Sequoyah, Units 1 and 2, Enclosure 2 - Volume 15 - Improved Technical Specifications Conversion, ITS Chapter 4.0, Design Features, Revision 0

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Text

ENCLOSURE 2 VOLUME 15

SEQUOYAH NUCLEAR PLANT UNIT 1 AND UNIT 2 IMPROVED TECHNICAL SPECIFICATIONS CONVERSION

ITS CHAPTER 4.0 DESIGN FEATURES

Revision 0

LIST OF ATTACHMENTS

1. ITS Chapter 4.0 - DESIGN FEATURES ATTACHMENT 1 ITS 4.0, DESIGN FEATURES

Current Technical Specification (CTS) Markup and Discussion of Changes (DOCs)

A01ITS ITS Chapter 4.0 5.0 DESIGN FEATURES 5.1 SITE LOCATION The Sequoyah Nuclear Plant is located on a site near the geographical center of Hamilton County, Tennessee, on a peninsula on the western shore of Chickamauga Lake at Tennessee River mile (TRM) 484.5. The Sequoyah site is approximately 7.5 miles northeast of the nearest city limit of Chattanooga, Tennessee, 14 miles west-northwest of Cleveland, Tennessee, and approximately 31 miles south-southwest of TVA's Watts Bar Nuclear Plant.

EXCLUSION AREA

5.2.1 DELETED LOW POPULATION ZONE

5.1.2 DELETED SITE BOUNDARY FOR GASEOUS EFFLUENTS

5.1.3 DELETED

SITE BOUNDARY FOR LIQUID EFFLUENTS 5.1.4 DELETED

5.2 CONTAINMENT

CONFIGURATION

5.2.1 DELETED DESIGN PRESSURE AND TEMPERATURE

5.2.2 DELETED

August 2, 2006 SEQUOYAH - UNIT 1 5-1 Amendment No. 309 Page 1 of 16 4.1 A01ITS ITS Chapter 4.0

THIS PAGE INTENTIONALLY DELETED

August 2, 2006 SEQUOYAH - UNIT 1 5-2 Amendment No. 42, 114, 309 Page 2 of 16 A01ITS ITS Chapter 4.0

THIS PAGE INTENTIONALLY DELETED

August 2, 2006 SEQUOYAH - UNIT 1 5-3 Amendment No. 309 Page 3 of 16 A01ITS ITS Chapter 4.0 5.3 REACTOR CORE FUEL ASSEMBLIES

5.3.1 The reactor shall contain 193 fuel assemblies. Each assembly shall consist of a matrix of zircaloy or M5 clad fuel rods with an initial composition of natural or slightly enriched uranium dioxide as fuel material. Limited substitutions of zirconium alloy or stainless steel filler rods for fuel rods, in accordance with NRC-approved applications of fuel rod configurations, may be used. Fuel assemblies shall be limited to those fuel designs that have been analyzed with applicable NRC staff-approved codes and methods, and shown by tests or analyses to comply with all fuel safety design bases. A limited number of lead test assemblies that have not completed representative testing may be placed in nonlimiting core regions. Sequoyah is authorized to place a limited number of lead test assemblies into the reactor as described in the Framatome-Cogema Fuels report BAW-2328, beginning with the Unit 1 Operating Cycle 12.

CONTROL ROD ASSEMBLIES

5.3.2 The reactor core shall contain 53 full length and no part length control rod assemblies. The full length control rod assemblies shall contain a nominal 142 inches of absorber material. The nominal values of absorber material shall be 80 percent silver, 15 percent indium and 5 percent cadmium. All control rods shall be clad with stainless steel tubing.

