stress limits D + M + W1 Factor of safety against overturning shall be 1.1 D + F Level D D + E
 
D + Y
 
D = Crane hook dead load D* = Apparent crane hook dead load S = Snow and ice load for the CHF site M = Tornado missile load of the CHF site 1 W = Tornado wind load for the CHF site 1 F = Flood load for the CHF site E = Seismic load for the CHF site Y = Tsunami load for the CHF site
 
Note:
: 1. Tornado missile load may be reduced or eliminated based on a PRA for t he CHF site.


Certificate of Compliance No. 1015 B3-13 Renewed Amendment No. 4}}
Design Features B 3.0 Certificate of Compliance No. 1015 B3-13 Table B3-2 Load Combinations and Service Condition Definitions for the CANISTER HANDLING FACILITY (CHF) Structure Load Combination ASME Section III Service Condition for Definition of Allowable Stress Comment D*
D + S Level A All primary load bearing members must satisfy Level A stress limits D + M + W1 D + F D + E D + Y Level D Factor of safety against overturning shall be 1.1 D
=
Crane hook dead load D*
=
Apparent crane hook dead load S
=
Snow and ice load for the CHF site M
=
Tornado missile load of the CHF site1 W
=
Tornado wind load for the CHF site1 F
=
Flood load for the CHF site E
=
Seismic load for the CHF site Y
=
Tsunami load for the CHF site Note:
1.
Tornado missile load may be reduced or eliminated based on a PRA for the CHF site.
Renewed Amendment No. 4}}

Latest revision as of 18:10, 24 November 2024

Conditions for Cask Use and Technical Specifications, Renewed Amendment 4 - Appendix B
ML24151A014
Person / Time
Site: 07201015
Issue date: 06/11/2024
From:
Storage and Transportation Licensing Branch
To:
NAC International
References
Download: ML24151A014 (1)


Text

____________________________________________________________________________

Certificate of Compliance No. 1015 B-1 Renewed Amendment No. 4 APPENDIX B APPROVED CONTENTS AND DESIGN FEATURES FOR THE NAC-UMS SYSTEM AMENDMENT 4

LIST OF EFFECTIVE PAGES (updated by Revision UMSS-04B)

Appendix B Certificate of Compliance No. 1015 B-2 B-1........................Amendment No. 4 B-2........................Amendment No. 4 B-3........................Amendment No. 4 B1-1.......................Amendment No. 4 B2-1.......................Amendment No. 4 B2-2.......................Amendment No. 4 B2-3.......................Amendment No. 4 B2-4.......................Amendment No. 4 B2-5.......................Amendment No. 4 B2-6.......................Amendment No. 4 B2-7.......................Amendment No. 4 B2-8.......................Amendment No. 4 B2-9.......................Amendment No. 4 B2-10.....................Amendment No. 4 B2-11.....................Amendment No. 4 B2-12.....................Amendment No. 4 B2-13.....................Amendment No. 4 B2-14.....................Amendment No. 4 B2-15.....................Amendment No. 4 B2-16.....................Amendment No. 4 B2-17.....................Amendment No. 4 B2-18.....................Amendment No. 4 B3-1....................... Amendment No. 4 B3-2....................... Amendment No. 4 B3-3....................... Amendment No. 4 B3-4....................... Amendment No. 4 B3-5....................... Amendment No. 4 B3-6....................... Amendment No. 4 B3-7....................... Amendment No. 4 B3-8....................... Amendment No. 4 B3-9....................... Amendment No. 4 B3-10..................... Amendment No. 4 B3-11..................... Amendment No. 4 B3-12..................... Amendment No. 4 B3-13..................... Amendment No. 4 Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B-3 Appendix B Table of Contents B 1.0 [Reserved]................................................................................................................... B1-1 B 2.0 Approved Contents..................................................................................................... B2-1 B 2.1 Fuel Specifications and Loading Conditions................................................... B2-1 Figure B2-1 PWR Basket Fuel Loading Positions............................................................ B2-4 Figure B2-2 BWR Basket Fuel Loading Positions............................................................ B2-4 Table B2-1 Fuel Assembly Limits.................................................................................... B2-5 Table B2-2 PWR Fuel Assembly Characteristics............................................................ B2-8 Table B2-3 BWR Fuel Assembly Characteristics............................................................ B2-9 Table B2-4 Minimum Cooling Time Versus Burnup/Initial Enrichment for PWR Fuel................................................................................................... B2-10 Table B2-5 Minimum Cooling Time Versus Burnup/Initial Enrichment for BWR Fuel................................................................................................... B2-11 Table B2-6 Maine Yankee Site Specific Fuel Canister Loading Position Summary..... B2-12 Table B2-7 Maine Yankee Site Specific Fuel Limits..................................................... B2-13 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material - Required Cool Time in Years Before Assembly is Acceptable.................................................................................................. B2-16 Table B2-9 Loading Table for Maine Yankee CE 14 x 14 Fuel Containing CEA Cooled to Indicated Time................................................................... B2-18 B 3.0 Design Features.......................................................................................................... B3-1 B 3.1 Site.................................................................................................................. B3-1 B 3.2 Design Features Important for Criticality Control............................................. B3-1 B 3.3 Codes and Standards...................................................................................... B3-1 B 3.4 Site Specific Parameters and Analyses........................................................... B3-7 B 3.5 CANISTER HANDLING FACILITY (CHF)..................................................... B3-11 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM....................... B3-3 Table B3-2 Load Combinations and Service Condition Definitions for the CANISTER HANDLING FACILITY (CHF) Structure................................... B3-13 Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B1-1 1.0

[Reserved]

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-1 B 2.0 APPROVED CONTENTS B 2.1 Fuel Specifications and Loading Conditions The NAC-UMS System is designed to provide passive dry storage of canistered PWR and BWR spent fuel. The system requires few operating controls. The principal controls and limits for the NAC-UMS SYSTEM are satisfied by the selection of fuel for storage that meets the Approved Contents presented in this section and in Tables B2-1 through B2-5 for the standard NAC-UMS SYSTEM design basis spent fuels.

This section also permits the loading of fuel assemblies that are unique to specific reactor sites. SITE SPECIFIC FUEL assembly configurations are either shown to be bounded by the analysis of the standard NAC-UMS System design basis fuel assembly configuration of the same type (PWR or BWR), or are shown to be acceptable contents by specific evaluation of the configuration.

The separate specific evaluation may establish different limits, which are maintained by administrative controls for preferential loading. The preferential loading controls allow the loading of fuel configurations that may have higher burnup, additional hardware material or unique configurations as compared to the standard NAC-UMS System design basis spent fuels.

Unless specifically excepted, SITE SPECIFIC FUEL must meet all of the controls and limits specified for the NAC-UMS System.

If any Fuel Specification or Loading Conditions of this section are violated, the following actions shall be completed:

The affected fuel assemblies shall be placed in a safe condition.