5.4 REACTOR COOLANT SYSTEM

DESIGN PRESSURE AND TEMPERATURE

5.4.1 DELETED

VOLUME 5.4.2 DELETED

5.5 METEOROLOGICAL TOWER LOCATION

5.5.1 DELETED

August 2, 2006 SEQUOYAH - UNIT 1 5-4 Amendment No. 45, 144, 180, 258, 268, 309 4.2 4.2.1 4.2.2 Page 4 of 16 A01ITS ITS Chapter 4.0 DESIGN FEATURES 5.6 FUEL STORAGE CRITICALITY - SPENT FUEL

5.6.1.1 The spent fuel storage racks are designed for fuel enriched to 5 weight percent U-235 and shall be maintained with:

a. A k eff less than critical when flooded with unborated water and a k eff less than or equal to 0.95 when flooded with water containing 300 ppm soluble boron.*

b. A nominal 8.972 inch center-to-center distance between fuel assemblies placed in the storage racks.

c. Arrangements of one or more of three different arrays (Regions) or sub-arrays as illustrated in Figures 5.6-1 and 5.6-1a. These arrangements in the spent fuel storage pool have the following definitions:

1. Region 1 is designed to accommodate new fuel with a maximum enrichment of 4.95

+/- 0.05 wt% U-235, (or spent fuel regardless of the fuel burnup), in a 1-in-4 checkerboard arrangement of 1 fresh assembly with 3 spent fuel assemblies with enrichment-burnup and cooling times illustrated in Figure 5.6-2 and defined by the equations in Table 5.6-1. Cooling time is defined as the period since reactor shutdown at the end of the last operating cycle for the discharged spent fuel assembly. The presence of a removable, non-fissile insert such as a burnable poison rod assembly (BPRA) or either gadolinia or integral fuel burnable absorber (IFBA) in a fresh fuel assembly does not affect the applicability of Figure 5.6-2 or Table 5.6-1.

Two alternative storage arrays (or sub-arrays) are acceptable in Region 1 if the fresh fuel assemblies contain rods with either gadolinia or integral fuel burnable absorber (IFBA). For these types of assemblies, the minimum burnup of the spent fuel in the 1-of-4 sub-array are defined by the equations in Table 5.6-2.

Restrictions in Region 1 Any of the three sub-arrays illustrated in Figure 5.6-1a may be used in any combination provided that:

1) Each sub-array of 4 fuel assemblies includes, in addition to the fresh fuel assembly, 3 assemblies with enrichment and minimum burnup requirements defined by the equations in Tables 5.6-1 and 5.6-2, as appropriate.

2) The arrangement of Region 1 sub-arrays must not allow a configuration with fresh assemblies adjacent to each other.

3) If Region 1 arrays are used in conjunction with Region 2 or Region 3 arrangements (see below), the arrangements shall not allow fresh fuel assemblies to be adjacent to each other (see also Figure 5.6-1).

• For some accident conditions, the presence of dissolved boron in the pool water may be taken into account by applying the double contingency principle which requires two unlikely, independent, concurrent events to produce a criticality accident.

December 19, 2000 SEQUOYAH - UNIT 1 5-5 Amendment No. 13, 60, 114, 144, 167, 2654.3 4.3.1 4.3.1.1 4.3.1.1.a 4.3.1.1.b 4.3.1.1.c 4.3.1.1.b See ITS 3.7.15 Page 5 of 16 A01ITS ITS Chapter 4.0 DESIGN FEATURES 5.6 FUEL STORAGE CRITICALITY - NEW FUEL 5.6.1.2 The new fuel pit storage racks are designed for fuel enriched to 5.0 weight percent U-235 and shall be maintained with the arrangement of 146 storage locations shown in Figure 5.6-4. The cells shown as empty cells in Figure 5.6-4 shall have physical barriers installed to ensure that inadvertent loading of fuel assemblies into these locations does not occur. This configuration ensures k eff will remain less than or equal to 0.95 when flooded with unborated water and less than or equal to 0.98 under optimum moderation conditions.

DRAINAGE 5.6.2 The spent fuel pit is designed and shall be maintained to prevent inadvertent draining of the pool below elevation 722 ft.

CAPACITY 5.6.3 The spent fuel storage pool is designed and shall be maintained with a storage capacity limited to no more than 2091 fuel assemblies. In addition, no more than 225 fuel assemblies will be stored in a rack module in the cask loading area of the cask pit.