Within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />, notify the NRC Operations Center.

Within 30 days, submit a special report that describes the cause of the violation and actions taken to restore or demonstrate compliance and prevent recurrence.

(continued)

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-2 B 2.1.1 Fuel to be Stored in the NAC-UMS SYSTEM INTACT FUEL ASSEMBLIES meeting the limits specified in Tables B2-1 through B2-5 may be stored in the NAC-UMS SYSTEM.

B 2.1.2 Maine Yankee SITE SPECIFIC FUEL Preferential Loading The estimated Maine Yankee SITE SPECIFIC FUEL inventory is shown in Table B2-6.

As shown in this table, certain of the Maine Yankee fuel configurations must be preferentially loaded in specific basket fuel tube positions.

Corner positions are used for CONSOLIDATED FUEL, certain HIGH BURNUP FUEL and DAMAGED FUEL or FUEL DEBRIS loaded in a MAINE YANKEE FUEL CAN, for fuel assemblies with missing fuel rods, burnable poison rods or fuel assemblies with fuel rods that have been replaced by hollow zirconium alloy rods. Designation for placement in corner positions results primarily from shielding or criticality evaluations of these fuel configurations. CONSOLIDATED FUEL is conservatively designated for a corner position, even though analysis shows that these lattices could be loaded in any basket position.

Corner positions are positions 3, 6, 19, and 22 in Figure B2-1.

Preferential loading is also used for HIGH BURNUP fuel not loaded in the MAINE YANKEE FUEL CAN. This fuel is assigned to peripheral locations, positions 1, 2, 3, 6, 7, 12, 13, 18, 19, 22, 23, and 24 in Figure B2-1. The interior locations, positions 4, 5, 8, 9, 10, 11, 14, 15, 16, 17, 20, and 21, must be loaded with fuel that has lower burnup and/or longer cool times to maintain the design basis heat load (23 kW per canister).

One of the two loading patterns (Standard or Preferential) shown in Table B2-8 must be used to load each canister. For the Standard loading pattern, the heat load of each fuel assembly is limited to 0.958 kW. For the Preferential loading pattern, the heat load of the fuel assemblies at the basket periphery locations is limited to 1.05 kW, and the heat load of the fuel assemblies at the basket interior locations is limited to 0.867 kW. Once selected, all of the spent fuel in that canister must be loaded in accordance with that pattern. Within a pattern, mixing of enrichment and cool time is allowed, but no mixing of loading patterns is permitted. Choosing a Preferential pattern restricts the interior fuel to the cool times shown in the Preferential (I) column, and the peripheral fuel to the cool times shown in the Preferential (P) column.

(continued)

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-3 B 2.1.2 Maine Yankee SITE SPECIFIC FUEL Preferential Loading (continued)

Fuel assemblies with a control element assembly (CEA) inserted will be loaded in a Class 2 canister and basket due to the increased length of the assembly with the CEA installed. However, these assemblies are not restricted as to loading position within the basket. Fuel assemblies with non-fuel items installed in corner guide tubes of the fuel assembly must also have a flow mixer installed and must be loaded in a basket corner fuel position in a Class 2 canister.

The Transportable Storage Canister loading procedures indicate that loading of a fuel configuration with removed fuel or poison rods, CONSOLIDATED FUEL, or a MAINE YANKEE FUEL CAN with DAMAGED FUEL, FUEL DEBRIS or HIGH BURNUP FUEL, is administratively controlled in accordance with Section B 2.1.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-4 Figure B2-1 PWR Basket Fuel Loading Positions Figure B2-2 BWR Basket Fuel Loading Positions Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-5 Table B2-1 Fuel Assembly Limits I.

NAC-UMS CANISTER: PWR FUEL A. Allowable Contents 1.

Uranium oxide PWR INTACT FUEL ASSEMBLIES listed in Table B2-2 and meeting the following specifications:

a.

Cladding Type:

Zirconium alloy with thickness as specified in Table B2-2 for the applicable fuel assembly class.

b.

Enrichment, Post-irradiation Cooling Time and Average Burnup Per Assembly:

Maximum enrichment limits are shown in Table B2-2. For variable enrichment fuel assemblies, maximum enrichments represent peak rod enrichments. Combined minimum enrichment, maximum burnup and minimum cool time limits are shown in Table B2-4.

c.

Decay Heat Per Assembly:

< 958.3 watts d.

Nominal Fresh Fuel Assembly Length (in.):

< 178.3 e.

Nominal Fresh Fuel Assembly Width (in.):

< 8.54 f.

Fuel Assembly Weight (lbs.):

< 1,602 Decay heat may be higher for site-specific configurations, which control fuel loading position.

Includes the weight of nonfuel-bearing components.

B. Quantity per CANISTER: Up to 24 PWR INTACT FUEL ASSEMBLIES.

C. PWR INTACT FUEL ASSEMBLIES may contain a flow mixer (thimble plug), an in-core instrument thimble, a burnable poison rod insert (Class 1 and Class 2 contents) consistent with Table B2-2, or solid stainless steel rods (inserted in the guide tubes).

D. PWR INTACT FUEL ASSEMBLIES shall not contain a control element assembly, except as permitted for SITE-SPECIFIC FUEL.

E. Stainless steel spacers may be used in CANISTERS to axially position PWR INTACT FUEL ASSEMBLIES that are shorter than the available cavity length to facilitate handling.

F. Unenriched fuel assemblies are not authorized for loading.

G. The minimum length of the PWR INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure that the minimum distance to the fuel region from the base of the CANISTER is 3.2 inches.

H. PWR INTACT FUEL ASSEMBLIES with one or more grid spacers missing or damaged such that the unsupported length of the fuel rods does not exceed 60 inches. End fitting damage including damaged or missing hold-down springs is allowed, as long as the assembly can be handled safely by normal means.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-6 Table B2-1 Fuel Assembly Limits (continued)

II.

NAC-UMS CANISTER: BWR FUEL A. Allowable Contents 1.

Uranium oxide BWR INTACT FUEL ASSEMBLIES listed in Table B2-3 and meeting the following specifications:

a. Cladding Type:

Zirconium alloy with thickness as specified in Table B2-3 for the applicable fuel assembly class.

b. Enrichment:

Maximum INITIAL PEAK PLANAR-AVERAGE ENRICHMENTS are shown in Table B2-3.

Combined minimum enrichment, maximum burnup and minimum cool time limits are shown in Table B2-5.

c. Decay Heat per Assembly:

< 410.7 watts

d. Post-irradiation Cooling Time and Average Burnup Per Assembly:

As specified in Table B2-5 and for the applicable fuel assembly class.

e. Nominal Fresh Fuel Design Assembly Length (in.):

< 176.1 f.