5.7 COMPONENT CYCLIC OR TRANSIENT LIMIT

5.7.1 DELETED

August 2, 2006 SEQUOYAH - UNIT 1 5-5b Amendment No. 167, 225, 309 4.3 4.3.1 4.3.2 4.3.3 4.3.1.2.a 4.3.1.2.d 4.3.1.2.b 4.3.1.2.c Page 6 of 16 Enclosure 2, Rev. 0, Page 11 of 35 Volume 15,/'---"-\/\( nor )t _ ---/[s Figure 4 3.1 2-1 ITS Chapter 4.0 December 19, 2000 Amendment No. 225Page 7 of 16 il T Besic Cell ?l inch X 2l inch Erp"f Cell 9.4X5CdlR"ilEks 146 / 180 t o'qling Penem Figure 5.6-4 New Fuel Pit Storage Rack Loading Pattern 5-59 SEQUOYAH - UNIT 1 Enclosure 2, Volume15, Rev. 0, Page 11 of 35 A01ITS ITS Chapter 4.0

THIS PAGE INTENTIONALLY DELETED

August 2, 2006 SEQUOYAH - UNIT 1 5-6 Amendment No. 36, 114, 157, 309

Page 8 of 32 Page 8 of 16 ITS Chapter 4.0 A01ITS 5.0 DESIGN FEATURES 5.1 SITE LOCATION The Sequoyah Nuclear Plant is located on a site near the geographical center of Hamilton County, Tennessee, on a peninsula on the western shore of Chickamauga Lake at Tennessee River mile (TRM) 484.5. The Sequoyah site is approximately 7.5 miles northeast of the nearest city limit of Chattanooga, Tennessee, 14 miles west-northwest of Cleveland, Tennessee, and approximately 31 miles south-southwest of TVA's Watts Bar Nuclear Plant.

EXCLUSION AREA

5.1.1 DELETED

LOW POPULATION ZONE 5.1.2 DELETED SITE BOUNDARY FOR GASEOUS EFFLUENTS

5.1.3 DELETED

SITE BOUNDARY FOR LIQUID EFFLUENTS 5.1.4 DELETED

5.2 CONTAINMENT

5.2.1 DELETED DESIGN PRESSURE AND TEMPERATURE

5.2.2 DELETED

August 2, 2006 SEQUOYAH - UNIT 2 5-1 Amendment No. 298 4.1 Page 9 of 16 ITS Chapter 4.0 A01ITS

THIS PAGE INTENTIONALLY DELETED

August 2, 2006 SEQUOYAH - UNIT 2 5-2 Amendment No. 34, 104, 298 Page 10 of 16 ITS Chapter 4.0 A01ITS

THIS PAGE INTENTIONALLY DELETED

August 2, 2006 SEQYOYAH - UNIT 2 5-3 Amendment No. 298 Page 11 of 16 ITS Chapter 4.0 A01ITS DESIGN FEATURES 5.3 REACTOR CORE FUEL ASSEMBLIES

5.3.1 The reactor shall contain 193 fuel assemblies. Each assembly shall consist of a matrix of zircaloy or M5 clad fuel rods with an initial composition of natural or slightly enriched uranium dioxide as fuel material. Limited substitutions of zirconium alloy or stainless steel filler rods for fuel rods, in accordance with NRC-approved applications of fuel rod configurations, may be used. Fuel assemblies shall be limited to those fuel designs that have been analyzed with applicable NRC staff-approved codes and methods, and shown by tests or analyses to comply with all fuel safety design bases. A limited number of lead test assemblies that have not completed representative testing may be placed in nonlimiting core regions. Sequoyah is authorized to place a limited number of lead test assemblies into the reactor, as described in the Framatome Cogema Fuels Report BAW-2328, beginning with the Unit 2 Operating Cycle 10 core.

CONTROL ROD ASSEMBLIES 5.3.2 The reactor core shall contain 53 full length and no part length control rod assemblies. The full length control rod assemblies shall contain a nominal 142 inches of absorber material. The nominal values of absorber material shall be 80 percent silver, 15 percent indium and 5 percent cadmium. All control rods shall be clad with stainless steel tubing.