Nominal Fresh Fuel Design Assembly Width (in.):

< 5.51

g. Fuel Assembly Weight (lbs):

< 702, including channels Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-7 Table B2-1 Fuel Assembly Limits (continued)

B.

Quantity per CANISTER: Up to 56 BWR INTACT FUEL ASSEMBLIES C.

BWR INTACT FUEL ASSEMBLIES can be unchanneled or channeled with zirconium alloy channels.

D.

BWR INTACT FUEL ASSEMBLIES with stainless steel channels shall not be loaded.

E.

Stainless steel fuel spacers may be used in CANISTERS to axially position BWR INTACT FUEL ASSEMBLIES that are shorter than the available cavity length to facilitate handling.

F.

Unenriched fuel assemblies are not authorized for loading.

G.

The minimum length of the BWR INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure that the minimum distance to the fuel region from the base of the CANISTER is 6.2 inches.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-8 Table B2-2 PWR Fuel Assembly Characteristics Fuel Class Vendor 1 Array Max.

MTU W/O Boron Max.

wt %

235U 4 With Boron Max.

wt %

235U 5 No. of Fuel Rods 3 No. of Water Holes Max.

Pitch (in)

Min.

Rod Dia. (in)

Min.

Clad Thick (in)

Max.

Pellet Dia.(in)

Max.

Active Length (in)

Min. Guide Tube Thick (in) 1 CE 14x14 0.404 4.7 5.0 176 5

0.590 0.438 0.024 0.380 137.0 0.034 1

Ex/ANF 14x14 0.369 5.0 5.0 179 17 0.556 0.424 0.030 0.351 142.0 0.034 1

WE 14x14 0.362 5.0 5.0 179 17 0.556 0.400 0.024 0.345 144.0 0.034 1

WE 14x14 0.415 5.0 5.0 179 17 0.556 0.422 0.022 0.368 145.2 0.034 1

WE, Ex/ANF 15x15 0.465 4.4 5.0 204 21 0.563 0.422 0.024 0.366 144.0 0.015 1

Ex/ANF 17x17 0.413 4.4 5.0 264 25 0.496 0.360 0.025 0.303 144.0 0.016 1

WE 17x17 0.468 4.5 5.0 264 25 0.496 0.374 0.022 0.323 144.0 0.015 1

WE 17x17 0.429 4.3 5.0 264 25 0.496 0.360 0.022 0.309 144.0 0.015 2

B&W 15x15 0.481 4.4 5.0 208 17 0.568 0.430 0.026 0.369 144.0 0.016 2

B&W 17x17 0.466 4.4 5.0 264 25 0.502 0.379 0.024 0.324 143.0 0.017 3

CE 16x16 0.442 4.8 5.0 236 5

0.506 0.382 0.023 0.3255 150.0 0.035 1

Ex/ANF2 14x14 0.375 5.0 179 17 0.556 0.417 0.030 0.351 144.0 0.036 1

CE2 15x15 0.432 4.2 216 9 6 0.550 0.418 0.026 0.358 132.0 1

Ex/ANF2 15x15 0.431 4.2 216 9 6 0.550 0.417 0.030 0.358 131.8 1

CE2 16x16 0.403 4.8 236 5

0.506 0.382 0.023 0.3255 136.7 0.035 Note: Parameters shown are nominal pre-irradiation values.

1.

Vendor ID indicates the source of assembly base parameters, which are nominal, pre-irradiation values. Loading of assemblies meeting above limits is not restricted to the vendor(s) listed.

2.

14x14, 15x15 and 16x16 fuel manufactured for Prairie Island, Palisades and St. Lucie 2 cores, respectively. These are not generic fuel assemblies provided to multiple reactors.

3.

Fuel rod positions may be occupied by burnable poison rods or solid filler rods.

4.

Maximum initial enrichment without boron credit. Assemblies meeting this limit may contain a flow mixer (thimble plug), an ICI thimble, a burnable poison rod insert, or solid stainless steel rods (inserted in guide tubes).

5.

Maximum initial enrichment with credit for a minimum soluble boron concentration of 1000 ppm in the spent fuel pool water. Assemblies meeting this limit may contain a flow mixer (thimble plug).

6.

Nine non-fuel locations, which may be filled by solid non-fuel rods.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-9 Amendment No. 4 Table B2-3 BWR Fuel Assembly Characteristics Fuel Class1 Vendor4 Array Max.

MTU Max.

wt % 235U No. of Fuel Rods Max.

Pitch (in)

Min. Rod Dia. (in)

Min. Clad Thick (in)

Max.

Pellet Dia.(in)

Max. Active Length (in)2 4

Ex/ANF 7 x 7 0.196 4.5 48 0.738 0.570 0.036 0.490 144.0 4

Ex/ANF 8 x 8 0.177 4.7 63 0.641 0.484 0.036 0.405 145.2 4

Ex/ANF 9 x 9 0.173 4.4 79 0.572 0.424 0.030 0.357 145.2 4

GE 7 x 7 0.199 4.5 49 0.738 0.570 0.036 0.488 144.0 4

GE 7 x 7 0.198 4.5 49 0.738 0.563 0.032 0.487 144.0 4

GE 8 x 8 0.173 4.5 60 0.640 0.484 0.032 0.410 145.2 4

GE 8 x 8 0.179 4.5 62 0.640 0.483 0.032 0.410 145.2 4

GE 8 x 8 0.186 4.7 63 0.640 0.493 0.034 0.416 144.0 5

Ex/ANF 8 x 8 0.180 4.6 62 0.641 0.484 0.036 0.405 150.0 5

Ex/ANF 9 x 9 0.167 4.4 743 0.572 0.424 0.030 0.357 150.0 5

Ex/ANF 9 x 9 0.178 4.5 793 0.572 0.424 0.030 0.357 150.0 5

GE 7 x 7 0.193 4.7 49 0.738 0.563 0.037 0.477 146.0 5

GE 7 x 7 0.198 4.5 49 0.738 0.563 0.032 0.487 144.0 5

GE 8 x 8 0.179 4.5 60 0.640 0.484 0.032 0.410 150.0 5

GE 8 x 8 0.185 4.5 62 0.640 0.483 0.032 0.410 150.0 5

GE 8 x 8 0.188 4.7 63 0.640 0.493 0.034 0.416 146.0 5

GE 9 x 9 0.186 4.5 743 0.566 0.441 0.028 0.376 150.0 5

GE 9 x 9 0.198 4.6 793 0.566 0.441 0.028 0.376 150.0 Note: Parameters shown are nominal pre-irradiation values.

1. All fuel rods are zirconium alloy clad.
2. 150-inch active fuel length assemblies contain 6 natural uranium blankets on top and bottom.
3. Shortened active fuel length in some rods.
4. Vendor ID indicates the source of assembly base parameters, which are nominal, pre-irradiation values. Loading of assemblies meeting above limits is not restricted to the vendor(s) listed.