5.4 REACTOR COOLANT SYSTEM DESIGN PRESSURE AND TEMPERATURE 5.4.1 DELETED VOLUME 5.4.2 DELETED 5.5 METEOROLOGICAL TOWER LOCATION

5.5.1 DELETED

August 2, 2006 SEQUOYAH - UNIT 2 5-4 Amendment No 37, 125, 172, 234, 249, 298 4.2 4.2.1 4.2.2 Page 12 of 16 ITS Chapter 4.0 A01ITS DESIGN FEATURES 5.6 FUEL STORAGE

CRITICALITY - SPENT FUEL 5.6.1.1 The spent fuel storage racks are designed for fuel enriched to 5 weight percent U-235 and shall be maintained with:

a. A k eff less than critical when flooded with unborated water and a k eff less than or equal to 0.95 when flooded with water containing 300 ppm soluble boron.*

b. A nominal 8.972 inch center-to-center distance between fuel assemblies placed in the storage racks.

c. Arrangements of one or more of three different arrays (Regions) or sub-arrays as illustrated in Figures 5.6-1 and 5.6-1a. These arrangements in the spent fuel storage pool have the following definitions:

1. Region 1 is designed to accommodate new fuel with a maximum enrichment of 4.95

+/- 0.05 wt% U-235, (or spent fuel regardless of the fuel burnup), in a 1-in-4 checkerboard arrangement of 1 fresh assembly with 3 spent fuel assemblies with enrichment-burnup and cooling times illustrated in Figure 5.6-2 and defined by the equations in Table 5.6-1. Cooling time is defined as the period since reactor shutdown at the end of the last operating cycle for the discharged spent fuel assembly. The presence of a removable, non-fissile insert such as a burnable poison rod assembly (BPRA) or either gadolinia or integral fuel burnable absorber (IFBA) in a fresh fuel assembly does not affect the applicability of Figure 5.6-2 or Table 5.6-1.

Two alternative storage arrays (or sub-arrays) are acceptable in Region 1 if the fresh fuel assemblies contain rods with either gadolinia or integral fuel burnable absorber (IFBA). For these types of assemblies, the minimum burnup of the spent fuel in the 1-of-4 sub-array are defined by the equations in Table 5.6-2.

Restrictions in Region 1 Any of the three sub-arrays illustrated in Figure 5.6-1a may be used in any combination provided that:

1) Each sub-array of 4 fuel assemblies includes, in addition to the fresh fuel assembly, 3 assemblies with enrichment and minimum burnup requirements defined by the equations in Tables 5.6-1 and 5.6-2, as appropriate.

2) The arrangement of Region 1 sub-arrays must not allow a configuration with fresh assemblies adjacent to each other.

3) If Region 1 arrays are used in conjunction with Region 2 or Region 3 arrangements (see below), the arrangements shall not allow fresh fuel assemblies to be adjacent to each other (see also Figure 5.6-1).

• For some accident conditions, the presence of dissolved boron in the pool water may be taken into account by applying the double contingency principle which requires two unlikely, independent, concurrent events to produce a criticality accident.

December 19, 2000 SEQUOYAH - UNIT 2 5-5 Amendment No. 4, 52, 125, 157, 256 4.3 4.3.1 4.3.1.1 4.3.1.1.a 4.3.1.1.b 4.3.1.1.c 4.3.1.1.b See ITS 3.7.15 Page 13 of 16 ITS Chapter 4.0 A01ITS DESIGN FEATURES 5.6 FUEL STORAGE CRITICALITY - NEW FUEL

5.6.1.2 The new fuel pit storage racks are designed for fuel enriched to 5.0 weight percent U-235 and shall be maintained with the arrangement of 146 storage locations shown in Figure 5.6-4. The cells shown as empty cells in Figure 5.6-4 shall have physical barriers installed to ensure that inadvertent loading of fuel assemblies into these locations does not occur. This configuration ensures k eff will remain less than or equal to 0.95 when flooded with unborated water and less than or equal to 0.98 under optimum moderation conditions.