Renewed

Approved Contents B 2.0 Certificate of Compliance B2-10 Table B2-4 Minimum Cooling Time Versus Burnup/Initial Enrichment for PWR Fuel Minimum Initial Enrichment Burnup 30 GWD/MTU Minimum Cooling Time [years]

30< Burnup 35 GWD/MTU Minimum Cooling Time [years]

wt % 235U (E) 14x14 15x15 16x16 17x17 14x14 15x15 16x16 17x17 1.9 E < 2.1 5

5 5

5 7

7 5

7 2.1 E < 2.3 5

5 5

5 7

6 5

6 2.3 E < 2.5 5

5 5

5 6

6 5

6 2.5 E < 2.7 5

5 5

5 6

6 5

6 2.7 E < 2.9 5

5 5

5 6

5 5

5 2.9 E < 3.1 5

5 5

5 5

5 5

5 3.1 E < 3.3 5

5 5

5 5

5 5

5 3.3 E < 3.5 5

5 5

5 5

5 5

5 3.5 E < 3.7 5

5 5

5 5

5 5

5 3.7 E < 3.9 5

5 5

5 5

5 5

5 3.9 E < 4.1 5

5 5

5 5

5 5

5 4.1 E < 4.3 5

5 5

5 5

5 5

5 4.3 E < 4.5 5

5 5

5 5

5 5

5 4.5 E < 4.7 5

5 5

5 5

5 5

5 4.7 E < 4.9 5

5 5

5 5

5 5

5 E 4.9 5

5 5

5 5

5 5

5 Minimum Initial Enrichment 35< Burnup 40 GWD/MTU Minimum Cooling Time [years]

40< Burnup 45 GWD/MTU Minimum Cooling Time [years]

wt % 235U (E) 14x14 15x15 16x16 17x17 14x14 15x15 16x16 17x17 1.9 E < 2.1 10 10 7

10 15 15 11 15 2.1 E < 2.3 9

9 6

9 14 13 9

13 2.3 E < 2.5 8

8 6

8 12 12 8

12 2.5 E < 2.7 8

7 6

7 11 11 7

11 2.7 E < 2.9 7

7 6

7 10 10 7

10 2.9 E < 3.1 7

6 6

7 9

9 7

9 3.1 E < 3.3 6

6 6

6 9

8 7

8 3.3 E < 3.5 6

6 6

6 8

8 7

8 3.5 E < 3.7 6

6 6

6 7

8 7

7 3.7 E < 3.9 6

6 6

6 7

8 7

7 3.9 E < 4.1 6

6 6

6 7

7 7

7 4.1 E < 4.3 5

6 6

6 6

7 7

7 4.3 E < 4.5 5

6 6

6 6

7 7

7 4.5 E < 4.7 5

6 5

6 6

7 6

7 4.7 E < 4.9 5

6 5

6 6

7 6

7 E 4.9 5

6 5

6 6

7 6

7 Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance B2-11 Table B2-5 Minimum Cooling Time Versus Burnup/Initial Enrichment for BWR Fuel Minimum Initial Enrichment Burnup 30 GWD/MTU Minimum Cooling Time [years]

30< Burnup 35 GWD/MTU Minimum Cooling Time [years]

wt % 235U (E) 7x7 8x8 9x9 7x7 8x8 9x9 1.9 E < 2.1 5

5 5

8 7

7 2.1 E < 2.3 5

5 5

6 6

6 2.3 E < 2.5 5

5 5

6 5

6 2.5 E < 2.7 5

5 5

5 5

5 2.7 E < 2.9 5

5 5

5 5

5 2.9 E < 3.1 5

5 5

5 5

5 3.1 E < 3.3 5

5 5

5 5

5 3.3 E < 3.5 5

5 5

5 5

5 3.5 E < 3.7 5

5 5

5 5

5 3.7 E < 3.9 5

5 5

5 5

5 3.9 E < 4.1 5

5 5

5 5

5 4.1 E < 4.3 5

5 5

5 5

5 4.3 E < 4.5 5

5 5

5 5

5 4.5 E 4.7 5

5 5

5 5

5 Minimum Initial Enrichment 35< Burnup 40 GWD/MTU Minimum Cooling Time [years]

40< Burnup 45 GWD/MTU Minimum Cooling Time [years]

wt % 235U (E) 7x7 8x8 9x9 7x7 8x8 9x9 1.9 E < 2.1 16 14 15 26 24 25 2.1 E < 2.3 13 12 12 23 21 22 2.3 E < 2.5 11 9

10 20 18 19 2.5 E < 2.7 9

8 8

18 16 17 2.7 E < 2.9 8

7 7

15 13 14 2.9 E < 3.1 7

6 6

13 11 12 3.1 E < 3.3 6

6 6

11 10 10 3.3 E < 3.5 6

5 6

9 8

9 3.5 E < 3.7 6

5 6

8 7

7 3.7 E < 3.9 6

5 5

7 6

7 3.9 E < 4.1 5

5 5

7 6

7 4.1 E < 4.3 5

5 5

7 6

6 4.3 E < 4.5 5

5 5

6 6

6 4.5 E 4.7 5

5 5

6 6

6 Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance B2-12 Table B2-6 Maine Yankee Site Specific Fuel Canister Loading Position Summary Site Specific Spent Fuel Configurations1 Est. Number of Assemblies2 Canister Loading Position Total Number of Fuel Assemblies3 1,434 Any Inserted Control Element Assembly (CEA) 168 Any Inserted In-Core Instrument (ICI) Thimble 138 Any Consolidated Fuel 2

Corner4 Fuel Rod Replaced by Rod Enriched to 1.95 wt %

3 Any Fuel Rod Replaced by Stainless Steel Rod or Zirconium Alloy Rod 18 Any Fuel Rods Removed 10 Corner4 Variable Enrichment6 72 Any Variable Enrichment and Axial Blanket6 68 Any Burnable Poison Rod Replaced by Hollow Zirconium Alloy Rod 80 Corner4 Damaged Fuel in MAINE YANKEE FUEL CAN 12 Corner4 Burnup between 45,000 and 50,000 MWD/MTU 90 Periphery5 MAINE YANKEE FUEL CAN As Required Corner4 Inserted Start-up Source 4

Corner4 Inserted CEA Finger Tip or ICI String Segment 1

Corner4 1.

All spent fuel, including that held in a Maine Yankee fuel can, must conform to the loading limits presented in Tables B2-8 and B2-9 for cool time.

2.

The number of fuel assemblies in some categories may vary depending on future fuel inspections.

3.

Includes these site specific spent fuel configurations and standard fuel assemblies. Standard fuel assemblies may be loaded in any canister position.

4.

Basket corner positions are positions 3, 6, 19, and 22 in Figure B2-1. Corner positions are also periphery positions.

5.