DRAINAGE 5.6.2 The spent fuel storage pool is designed and shall be maintained to prevent inadvertent draining of the pool below elevation 722 ft.

CAPACITY 5.6.3 The spent fuel storage pool is designed and shall be maintained with a storage capacity limited to no more than 2091 fuel assemblies. In addition, no more than 225 fuel assemblies will be stored in a rack module in the cask loading area of the cask pit.

5.7 COMPONENT CYCLIC OR TRANSIENT LIMIT

5.7.1 DELETED

August 2, 2006 SEQUOYAH - UNIT 2 5-5b Amendment No. 157, 216, 2984.3 4.3.1 4.3.2 4.3.3 4.3.1.2.a 4.3.1.2.d 4.3.1.2.b 4.3.1.2.c Page 14 of 16 Enclosure 2, Rev. 0, Page 19 of 35 Volume 15, G)ITS Figure4312-1 ITS Chapter 4 A Besic Cell 3l inch .X 3l incb E*pry Cdl 9.4X5CdlRscks 146 / t80 t"o'.tjng Pancm Figure 5.6-4 New Fuel Pit Storage Rack Loading Pattern 5-59 n T SEQUOYAH - UNIT 2 December 19, 2000Amendment No. 216Enclosure 2, Volume 15, Rev. 0, Page 19 of 35 Page 15 of 16 ITS Chapter 4.0 A01ITS

THIS PAGE INTENTIONALLY DELETED

August 2, 2006 SEQUOYAH - UNIT 2 5-6 Amendment No. 28, 104, 147, 298 Page 16 of 16 DISCUSSION OF CHANGES ITS Chapter 4.0, DESIGN FEATURES Sequoyah Unit 1 and Unit 2 Page 1 of 1 ADMINISTRATIVE CHANGES A01 In the conversion of the Sequoyah Nuclear Plant (SQN) Current Technical Specifications (CTS) to the plant specific Improved Technical Specifications (ITS), certain changes (wording preferences, editorial changes, reformatting, revised numbering, etc.) are made to obtain consistency with NUREG - 1431, Rev. 4.0, "Standard Technical Specifications - Westinghouse Plants" (ISTS) and additional Technical Specification Task Force (TSTF) travelers included in this

submittal.

These changes are designated as administrative changes and are acceptable because they do not result in technical changes to the CTS.

MORE RESTRICTIVE CHANGES None

RELOCATED SPECIFICATIONS

None REMOVED DETAIL CHANGES

None LESS RESTRICTIVE CHANGES

None

Improved Standard Technical Specifications (ISTS) Markup and Justification for Deviations (JFDs)

Design Features 4.0 Westinghouse STS 4.0-1 Rev. 4.0 CTS 4SEQUOYAH UNIT 1 Amendment XXX 4.0 DESIGN FEATURES

4.1 Site Location

[ Text description of site location.

]

4.2 Reactor Core

4.2.1 Fuel Assemblies The reactor shall contain

[157] fuel assemblies. Each assembly shall consist of a matrix of

[Zircalloy or ZIRLO] fuel rods with an initial composition of natural or slightly enriched uranium dioxide (UO

2) as fuel material. Limited substitutions of zirconium alloy or stainless steel filler rods for fuel rods, in accordance with approved applications of fuel rod configurations, may be used. Fuel assemblies shall be limited to those fuel designs that have been analyzed with applicable NRC staff approved codes and methods and shown by tests or analyses to comply with all fuel safety design bases. A limited number of lead test assemblies that have not completed representative testing may be placed in nonlimiting core regions.

4.2.2 [Control Rod

] Assemblies The reactor core shall contain

[48] [control rod

] assemblies. The control material shall be [silver indium cadmium, boron carbide, or hafnium metal] as approved by the NRC.