Basket periphery positions are positions 1, 2, 3, 6, 7, 12, 13, 18, 19, 22, 23, and 24 in Figure B2-1. Periphery positions include the corner positions.

6.

Variably enriched fuel assemblies have a maximum burnup of less than 30,000 MWD/MTU and enrichments greater than 1.9 wt %. The minimum required cool time for these assemblies is 5 years.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance B2-13 Table B2-7 Maine Yankee Site Specific Fuel Limits A. Allowable Contents 1.

Combustion Engineering 14 x 14 PWR INTACT FUEL ASSEMBLIES meeting the specifications presented in Tables B2-1, B2-2 and B2-4.

2.

PWR INTACT FUEL ASSEMBLIES may contain inserted Control Element Assemblies (CEA), In-Core Instrument (ICI) Thimbles or Flow Mixers. CEAs or Flow Mixers may not be inserted in damaged fuel assemblies, consolidated fuel assemblies or assemblies with irradiated stainless steel replacement rods. Fuel assemblies with a CEA or Flow Mixer inserted must be loaded in a Class 2 CANISTER and cannot be loaded in a Class 1 CANISTER. Fuel assemblies without an inserted CEA or CEA Plug, including those with inserted ICI Thimbles, must be loaded in a Class 1 CANISTER.

3.

PWR INTACT FUEL ASSEMBLIES with fuel rods replaced with stainless steel or zirconium alloy rods or with uranium oxide rods nominally enriched up to 1.95 wt %.

4.

PWR INTACT FUEL ASSEMBLIES with fuel rods having variable enrichments with a maximum fuel rod enrichment up to 4.21 wt % 235U and that also have a maximum planar average enrichment up to 3.99 wt % 235U.

5.

PWR INTACT FUEL ASSEMBLIES with annular axial end blankets. The axial end blanket enrichment may be up to 2.6 wt % 235U.

6.

PWR INTACT FUEL ASSEMBLIES with solid filler rods or burnable poison rods occupying up to 16 of 176 fuel rod positions.

7.

PWR INTACT FUEL ASSEMBLIES with one or more grid spacers missing or damaged such that the unsupported length of the fuel rods does not exceed 60 inches or with end fitting damage, including damaged or missing hold-down springs, as long as the assembly can be handled safely by normal means.

B. Allowable Contents requiring preferential loading based on shielding, criticality or thermal constraints. The preferential loading requirement for these fuel configurations is as described in Table B2-6.

1.

PWR INTACT FUEL ASSEMBLIES with up to 176 fuel rods missing from the fuel assembly lattice.

2.

PWR INTACT FUEL ASSEMBLIES with a burnup between 45,000 and 50,000 MWD/MTU that must be loaded in accordance with Tables B2-6 and B2-8.

3.

PWR INTACT FUEL ASSEMBLIES with a burnable poison rod replaced by a hollow zirconium alloy rod.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance B2-14 Table B2-7 Maine Yankee Site Specific Fuel Limits (continued) 4.

INTACT FUEL ASSEMBLIES with a start-up source in a center guide tube. The assembly must be loaded in a basket corner position and must be loaded in a Class 1 CANISTER. Only one (1) start-up source may be loaded in any fuel assembly or any CANISTER.

5.

PWR INTACT FUEL ASSEMBLIES with CEA ends (finger tips) and/or ICI segment inserted in corner guide tube positions. The assembly must also have a CEA plug installed. The assembly must be loaded in a basket corner position and must be loaded in a Class 2 CANISTER.

6.

INTACT FUEL ASSEMBLIES may be loaded in a MAINE YANKEE FUEL CAN.

7.

FUEL enclosed in a MAINE YANKEE FUEL CAN. The MAINE YANKEE FUEL CAN can only be loaded in a Class 1 CANISTER. The contents that must be loaded in the MAINE YANKEE FUEL CAN are:

a) PWR fuel assemblies with up to two INTACT or DAMAGED FUEL rods inserted in each fuel assembly guide tube or with up to two burnable poison rods inserted in each guide tube. The rods inserted in the guide tubes cannot be from a different fuel assembly. The maximum number of rods in the fuel assembly (fuel rods plus inserted rods, including burnable poison rods) is 176.

b) A DAMAGED FUEL ASSEMBLY with up to 100% of the fuel rods classified as damaged and/or damaged or missing assembly hardware components. A DAMAGED FUEL ASSEMBLY cannot have an inserted CEA or other non-fuel component.

c)

Individual INTACT or DAMAGED FUEL rods in a rod type structure, which may be a guide tube, to maintain configuration control.

d) FUEL DEBRIS consisting of fuel rods with exposed fuel pellets or individual intact or partial fuel pellets not contained in fuel rods.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-15 Table B2-7 Maine Yankee Site Specific Fuel Limits (continued) e) CONSOLIDATED FUEL lattice structure with a 17 x 17 array formed by grids and top and bottom end fittings connected by four solid stainless steel rods. Maximum contents are 289 fuel rods having a total lattice weight 2,100 pounds. A CONSOLIDATED FUEL lattice cannot have an inserted CEA or other non-fuel component. Only one CONSOLIDATED FUEL lattice may be stored in any CANISTER.

C. Unenriched fuel assemblies are not authorized for loading.

D. A canister preferentially loaded in accordance with Table B2-8 may only contain fuel assemblies selected from the same loading pattern.

Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-16 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material -

Required Cool Time in Years Before Assembly is Acceptable Burnup 30 GWD/MTU - Minimum Cool Time [years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 5

5 5

2.1 E < 2.3 5

5 5

2.3 E < 2.5 5

5 5

2.5 E < 2.7 5

5 5

2.7 E < 2.9 5

5 5

2.9 E < 3.1 5

5 5

3.1 E < 3.3 5

5 5

3.3 E < 3.5 5

5 5

3.5 E < 3.7 5

5 5

3.7 E 4.2 5

5 5

30 < Burnup 35 GWD/MTU - Minimum Cool Time

[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 5

5 5

2.1 E < 2.3 5

5 5

2.3 E < 2.5 5

5 5

2.5 E < 2.7 5

5 5

2.7 E < 2.9 5

5 5

2.9 E < 3.1 5

5 5

3.1 E < 3.3 5

5 5

3.3 E < 3.5 5

5 5

3.5 E < 3.7 5

5 5

3.7 E 4.2 5

5 5

35 < Burnup 40 GWD/MTU - Minimum Cool Time

[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 7

7 5

2.1 E < 2.3 6

6 5

2.3 E < 2.5 6

6 5

2.5 E < 2.7 5

6 5

2.7 E < 2.9 5

6 5

2.9 E < 3.1 5

6 5

3.1 E < 3.3 5

6 5

3.3 E < 3.5 5

6 5

3.5 E < 3.7 5

6 5

3.7 E 4.2 5

6 5

1.

Standard loading pattern: allowable decay heat = 0.958 kW per assembly 2.

Preferential loading pattern, interior basket locations: allowable heat decay

.867 kW per assembly 3.

Preferential loading pattern, periphery basket locations: allowable heat decay = 1.05 kW per assembly Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-17 Table B2-8 Loading Table for Maine Yankee CE 14 x 14 Fuel with No Non-Fuel Material -

Required Cool Time in Years Before Assembly is Acceptable (Continued) 40 < Burnup 45 GWD/MTU - Minimum Cool Time

[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 11 11 6

2.1 E < 2.3 9

9 6

2.3 E < 2.5 8

8 6

2.5 E < 2.7 7

7 6

2.7 E < 2.9 7

7 6

2.9 E < 3.1 6

7 6

3.1 E < 3.3 6

7 5

3.3 E < 3.5 6

7 5

3.5 E < 3.7 6

7 5

3.7 E 4.2 6

7 5

45 < Burnup 50 GWD/MTU - Minimum Cool Time

[years] for Enrichment Standard1 Preferential (I)2 Preferential (P)3 1.9 E < 2.1 Not allowed Not allowed 7

2.1 E < 2.3 Not allowed Not allowed 7

2.3 E < 2.5 Not allowed Not allowed 7

2.5 E < 2.7 Not allowed Not allowed 7

2.7 E < 2.9 Not allowed Not allowed 7

2.9 E < 3.1 Not allowed Not allowed 7

3.1 E < 3.3 Not allowed Not allowed 7

3.3 E < 3.5 Not allowed Not allowed 6

3.5 E < 3.7 Not allowed Not allowed 6

3.7 E 4.2 Not allowed Not allowed 6

1.

Standard loading pattern: allowable decay heat = 0.958 kW per assembly 2.

Preferential loading pattern, interior basket locations: allowable heat decay = 0.867 kW per assembly 3.

Preferential loading pattern, periphery basket locations: allowable heat decay = 1.05 kW per assembly Renewed Amendment No. 4

Approved Contents B 2.0 Certificate of Compliance No. 1015 B2-18 Table B2-9 Loading Table for Maine Yankee CE 14 x 14 Fuel Containing CEA Cooled to Indicated Time 30 GWD/MTU Burnup - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 5

5 5

5 5

2.1 E < 2.3 5

5 5

5 5

2.3 E < 2.5 5

5 5

5 5

2.5 E < 2.7 5

5 5

5 5

2.7 E < 2.9 5

5 5

5 5

2.9 E < 3.1 5

5 5

5 5

3.1 E < 3.3 5

5 5

5 5

3.3 E < 3.5 5

5 5

5 5

3.5 E < 3.7 5

5 5

5 5

3.7 E 4.2 5

5 5

5 5

30 < Burnup 35 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 5

5 5

5 5

2.1 E < 2.3 5

5 5

5 5

2.3 E < 2.5 5

5 5

5 5

2.5 E < 2.7 5

5 5

5 5

2.7 E < 2.9 5

5 5

5 5

2.9 E < 3.1 5

5 5

5 5

3.1 E < 3.3 5

5 5

5 5

3.3 E < 3.5 5

5 5

5 5

3.5 E < 3.7 5

5 5

5 5

3.7 E 4.2 5

5 5

5 5

35 < Burnup 40 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 7

7 7

7 7

2.1 E < 2.3 6

6 6

6 6

2.3 E < 2.5 6

6 6

6 6

2.5 E < 2.7 5

6 5

5 5

2.7 E < 2.9 5

6 5

5 5

2.9 E < 3.1 5

6 5

5 5

3.1 E < 3.3 5

5 5

5 5

3.3 E < 3.5 5

5 5

5 5

3.5 E < 3.7 5

5 5

5 5

3.7 E 4.2 5

5 5

5 5

40 < Burnup 45 GWD/MTU - Minimum Cool Time in Years for Enrichment No CEA (Class 2) 5 Year CEA 10 Year CEA 15 Year CEA 20 Year CEA 1.9 E < 2.1 11 11 11 11 11 2.1 E < 2.3 9

9 9

9 9

2.3 E < 2.5 8

8 8

8 8

2.5 E < 2.7 7

7 7

7 7

2.7 E < 2.9 7

7 7

7 7

2.9 E < 3.1 6

6 6

6 6

3.1 E < 3.3 6

6 6

6 6

3.3 E < 3.5 6

6 6

6 6

3.5 E < 3.7 6

6 6

6 6

3.7 E 4.2 6

6 6

6 6

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-1 B 3.0 DESIGN FEATURES B 3.1 Site B 3.1.1 Site Location The NAC-UMS SYSTEM is authorized for general use by 10 CFR 50 license holders at various site locations under the provisions of 10 CFR 72, Subpart K.

B 3.2 Design Features Important for Criticality Control B 3.2.1 CANISTER-INTACT FUEL ASSEMBLIES a)

Minimum 10B loading in the neutron absorbers:

1.

PWR - 0.025g/cm2 2.

BWR - 0.011g/cm2 b)

Minimum length of INTACT FUEL ASSEMBLY internal structure and bottom end fitting and/or spacers shall ensure the minimum distance to the fuel region from the base of the CANISTER is:

1.

PWR - 3.2 inches 2.

BWR - 6.2 inches c)

Soluble boron concentration in the PWR fuel pool and CANISTER water:

1. Fuel meeting the enrichment limits in Table B2-2 without boron - 0 ppm.
2. Fuel meeting the enrichment limits in Table B2-2 with boron 1000 ppm.

d) Minimum water temperature for PWR fuel to ensure boron is soluble:

1.

Temperature should be 5 - 10oF higher than the minimum needed to ensure solubility.

B 3.3 Codes and Standards The American Society of Mechanical Engineers Boiler and Pressure Vessel Code (ASME Code), 1995 Edition with Addenda through 1995, is the governing Code for the NAC-UMS CANISTER.

The American Concrete Institute Specifications ACI-349 (1985) and ACI-318 (1995) govern the NAC-UMS CONCRETE CASK design and construction, respectively.

The American National Standards Institute ANSI N14.6 (1993) and NUREG-0612 govern the NAC-UMS TRANSFER CASK design, operation, fabrication, testing, inspection and maintenance.

(continued)

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-2 B 3.3.1 Exceptions to Codes, Standards, and Criteria Table B3-1 lists exceptions to the ASME Code for the design of the NAC-UMS SYSTEM.

B 3.3.2 Construction/Fabrication Exceptions to Codes, Standards, and Criteria Proposed alternatives to ASME Code,Section III, 1995 Edition with Addenda, through 1995, including exceptions listed in Specification B3.3.1, may be used when authorized by the Director of the Office of Nuclear Material Safety and Safeguards or designee. The request for such alternatives should demonstrate that:

1. The proposed alternatives would provide an acceptable level of quality and safety, or 2.

Compliance with the specified requirements of ASME Code,Section III, 1995 Edition with Addenda through 1995, would result in hardship or unusual difficulty without a compensating increase in the level of quality and safety.