4.3 Fuel Storage

4.3.1 Criticality

4.3.1.1 The spent fuel storage racks are designed and shall be maintained with:

a. Fuel assemblies having a maximum U-235 enrichment of

[4.5] weight percent

, b. k eff 0.95 if fully flooded with unborated water, which includes an allowance for uncertainties as described in [Section 9.1 of the FSAR], [ c. A nominal

[9.15] inch center to center distance between fuel assemblies placed in

[the high density fuel storage racks

], ]

[ d. A nominal [10.95]

inch center to center distance between fuel assemblies placed in [low density fuel storage racks], ] INSERT 1 1 193 INSERT 2 INSERT 353 full length and no part length 8.972INSERT 4 5.1 5.3 5.3.1 5.3.2 5.6 5.6 5.6.1.1 5.6.1.1 5.6.1.1.a, Footnote

• 5.6.1.1.b 5.0;.1 2 1 2 1 1 3 2 1 1M5 clad 5Zircaloy 4.0 Insert Page 4.0-1 CTS INSERT 1 The Sequoyah Nuclear Plant is located on a site near the geographical center of Hamilton County, Tennessee, on a peninsula on the western shore of Chickamauga Lake at Tennessee River mile (TRM) 484.5. The Sequoyah site is approximately 7.5 miles northeast of the nearest city limit of Chattanooga, Tennessee, 14 miles west-northwest of Cleveland, Tennessee, and approximately 31 miles south-southwest of TVA's Watts Bar Nuclear Plant.

INSERT 2 Sequoyah is authorized to place a limited number of lead test assemblies into the reactor as described in the Framatome-Cogema Fuels report BAW-2328, beginning with the Unit 1

Operating Cycle 12.

INSERT 3 The full length control rod assemblies shall contain a nominal 142 inches of absorber material.

The nominal values of absorber material shall be 80 percent silver, 15 percent indium and 5 percent cadmium. All control rods shall be clad with stainless steel tubing.

INSERT 4

A k eff less than critical when flooded with unborated water and a k eff less than or equal to 0.95 when flooded with water containing 300 ppm soluble boron. For some accident conditions, the presence of dissolved boron in the pool water may be taken into account by applying the double contingency principle which requires two unlikely, independent, concurrent events to produce a criticality accident; and 15.1 5.6.1.1.a, Footnote

• 5.3.2 5.3.1 2 2 2 Design Features 4.0 Westinghouse STS 4.0-2 Rev. 4.0 CTS 4SEQUOYAH UNIT 1 Amendment XXX 4.0 DESIGN FEATURES

4.3 Fuel Storage (continued)

[ e. New or partially spent fuel assemblies with a discharge burnup in the "acceptable range" of Figure

[3.7.17-1] may be allowed unrestricted storage in [either] fuel storage rack(s), and

] [ f. New or partially spent fuel assemblies with a discharge burnup in the "unacceptable range" of Figure [3.7.17-1] will be stored in compliance with the NRC approved [specific document containing the analytical methods, title, date, or specific configuration or figure]. ] 4.3.1.2 The new fuel storage racks are designed and shall be maintained with:

a. Fuel assemblies having a maximum U-235 enrichment of

[4.5] weight percent

,

b. k eff 0.95 if fully flooded with unborated water, which includes an allowance for uncer tainties as described in [Section 9.1 of the FSAR],

c. k eff 0.98 if moderated by aqueous foam, which includes an allowance for uncertainties as described in [Section 9.1 of the FSAR], and

d. A nomin al [10.95]

inch center to center distance between fuel assemblies placed in the storage racks.

4.3.2 Drainage

The spent fuel storage pool is designed and shall be maintained to prevent inadvertent draining of the pool below elevation

[23 ft]. 4.3.3 Capacity The spent fuel storage pool is designed and shall be maintained with a storage capacity limited to no more than [1737] fuel assemblies.

under optimum moderation conditions;INSERT 5 5.0 7225.6 5.6.1.2 5.6.1.2 5.6.1.2 5.6.1.2 5.6.1.2 5.6. 2 5.6.3 ;; 1 1 1 3 1 3 2 1 2 3 2 1 1 1 2091 INSERT 6 2 INSERT 7 2 4.0 Insert Page 4.0-2a CTS INSERT 5 The arrangement of 146 storage locations shown in Figure 4.3.1.2-1. The cells shown as empty cells in Figure 4.3.1.2-1 shall have physical barriers installed to ensure that inadvertent loading of fuel assemblies into these locations does not occur.