Requests for exceptions shall be submitted in accordance with 10 CFR 72.4.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-3 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER NB-1100 Statement of requirements for Code stamping of components.

CANISTER is designed and will be fabricated in accordance with ASME Code,Section III, Subsection NB to the maximum practical extent, but Code stamping is not required. The completion of an ASME Design Specification, Design Report and Overpressure Protection Report is not required.

CANISTER NB-2000 Requirements to be supplied by ASME-approved material supplier.

Materials will be supplied by NAC-approved suppliers with Certified Material Test Reports (CMTRs) in accordance to NB-2000 requirements.

CANISTER NB-2500 Repairs to pressure-retaining material from which a defect(s) has been removed are to be examined by magnetic particle or dye penetrant methods. If the depth of the repair exceeds the lesser of 3/8-inch or 10% of the section thickness, examination is to be by radiography.

In accordance with ASME Code Case N-595-4, a loaded CANISTER shell examination of a weld repair of material within 1/2-inch of a closure weld may be done by progressive magnetic particle or dye penetrant examination methods for each weld layer 1/4-inch and final surface.

CANISTER Shield Lid and Structural Lid Welds NB-4243 Full penetration welds required for Category C joints (flat head to main shell per NB-3352.3).

Shield lid and structural lid to CANISTER shell welds are not full penetration welds. These field welds are performed independently to provide a redundant closure.

Leaktightness of the CANISTER is verified by testing.

CANISTER Structural Lid Weld NB-4421 Requires removal of backing ring.

Structural lid to CANISTER shell weld uses a backing ring that is not removed. The backing ring permits completion of the groove weld; it is not considered in any analyses; and it has no detrimental effect on the CANISTERs function.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-4 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)

Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER Vent Port Cover and Drain Port Cover to Shield Lid Welds; Shield Lid to Canister Shell Weld NB-5230 Radiographic (RT) or ultrasonic (UT) examination required.

Root and final surface liquid penetrant examination to be performed per ASME Code Section V, Article 6, with acceptance in accordance with ASME Code,Section III, NB-5350.

CANISTER Structural Lid to Shell Weld NB-5230 Radiographic (RT) or ultrasonic (UT) examination required.

The CANISTER structural lid to CANISTER shell closure weld is performed in the field following fuel assembly loading. The structural lid-to-shell weld will be verified by either ultrasonic (UT) or progressive liquid penetrant (PT) examination. If progressive PT examination is used, at a minimum, it must include the root and final layers and each approximately 3/8 inch of weld depth.

If UT examination is used, it will be followed by a final surface PT examination. For either UT or PT examination, the maximum, undetectable flaw size is demonstrated to be smaller than the critical flaw size.

The critical flaw size is determined in accordance with ASME Code,Section XI methods. The examination of the weld will be performed by qualified personnel per ASME Code Section V, Articles 5 (UT) and 6 (PT) with acceptance per ASME Code Section III, NB-5332 (UT) per 1995 Addenda, and NB-5350 for (PT).

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-5 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)

Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER Vessel and Shield Lid NB-6111 All completed pressure retaining systems shall be pressure tested.

The CANISTER shield lid to shell weld is performed in the field following fuel assembly loading. The CANISTER is then pneumatically (air/nitrogen/

helium-over-water) pressure tested as defined in Chapter 9 and described in Chapter 8. Accessibility for leakage inspections precludes a Code compliant hydrostatic test. The shield lid-to-shell weld is also leak tested to the leak-tight criteria of ANSI N14.5.

The vent port and drain port cover welds are examined by root and final PT examination. The structural lid enclosure weld is examined by progressive PT or UT and final surface PT.

CANISTER Vessel NB-7000 Vessels are required to have overpressure protection.

No overpressure protection is provided. The function of the CANISTER is to confine radioactive contents under normal, off-normal, and accident conditions of storage. The CANISTER vessel is designed to withstand a maximum internal pressure considering 100% fuel rod failure and maximum accident temperatures.

CANISTER Vessel NB-8000 States requirements for nameplates, stamping and reports per NCA-8000.

The NAC-UMS SYSTEM is marked and identified in accordance with 10 CFR 72 requirements. Code stamping is not required. The QA data package will be in accordance with NACs approved QA program. The completion of an ASME Design Specification, Design Report and Overpressure Protection Report is not required.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-6 Table B3-1 List of ASME Code Exceptions for the NAC-UMS SYSTEM (continued)

Component Reference ASME Code Section/Article Code Requirement Exception, Justification and Compensatory Measures CANISTER Basket Assembly NG-2000 Requires materials to be supplied by ASME approved material supplier.

Materials to be supplied by NAC-approved suppliers with CMTRs in accordance with NG-2000 requirements.

CANISTER Basket Assembly NG-8000 States requirements for nameplates, stamping and reports per NCA-8000.

The NAC-UMS SYSTEM will be marked and identified in accordance with 10 CFR 72 requirements. No Code stamping is required. The CANISTER basket data package will be in accordance with NACs approved QA program.

CANISTER Vessel and Basket Assembly Material NB-2130/ NG-2130 States requirements for certification of material organizations and materials to NCA-3861 and NCA-3862, respectively.

The NAC-UMS CANISTER and Basket Assembly component materials are procured in accordance with the specifications for materials in ASME Code Section II with Certified Material Test Reports. The component materials will be obtained from NAC approved Suppliers in accordance with NACs approved QA program.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-7 B 3.4 Site Specific Parameters and Analyses This section presents site-specific parameters and analytical bases that must be verified by the NAC-UMS SYSTEM user. The parameters and bases presented in Section B.3.4.1 are those applied in the design basis analysis. The parameters and bases used in the evaluation of SITE SPECIFIC FUEL are presented in the appropriate sections below.

B 3.4.1 Design Basis Site Specific Parameters and Analyses The design basis site-specific parameters and analyses that require verification by the NAC-UMS SYSTEM user are:

1.

The temperature of 76°F is the maximum average yearly temperature. The 3-day average ambient temperature shall be 106°F or less.

2.

The allowed temperature extremes, averaged over a 3-day period, shall be greater than -40°F and less than 133°F.

3.

a)

The design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad or at the center of gravity of the loaded concrete cask on the ISFSI pad are bounded by the values shown:

Configuration Coefficient of Friction Horizontal g-level in each of Two Orthogonal Directions Corresponding Vertical g-level Standard 0.35 0.26g 0.26g Standard 0.40 0.29g 0.29g Note: For site conditions that are not bounded by the above values, site-specific analysis may be performed in accordance with B 3.4.1(3)(b).

b)

Alternatively, the design basis earthquake motion of the ISFSI pad may be limited so that the acceleration g-load resulting from the collision of two sliding casks remains bounded by the accident condition analyses presented in Chapter 11 of the FSAR.

Site-specific analysis by the cask user shall demonstrate that a cask does not slide off the ISFSI pad.

(continued)

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-8 B 3.4.1 Design Basis Site Specific Parameters and Analyses (continued) 4.

The analyzed flood condition of 15 fps water velocity and a height of 50 feet of water (full submergence of the loaded cask) are not exceeded.

5.

The potential for fire and explosion shall be addressed, based on site-specific considerations. This includes the condition that the fuel tank of the cask handling equipment used to move the loaded CONCRETE CASK onto or from the ISFSI site contains no more than 50 gallons of fuel.

6 In cases where engineered features (i.e., berms, shield walls) are used to ensure that requirements of 10 CFR 72.104(a) are met, such features are to be considered important to safety and must be evaluated to determine the applicable Quality Assurance Category on a site specific basis.

7.

TRANSFER CASK OPERATIONS shall only be conducted with surrounding air temperatures 0°F.

8.

The VERTICAL CONCRETE CASK shall only be lifted by the lifting lugs with surrounding air temperatures 0°F.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-9 B 3.4.2 Maine Yankee Site Specific Parameters and Analyses The design basis site-specific parameters and analyses that require verification by Maine Yankee are:

1.

The temperature of 76°F is the maximum average yearly temperature. The 3-day average ambient temperature shall be 106°F or less.

2.

The allowed temperature extremes, averaged over a 3-day period, shall be greater than -40°F and less than 133°F.

3.

The design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad are bounded by the values shown:

Configuration Coefficient of Friction Horizontal g-level in each of Two Orthogonal Directions1 Corresponding Vertical g-level (upward)

Maine Yankee 0.50 0.38 0.38 x 0.667 =

0.253g 1 Earthquake loads are applied to the center of gravity of the concrete cask on the ISFSI pad.

4.

The analyzed flood condition of 15 fps water velocity and a height of 50 feet of water (full submergence of the loaded cask) are not exceeded.

5.

The potential for fire and explosion shall be addressed, based on site-specific considerations. This includes the condition that the fuel tank of the cask handling equipment used to move the loaded CONCRETE CASK onto or from the ISFSI site contains no more than 50 gallons of fuel.

6.

Physical testing shall be conducted to demonstrate that the coefficient of friction between the concrete cask and ISFSI pad surface is at least 0.5.

(continued)

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-10 B 3.4.2 Maine Yankee Site Specific Parameters and Analyses (continued) 7.

In addition to the requirements of 10 CFR 72.212(b)(2)(ii), the ISFSI pad(s) and foundation shall meet the design basis earthquake horizontal and vertical seismic acceleration levels at the top surface of the ISFSI pad as specified in B 3.4.2 (3).

The surface of the ISFSI pad shall have a broom finish or brushed surface as defined in ACI 116R-90 and described in Sections 7.12 and 7.13.4 of ACI 302.1R.

8.

In cases where engineered features (i.e., berms, shield walls) are used to ensure that requirements of 10 CFR 72.104(a) are met, such features are to be considered important to safety and must be evaluated to determine the applicable Quality Assurance Category on a site specific basis.

9.

TRANSFER CASK OPERATIONS shall only be conducted with surrounding air temperatures 0°F.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-11 B 3.5 CANISTER HANDLING FACILITY (CHF)

B 3.5.1 TRANSFER CASK and CANISTER Lifting Devices Movements of the TRANSFER CASK and CANISTER outside of the 10 CFR 50 licensed facilities, when loaded with spent fuel are not permitted unless the movements are made with a CANISTER HANDLING FACILITY designed, operated, fabricated, tested, inspected and maintained in accordance with the guidelines of NUREG-0612, Control of Heavy Loads at Nuclear Power Plants and the below clarifications. This Technical Specification does not apply to handling heavy loads under a 10 CFR 50 license.

B 3.5.2 CANISTER HANDLING FACILITY Structure Requirements B 3.5.2.1 CANISTER Station and Stationary Lifting Devices 1.

The weldment structure of the CANISTER HANDLING FACILITY shall be designed to comply with the stress limits of ASME Code,Section III, Subsection NF, Class 3 for linear structures. The applicable loads, load combinations, and associated service condition definitions are provided in Table B3-2. All compression loaded members shall satisfy the buckling criteria of ASME Code,Section III, Subsection NF.

2.

If a portion of the CANISTER HANDLING FACILITY structure is constructed of reinforced concrete, then the factored load combinations set forth in ACI-318 (1995) for the loads defined in Table B3-2 shall apply.

3.

The TRANSFER CASK and CANISTER lifting device used with the CANISTER HANDLING FACILITY shall be designed, fabricated, operated, tested, inspected and maintained in accordance with NUREG-0612, Section 5.1.

(continued)

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-12 B 3.5.2.1 CANISTER HANDLING Station and Stationary Lifting Devices (continued) 4.

The CHF design shall incorporate an impact limiter for CANISTER lifting and movement if a qualified single failure proof crane is not used. The impact limiter must be designed and fabricated to ensure that, if a CANISTER is dropped, the confinement boundary of the CANISTER would not be breached.

B 3.5.2.2 Mobile Lifting Devices If a mobile lifting device is used as the lifting device, in lieu of a stationary lifting device, it shall meet the guidelines of NUREG-0612, Section 5.1, with the following clarifications:

1.

Mobile lifting devices shall have a minimum safety factor of two over the allowable load table for the lifting device in accordance with the guidance of NUREG-0612, Section 5.1.6(1)(a) and shall be capable of stopping and holding the load during a Design Basis Earthquake (DBE) event.

2.

Mobile lifting devices shall conform to the requirements of ANSI B30.5, Mobile and Locomotive Cranes, in lieu of the requirements of ANSI B30.2, Overhead and Gantry Cranes.

3.

Mobile cranes are not required to meet the requirements of NUREG-0612, Section 5.1.6(2) for new cranes.

Renewed Amendment No. 4

Design Features B 3.0 Certificate of Compliance No. 1015 B3-13 Table B3-2 Load Combinations and Service Condition Definitions for the CANISTER HANDLING FACILITY (CHF) Structure Load Combination ASME Section III Service Condition for Definition of Allowable Stress Comment D*

D + S Level A All primary load bearing members must satisfy Level A stress limits D + M + W1 D + F D + E D + Y Level D Factor of safety against overturning shall be 1.1 D

=

Crane hook dead load D*

=

Apparent crane hook dead load S

=

Snow and ice load for the CHF site M

=

Tornado missile load of the CHF site1 W

=

Tornado wind load for the CHF site1 F

=

Flood load for the CHF site E

=

Seismic load for the CHF site Y

=

Tsunami load for the CHF site Note:

1.

Tornado missile load may be reduced or eliminated based on a PRA for the CHF site.

Renewed Amendment No. 4