INSERT 6

In addition, no more than 225 fuel assemblies will be stored in a rack module in the cask loading area of the cask pit. 5.6.1.2 2 25.6.3 4.0 Insert Page 4.0-2b CTS INSERT 7

Basic Cell 21 inch X 21 inch

Empty Cell

9 - 4 X 5 Cell Racks 146 / 180 Loading Pattern

Figure 4.3.1.2-1 New Fuel Storage Rack Loading Pattern Figure 5.6-4 2

Design Features 4.0 Westinghouse STS 4.0-1 Rev. 4.0 CTS 4SEQUOYAH UNIT 2 Amendment XXX 4.0 DESIGN FEATURES

4.1 Site Location

[ Text description of site location.

]

4.2 Reactor Core

4.2.1 Fuel Assemblies The reactor shall contain

[157] fuel assemblies. Each assembly shall consist of a matrix of

[Zircalloy or ZIRLO] fuel rods with an initial composition of natural or slightly enriched uranium dioxide (UO

2) as fuel material. Limited substitutions of zirconium alloy or stainless steel filler rods for fuel rods, in accordance with approved applications of fuel rod configurations, may be used. Fuel assemblies shall be limited to those fuel designs that have been analyzed with applicable NRC staff approved codes and methods and shown by tests or analyses to comply with all fuel safety design bases. A limited number of lead test assemblies that have not completed representative testing may be placed in nonlimiting core regions.

4.2.2 [Control Rod

] Assemblies The reactor core shall contain

[48] [control rod

] assemblies. The control material shall be [silver indium cadmium, boron carbide, or hafnium metal] as approved by the NRC.

4.3 Fuel Storage

4.3.1 Criticality

4.3.1.1 The spent fuel storage racks are designed and shall be maintained with:

a. Fuel assemblies having a maximum U-235 enrichment of

[4.5] weight percent

, b. k eff 0.95 if fully flooded with unborated water, which includes an allowance for uncertainties as described in [Section 9.1 of the FSAR], [ c. A nominal

[9.15] inch center to center distance between fuel assemblies placed in

[the high density fuel storage racks

], ]

[ d. A nominal [10.95]

inch center to center distance between fuel assemblies placed in [low density fuel storage racks], ] INSERT 1 1 193 INSERT 2 INSERT 353 full length and no part length 8.972INSERT 4 5.1 5.3 5.3.1 5.3.2 5.6 5.6 5.6.1.1 5.6.1.1 5.6.1.1.a, Footnote

• 5.6.1.1.b 5.0;.1 2 1 2 1 1 3 2 1 1M5 clad 5Zircaloy 4.0 Insert Page 4.0-1 CTS INSERT 1 The Sequoyah Nuclear Plant is located on a site near the geographical center of Hamilton County, Tennessee, on a peninsula on the western shore of Chickamauga Lake at Tennessee River mile (TRM) 484.5. The Sequoyah site is approximately 7.5 miles northeast of the nearest city limit of Chattanooga, Tennessee, 14 miles west-northwest of Cleveland, Tennessee, and approximately 31 miles south-southwest of TVA's Watts Bar Nuclear Plant.

INSERT 2 Sequoyah is authorized to place a limited number of lead test assemblies into the reactor as described in the Framatome-Cogema Fuels report BAW-2328, beginning with the Unit 1

Operating Cycle 12.

INSERT 3 The full length control rod assemblies shall contain a nominal 142 inches of absorber material.

The nominal values of absorber material shall be 80 percent silver, 15 percent indium and 5 percent cadmium. All control rods shall be clad with stainless steel tubing.

INSERT 4

A k eff less than critical when flooded with unborated water and a k eff less than or equal to 0.95 when flooded with water containing 300 ppm soluble boron. For some accident conditions, the presence of dissolved boron in the pool water may be taken into account by applying the double contingency principle which requires two unlikely, independent, concurrent events to produce a criticality accident; and 15.1 5.6.1.1.a, Footnote

• 5.3.2 5.3.1 2 2 2 Design Features 4.0 Westinghouse STS 4.0-2 Rev. 4.0 CTS 4SEQUOYAH UNIT 2 Amendment XXX 4.0 DESIGN FEATURES

4.3 Fuel Storage (continued)

[ e. New or partially spent fuel assemblies with a discharge burnup in the "acceptable range" of Figure

[3.7.17-1] may be allowed unrestricted storage in [either] fuel storage rack(s), and

] [ f. New or partially spent fuel assemblies with a discharge burnup in the "unacceptable range" of Figure [3.7.17-1] will be stored in compliance with the NRC approved [specific document containing the analytical methods, title, date, or specific configuration or figure]. ] 4.3.1.2 The new fuel storage racks are designed and shall be maintained with:

a. Fuel assemblies having a maximum U-235 enrichment of

[4.5] weight percent

,

b. k eff 0.95 if fully flooded with unborated water, which includes an allowance for uncertaint ies as described in [Section 9.1 of the FSAR],

c. k eff 0.98 if moderated by aqueous foam, which includes an allowance for uncertainties as described in [Section 9.1 of the FSAR], and

d. A nominal [1 0.95] inch center to center distance between fuel assemblies placed in the storage racks.

4.3.2 Drainage

The spent fuel storage pool is designed and shall be maintained to prevent inadvertent draining of the pool below elevation

[23 ft]. 4.3.3 Capacity The spent fuel storage pool is designed and shall be maintained with a storage capacity limited to no more than [1737] fuel assemblies.

under optimum moderation conditions;INSERT 5 5.0 7225.6 5.6.1.2 5.6.1.2 5.6.1.2 5.6.1.2 5.6.1.2 5.6. 2 5.6.3 ;; 1 1 1 3 1 3 2 1 2 3 2 1 1 1 2091 INSERT 6 2 INSERT 7 2 4.0 Insert Page 4.0-2a CTS INSERT 5 The arrangement of 146 storage locations shown in Figure 4.3.1.2-1. The cells shown as empty cells in Figure 4.3.1.2-1 shall have physical barriers installed to ensure that inadvertent loading of fuel assemblies into these locations does not occur.

INSERT 6

In addition, no more than 225 fuel assemblies will be stored in a rack module in the cask loading area of the cask pit. 5.6.1.2 2 25.6.3 4.0 Insert Page 4.0-2b CTS INSERT 7

Basic Cell 21 inch X 21 inch

Empty Cell

9 - 4 X 5 Cell Racks 146 / 180 Loading Pattern

Figure 4.3.1.2-1 New Fuel Storage Rack Loading Pattern Figure 5.6-4 2

JUSTIFICATION FOR DEVIATIONS ITS Chapter 4.0, DESIGN FEATURES Sequoyah Unit 1 and Unit 2 Page 1 of 1 1. The ISTS contains bracketed information and/or values that are generic to Westinghouse vintage plants. The brackets are removed and the proper plant specific information/value is inserted to reflect the current licensing basis.

2. ISTS 4.0 has been changed to address Sequoyah Nuclear Plant (SQN) site specific requirements for fuel assemblies, control rod assemblies, and fuel storage. This change is acceptable because it reflects the current licensing basis.

3. These punctuation corrections have been made consistent with the Writer's Guide for the Improved Technical Specifications, TSTF-GG-05-01, Section 5.1.3.

4. Changes are made (additions, deletions, and/or changes) to the ISTS that reflect the plant specific nomenclature, number, reference, system description, analysis, or licensing basis description.

5. Typographical/grammatical error corrected.

Specific No Significant Haza rds Considerations (NSHCs)

DETERMINATION OF NO SIGNIFICANT HAZARDS CONSIDERATIONS ITS Chapter 4.0, DESIGN FEATURES Sequoyah Unit 1 and 2 Page 1 of 1 There are no specific No Significant Hazards Considerations for this Specification.